ABSTRACT

The crab-eating raccoon Procyon cancrivorus (Cuvier, 1798) is a species of the order Carnivora and family Procyonidae with a geographical distribution in Central and South America. Although crab-eating raccoons use scansorial locomotion, they also have aquatic habits, displaying greatly developed skills when handling their food. This species can frequently be found in wildlife care centers due to injuries caused by domestic dogs, humans, and car collisions. Having knowledge of the species’ gross anatomy and anatomical bases is imperative to perform the most appropriate medical and surgical procedures. Thus, the objective of this investigation was to analyze the interspecific and intraspecific differences of the craniolateral forearm muscles of Procyon cancrivorus. Gross dissections were performed in four specimens describing the origin, insertion, shape, innervation, and arterial supply of the craniolateral forearm muscles. There is a constant and well development of brachioradialis muscle comparatively to that described in strictly cursorial species; the extensor carpi radialis muscle has two bellies that are fused proximally; the extensor digitorum communis muscle can also extend the tendon to the digit I as an anatomical variant, and the extensor digiti I and II muscle also extends the tendon to digit III. All are innervated by the deep branch of the radial nerve, and their arterial supply is mainly by the radial collateral, cubital transverse, and cranial interosseous arteries. The anatomical characteristics observed in this study complement the previous descriptions for Procyon cancrivorus, and the anatomical variants found in this species can also be in other carnivorans. Thus, the intraspecific anatomical variations of the digital extensor muscles in P. cancrivorus are phylogenetic traits that can occur as a common pattern or as anatomical variants in other species of the order Carnivora.

KEYWORDS:
Function; innervation; insertion; myology; origin

Procyon cancrivorus (Cuvier, 1798) is commonly known as the crab-eating raccoon and it has a wide geographic distribution that ranges from Costa Rica to Uruguay (Cubas et al., 2006Cubas, Z. S.; Silva, J. C. R. & Catão-Dias, J. L. 2006. Carnívora-Procyonidae (Quati, Mão-pelada, Jupará). Tratado de animais selvagens-medicina veterinária. São Paulo, Roca, p. 571-582.; Wilson & Mittermeier, 2009Wilson, D. E. & Mittermeier, R. A. 2009. Handbook of the Mammals of the World, Vol. 1. Carnivores. Barcelona, Lynx Edicions. 727p.). It belongs to the order Carnivora, suborder Caniformia and family Procyonidae (Nyakatura & Bininda-Emonds, 2012Nyakatura, K. & Bininda-Emonds, O. R. 2012. Updating the evolutionary history of Carnivora (Mammalia): a new species-level supertree complete with divergence time estimates. BMC Biology 10(1):1-31. ). Phenotypically, P. cancrivorus is a medium-sized animal (2-6 kg, Labate et al., 2001Labate, A.; Nunes A. L. & Gomes, M. 2001. Order Carnivora, Family Procyonidae (Raccoons, kinkajous). In: Fowler, M. E. & Cubas, Z. S. eds. Biology, Medicine and Surgery of South American Wild Animals. Iowa, Iowa State University Press, p. 317-322.), with a wide tail which is approximately 50% of its total body length and is marked by five to ten dark and yellowish rings (Cubas et al., 2006Cubas, Z. S.; Silva, J. C. R. & Catão-Dias, J. L. 2006. Carnívora-Procyonidae (Quati, Mão-pelada, Jupará). Tratado de animais selvagens-medicina veterinária. São Paulo, Roca, p. 571-582.). One of the main facial characteristics of the species is a dark mask around the eyes (Labate et al., 2001Labate, A.; Nunes A. L. & Gomes, M. 2001. Order Carnivora, Family Procyonidae (Raccoons, kinkajous). In: Fowler, M. E. & Cubas, Z. S. eds. Biology, Medicine and Surgery of South American Wild Animals. Iowa, Iowa State University Press, p. 317-322.). The species also portrays elongated limbs including hands without hair (Nowak, 1999Nowak, R. M. 1999. Walker’s Mammals of the World. 6ed. Baltimore, The John Hopkins University Press. 2015p.; Cubas et al., 2006Cubas, Z. S.; Silva, J. C. R. & Catão-Dias, J. L. 2006. Carnívora-Procyonidae (Quati, Mão-pelada, Jupará). Tratado de animais selvagens-medicina veterinária. São Paulo, Roca, p. 571-582.). Within the family Procyonidae, the species of the genus Procyon are semipalmigrades with five functional digits in its hands, providing skills to climb and handle food (Mcclearn, 1992Mcclearn, D. 1992. Locomotion, posture, and feeding behavior of kinkajous, coatis, and raccoons. Journal of Mammalogy 73(2):245-261.).

It is a solitary species, with nocturnal and twilight habits that lives in shrubby areas close to rivers, swamps, or similar sources of water (Nowak, 1999Nowak, R. M. 1999. Walker’s Mammals of the World. 6ed. Baltimore, The John Hopkins University Press. 2015p.; Pellanda et al., 2010Pellanda, M.; Castro-Almeida, C. M.; Dos Santos, M. D. & Hartz, S. M. 2010. Dieta do mão-pelada (Procyon cancrivorus, Procyonidae, Carnivora) no Parque Estadual de Itapuã, sul do Brasil. Neotropical Biology and Conservation 5(3):154-159. ). This is possibly due to its diet consisting of crab, and its ability to swim (Cubas et al., 2006Cubas, Z. S.; Silva, J. C. R. & Catão-Dias, J. L. 2006. Carnívora-Procyonidae (Quati, Mão-pelada, Jupará). Tratado de animais selvagens-medicina veterinária. São Paulo, Roca, p. 571-582.; Martinelli & Volpi, 2010Martinelli, M. M. & Volpi, T. A. 2010. Diet of racoon Procyon cancrivorus (Carnivora, Procyonidae) in a mangrove and restinga area in Espírito Santo state, Brazil. Natureza on line 8:150-151.). Although P. cancrivorus is a species with few studies due to its nocturnal and crepuscular habits, it frequents the terrestrial substratum, and climb trees in search of refuge (Massoia et al., 2012Massoia, E.; Chebez, J. C. & Bosso, A. 2012. Los mamíferos silvestres de la provincia de Misiones, Argentina. Buenos Aires, Fundación de Historia Natural Félix de Azara. 512p.). Therefore, this species characterizes its locomotion for being mainly terrestrial (Wilson & Mittermeier, 2009Wilson, D. E. & Mittermeier, R. A. 2009. Handbook of the Mammals of the World, Vol. 1. Carnivores. Barcelona, Lynx Edicions. 727p.; Massoia et al., 2012Massoia, E.; Chebez, J. C. & Bosso, A. 2012. Los mamíferos silvestres de la provincia de Misiones, Argentina. Buenos Aires, Fundación de Historia Natural Félix de Azara. 512p.), but also having arboreal and swimming abilities (Indrusiak & Eizirik, 2003Indrusiak, C. & Eizirik, E. 2003. Carnívoros. In: Fontana, C. S.; Bencke, G. A. & Reis, R. E. orgs. Livro vermelho da fauna ameaçada de extinção do RS. Porto Alegre, Edipucrs, p. 507-533.; Martinelli & Volpi, 2010Martinelli, M. M. & Volpi, T. A. 2010. Diet of racoon Procyon cancrivorus (Carnivora, Procyonidae) in a mangrove and restinga area in Espírito Santo state, Brazil. Natureza on line 8:150-151.; Pellanda et al., 2010Pellanda, M.; Castro-Almeida, C. M.; Dos Santos, M. D. & Hartz, S. M. 2010. Dieta do mão-pelada (Procyon cancrivorus, Procyonidae, Carnivora) no Parque Estadual de Itapuã, sul do Brasil. Neotropical Biology and Conservation 5(3):154-159. ). This can lead to changes in the shape and arrangement of the muscles (Diogo & Abdala, 2010Diogo, R. & Abdala, V. 2010. Muscles of vertebrates: comparative anatomy, evolution, homologies and development. Boca Raton, CRC Press. 500p.), such as has been reported in the flexor digitorum superficialis and palmaris longus muscles in carnivorans (Perdomo-Cárdenas et al., 2021Perdomo‐Cárdenas, V.; Patiño‐Holguín, C. & Vélez‐García, J. F. 2021. Evolutionary and terminological analysis of the flexor digitorum superficialis, interflexorii and palmaris longus muscles in kinkajou (Potos flavus) and crab‐eating racoon (Procyon cancrivorus). Anatomia Histologia Embryologia 50(3):520-533.). For example, some mustelids and species of the genera Procyon, Nasua, Ailurus and Ailuropoda have one m. palmaris longus evolutionarily derived from the m. flexor digitorum superficialis (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Davis, 1964Davis, D. 1964. The giant panda a morphological study of evolutionary mechanisms. Chicago, Natural History Museum Chicago 3:1-339.; Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.; Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ; Perdomo-Cárdenas et al., 2021Perdomo‐Cárdenas, V.; Patiño‐Holguín, C. & Vélez‐García, J. F. 2021. Evolutionary and terminological analysis of the flexor digitorum superficialis, interflexorii and palmaris longus muscles in kinkajou (Potos flavus) and crab‐eating racoon (Procyon cancrivorus). Anatomia Histologia Embryologia 50(3):520-533.). While the genus Potos has developed two palmaris longus muscles, from which it is inferred that it may have occurred due to Potos has higher manual abilities than other carnivoran species (Mcclearn, 1992Mcclearn, D. 1992. Locomotion, posture, and feeding behavior of kinkajous, coatis, and raccoons. Journal of Mammalogy 73(2):245-261.; Perdomo-Cárdenas et al., 2021Perdomo‐Cárdenas, V.; Patiño‐Holguín, C. & Vélez‐García, J. F. 2021. Evolutionary and terminological analysis of the flexor digitorum superficialis, interflexorii and palmaris longus muscles in kinkajou (Potos flavus) and crab‐eating racoon (Procyon cancrivorus). Anatomia Histologia Embryologia 50(3):520-533.). However, the presentation of a m. palmaris longus in carnivorans is also associated to a palmigrade or semipalmigrade locomotion (Perdomo-Cárdenas et al., 2021Perdomo‐Cárdenas, V.; Patiño‐Holguín, C. & Vélez‐García, J. F. 2021. Evolutionary and terminological analysis of the flexor digitorum superficialis, interflexorii and palmaris longus muscles in kinkajou (Potos flavus) and crab‐eating racoon (Procyon cancrivorus). Anatomia Histologia Embryologia 50(3):520-533.). On the other side, the rotators muscles are functionally more developed in arboreal carnivorans, while the humeral adductors and scapular adductor and protractors are more developed in terrestrial carnivorans (Taverne et al., 2018Taverne, M.; Fabre, A. C.; Herbin, M.; Herrel, A.; Peigmé, S.; Lacroux, C.; Lowi, A.; Pagès, F.; Theil, J. C. & Böhmer, C. 2018. Convergence in the functional properties of forelimb muscles in carnivorans: adaptations to an arboreal lifestyle? Biological Journal of the Linnean Society 125:250-263. ). Therefore, possible anatomical variations can also be found in species with different locomotion habits.

The movements of the different types of locomotion are generated by the contraction of the different muscle groups and the functioning of the peripheral nervous system. This innervates the muscles, providing the opportunity for chemical energy to be transformed into mechanical energy, resulting in the production of various movements (Paranaiba et al., 2012Paranaiba, J. F.; Helrigle, C.; Araújo, E. G. D. & Pereira, K. F. 2012. Aspectos morfológicos da mão e pé de Procyon cancrivorus. Natureza on line 10(4):165-169. ). The function of the thoracic limb muscles is fundamental to the animal capturing food, mating, and defending itself. These needs vary according to their habits of life, showing how fundamental is the study of the functional anatomy of different species (Aversi-Ferreira et al., 2005Aversi-Ferreira, T. A.; Aversi-Ferreira, R. A.; Silva, Z.; Gouvêa E Silva, L. F. & Penha-Silva, N. 2005. Estudo anatômico de músculos profundos do antebraço de Cebus apella (Linnaeus, 1766). Acta Scientiarum, Biological Sciences 27:297-301. ). The thoracic limbs, specifically the craniolateral muscles of the forearm, have functions of supination of the manus, extension of digits, and adduction and abduction of the carpus (Hermanson et al., 2013Hermanson, J. W. 2013. The Muscular System. In: Evans, H. E. & De Lahunta, A. eds. Miller’s anatomy of the dog. Missouri, Saunders Elsevier, p. 185-280.). Although, there are three studies about the thoracic limb muscles in P. cancrivorus (Windle, 1888Windle, B. C. 1888. Notes on the Limb Myology of Procyon cancrivorus and of the Ursidœ. Journal of Anatomy 23(1):81-89. ; Lima et al., 2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.; Santos et al., 2010aSantos, A. C.; Bertassoli, B. & Rosa, R. A. 2010a. Miologia comparada do membro torácico do mão-pelada (Procyon cancrivorus G. Cuvier, 1798). Revista da FVZA 17(2):262-275.), these do not contain a detailed description of the craniolateral forearm muscles. Among these studies, someone did not report the m. brachioradialis (Santos et al., 2010bSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ), the m. supinator (Lima et al., 2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.), and the m. extensor digiti I et II (Lima et al., 2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.; Santos et al., 2010aSantos, A. C.; Bertassoli, B. & Rosa, R. A. 2010a. Miologia comparada do membro torácico do mão-pelada (Procyon cancrivorus G. Cuvier, 1798). Revista da FVZA 17(2):262-275.,bSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ). The detailed knowledge of these muscles will give an anatomical basis allowing the performance of surgical procedures of the distal part of the humerus, and the entire length of the radius and the ulna. Also, this knowledge would be useful to evolutionary studies, such as muscular reconstructions in fossil procyonids (Tarquini et al., 2019Tarquini, J.; Morgan, C. C.; Toledo, N. & Soibelzon, L. H. 2019. Comparative osteology and functional morphology of the forelimb of Cyonasua (Mammalia, Procyonidae), the first South American carnivoran. Journal of Morphology 280:446-470. ; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). Thus, the main objective was to analyze the intra- and interspecific differences of the craniolateral forearm muscles of P. cancrivorus.

MATERIAL AND METHODS

Specimens and fixation process. Four specimens of P. carnivorous (two juvenile females and two adult males) that died of natural causes were used. These specimens remain at the amphitheater of Veterinary Anatomy of the Universidad del Tolima. One male with skin and one female without skin were donated by CORPOCALDAS (Corporación Autónoma Regional de Caldas, environmental authority of Caldas-Colombia) to the Universidad de Caldas; and two necropsied specimens (a juvenile female and an adult male) were donated by CORTOLIMA (Corporación Autónoma Regional del Tolima environmental authority of Tolima-Colombia). The specimens were fixed with intramuscular and subcutaneous infiltrations of a solution of 10% formaldehyde and 20% glycerin, and then submerged in a solution of 5% formaldehyde. In one of the females, arterial repletion was performed with latex dyed with red vinyl through the axillary arteries. This study was approved by the bioethics committee of the Universidad del Tolima (2.3-059).

Dissection and documentation. Gross dissections of both thoracic limbs were performed base on Evans & De Lahunta (2017Evans, H. E. & De Lahunta, A. 2017. Guide to the Dissection of the Dog. 5ed. St. Louis Missouri, Elsevier Health Sciences. 327p.). The origin, insertion, innervation, and arterial supply of each muscle were described according to the Nomina Anatomica Veterinaria (Icvgan, 2017Icvgan - International Committee On Veterinary Gross Anatomical Nomenclature. 2017. Nomina Anatomica Veterinaria. 6ed. Hannover, World Association of Veterinary Anatomists. 160p.). Photographic records of dissections were taken with a Canon EOS Rebel T5i 18 MP camera associated with a macro lens of 60 mm and a Canon 6D associated with a macro lens of 100 mm.

RESULTS

The m. brachioradialis was fusiform and flattened, with a fleshy origin from the proximal extreme of the lateral supracondylar crest of the humerus, and it was inserted by a tendon onto the proximal part of the styloid process of the radius (Figs 1, 2 and 4). It was innervated by the deep branch of the radial nerve (Fig. 5 and supplied by the collateral radial and transverse cubital arteries.

Fig. 1.
Cranial view of a left forearm (a), and lateral view of a left forearm (b). 1, m. brachioradialis; 2, m. extensor carpi radialis; 2’, cranial belly; 2”, caudal belly; 3, m. extensor digitorum communis; 3’, tendon; 4, m. extensor digitorum lateralis; 4’, tendon of insertion of the m. extensor digitorum lateralis; 5, m. extensor carpi ulnaris; 5’, tendon 6, m. abductor digiti i longus; 7; retinaculum extensor.

Fig. 2.
Lateral views of a left forearm where the m. extensor digitorum communis had been retracted toward caudal to see the bellies of the m. extensor carpi radialis. 1, m. brachioradialis; 2, m. extensor carpi radialis; 2’, cranial belly; 2”, caudal belly; 3, m. extensor digitorum communis; 3’, tendon; 4, m. extensor digitorum lateralis; 4’, tendon of insertion of the m. extensor digitorum lateralis; 5, m. extensor carpi ulnaris; 6, m. abductor digiti i longus.

The m. extensor carpi radialis (Figs 1-3) had a fleshy origin from the two distal thirds of the medial aspect of the lateral supracondylar crest of the humerus and the proximal fifth of the intermuscular septum with the m. extensor digitorum communis, which covered superficially the origin of the m. extensor carpi radialis. Two muscular bellies (cranial and caudal; Fig. 2) were formed from the proximal third of the forearm, the cranial belly was fusiform, and the caudal belly was bipennate. The cranial belly formed a tendon from the middle third of the forearm, whilst the caudal belly was free of muscle fibers from the distal third of the forearm. Both tendons passed deep to the tendon of the m. abductor digiti I longus. The tendon of the cranial belly inserted onto the dorsal surface of the base of metacarpal bone II, and the caudal belly onto the dorsal surface of the base of metacarpal bone III (Fig. 3). It was innervated by two branches of the deep branch of radial nerve (Fig. 5). Both bellies were supplied by the transverse cubital artery (Fig. 5), and the caudal belly also by a branch of the cranial interosseous artery.

Fig. 3.
Dorsal view of a left hand, dorsal view of a right hand (b), deep dorsal view of a left hand (c). 1, Extensor digitorum communis tendon; 1’, tendon to the digit I; 2, extensor digiti I et II tendons; 2’, medial tendon, 2”, lateral tendon; 3, extensor digitorum lateralis tendons; 3’, medial; 3”, intermediate; 3”’, lateral; 4, extensor carpi radialis tendon; 4’, tendon of the cranial belly; 4”, tendon of the caudal belly; 5, retinaculum extensor.

Fig. 4.
Deep lateral views of a two left forearms (a-b), and deep cranial view of a left forearm (c). 1, m. brachioradialis; 2, m. extensor carpi radialis; 3, m. supinator; 4, m. abductor digiti I longus; 4’, tendon; 5, m. extensor digiti I et II; 5’, medial tendon; 5”, lateral tendon; 6, m. extensor carpi ulnaris.

Fig. 5.
Lateral view of a left forearm where the m. brachioradialis had been retracted toward medial (a), and lateral view of a left forearm (b). 1, m. brachioradialis; 2, m. extensor carpi radialis; 3, m. extensor digitorum communis; 4, m. extensor digitorum lateralis; 5, m. extensor carpi ulnaris; 6, cranial interosseous artery; 7, m. supinator; 8, transverse cubital artery; 1’, 2’, 7’, branches of the deep branch of radial nerve to the respective muscle.

The m. extensor digitorum communis (Figs 1, 2 and 5) originated via fleshy and tendinous fibers from the lateral aspect of the distal third of the lateral supracondylar crest of the humerus, the lateral epicondyle of the humerus, and the adjacent intermuscular septa (m. extensor carpi radialis and m. extensor digitorum lateralis). This muscle formed a deep common tendon with the m. extensor digitorum lateralis, which originated from the lateral epicondyle of the humerus. In two specimens, muscle fibers originating from the antebrachial fascia were observed. In the middle of the forearm, four tendons were formed, but these were only free of fleshy fibers from the distal quarter of the forearm. Each tendon was inserted onto the extensor process of the distal phalanges of the digits II-V (Figs 3). In one thoracic limb of two specimens, the medial tendon sent a fascicle to the digit I (unilaterally), which joined to the medial tendon of the m. extensor digiti I et II. The muscle was innervated by the deep branch of radial nerve and supplied by the cranial interosseous and transverse cubital arteries (Fig. 5).

The m. extensor digitorum lateralis had a fleshy and tendinous origin from the lateral epicondyle of the humerus, intermuscular septum with the m. extensor digitorum communis, antebrachial fascia, and lateral collateral ligament of the elbow. It also had a common deep origin tendon with the m. extensor digitorum communis, which originated from the lateral epicondyle of the humerus (Fig. 1). In one specimen, the origin from the antebrachial fascia was not observed. Distally, the muscle formed three tendons that extended to the digits III-V, which joined the extensor digitorum communis tendons (Fig. 3). It was innervated by the deep branch of the radial nerve and was supplied by the cranial interosseous artery (Figs 1, 5).

The m. extensor carpi ulnaris was fusiform, originated via a tendon from the distal extreme of the lateral epicondyle of the humerus. It formed a flat tendon in the distal third of the forearm (Figs 1, 2), which inserted onto the base of the metacarpal V and the accessory carpal bone (Figs 4, 5). There was a synovial bursa at the level of the cranial surface of the styloid process of the ulna, which protected its tendon. In a left forearm, the muscle presented an ulnar head, which originated from the three middle fifths of the caudal part of the lateral surface of ulna (just caudal to the ulnar origin of the m. abductor digiti I longus) (Fig. 6). It was innervated by the deep branch of the radial nerve and was supplied by the cranial interosseous artery (Fig. 5).

Fig. 6.
Lateral view of a left forearm where the m. extensor carpi ulnaris had been retracted toward cranial. 1, m. extensor carpi ulnaris; 1”, ulnar head (variant accessory head) of the m. extensor carpi ulnaris; 2, M. extensor digiti I et II; 3, M. abductor digiti I longus.

The m. abductor digiti I longus (Figs 1, 2, 4) was bipennate and had a wide fleshy origin from the middle third of the lateral margin of the radius, along the antebrachial interosseous ligament, the antebrachial interosseous membrane, and the lateral surface of the ulna. In two specimens, its origin was also observed from the lateral collateral ligament of the elbow. It inserted by a tendon onto the medial surface of the base of the metacarpal I and the sesamoid bone (Fig. 4). Its tendon passed superficially to the tendons of m. extensor carpi radialis. It was innervated by the deep branch of the radial nerve and was supplied by the cranial and caudal interosseous arteries.

The m. extensor digiti I et II had two bellies, which originated from the caudal part of the lateral surface of the ulna and the epimysium of the m. abductor digiti I longus (Fig. 4). It formed two tendons, one medial and one lateral, the medial tendon extended to the digit I and the abaxial surface of the digit II; and the lateral tendon extended to the axial surface of the digit II and the abaxial surface of digit III. Both tendons joined with the extensor digitorum communis tendons at the level of the metacarpophalangeal joint (Figs 3, 4). It was innervated by the deep branch of the radial nerve and was supplied by the cranial interosseous artery.

The m. supinator was fusiform with a tendinous origin from the lateral epicondyle of the humerus, the annular radial ligament, and the lateral collateral ligament of the elbow. It had a fleshy insertion onto the proximal third of the cranial surface, lateral, and medial margins of the radius (Fig. 4). It was innervated by the deep branch of the radial nerve (Fig. 5) and supplied by the transverse cubital and cranial interosseous arteries.

DISCUSSION

Comparative myology. The m. brachioradialis of the specimens of P. cancrivorus in the current study had the same attachments reported by other authors (Windle, 1888Windle, B. C. 1888. Notes on the Limb Myology of Procyon cancrivorus and of the Ursidœ. Journal of Anatomy 23(1):81-89. ; Lima et al., 2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.; Souza-Junior et al., 2015Souza-Junior, P. D.; Dos Santos, L. M.; Nogueira, D. M., Abidu-Figueiredo, M. & Santos, A. L. 2015. Occurrence and morphometrics of the brachioradialis muscle in wild carnivorans (Carnivora: Caniformia, Feliformia). Zoologia 32(1):23-32. ). Although Santos et al. (2010aSantos, A. C.; Bertassoli, B. & Rosa, R. A. 2010a. Miologia comparada do membro torácico do mão-pelada (Procyon cancrivorus G. Cuvier, 1798). Revista da FVZA 17(2):262-275.,bSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ) did not mention the m. brachioradialis, this muscle was present on their figures. Therefore, the brachioradialis is a common muscle in P. cancrivorus as in other procyonids (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Allen, 1882Allen, H. 1882. The muscles of the limbs of the raccoon (Procyon lotor). Proceedings of the Academy of Natural Sciences of Philadelphia 34(2):115-144. ; Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ; Julitz, 1909Julitz, C. 1909. Osteologie und myologie der Extremitäten und des Wickelschwanzes vom Wickelbären, Cercoleptes caudivolvulus, mit besondere Berücksichtigung der Anpassungserscheinungen an das Baumleben. Archiv für Naturgeschichte Berlin 75:143-188.; Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.; Souza-Junior et al., 2015Souza-Junior, P. D.; Dos Santos, L. M.; Nogueira, D. M., Abidu-Figueiredo, M. & Santos, A. L. 2015. Occurrence and morphometrics of the brachioradialis muscle in wild carnivorans (Carnivora: Caniformia, Feliformia). Zoologia 32(1):23-32. , 2021Souza-Junior, P.; De Souza Pahim, A. B.; Viotto‐Souza, W.; Pellenz, J.; Bernardes, F. C. S.; Abidu‐Figueiredo, M. & Santos, A. L. Q. 2021. Evolutionary history or function? Which preponderates in the expression of the muscle mass of the thoracic limb in wild carnivorans? The Anatomical Record 304(36):1344-1356. ; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.), mustelids (Macalister, 1873Macalister, A. 1873. On the anatomy of Aonyx. Proceedings of the Royal Irish Academy 1:539-547.; Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ; Leach, 1976Leach, D. 1976. The forelimb musculature of marten (Martes americana Turton) and fisher (Martes pennanti Erxleben). Canadian Journal of Zoology 55(1):31-41. ; Moore et al., 2013Moore, A. L.; Budny, J. E.; Russell, A. P. & Butcher, M. T. 2013. Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus). Journal of Morphology 274(1):35-48. ; Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.; Souza-Junior et al., 2015Souza-Junior, P. D.; Dos Santos, L. M.; Nogueira, D. M., Abidu-Figueiredo, M. & Santos, A. L. 2015. Occurrence and morphometrics of the brachioradialis muscle in wild carnivorans (Carnivora: Caniformia, Feliformia). Zoologia 32(1):23-32. ; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.), ailurids (Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ), ursids (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ; Shepherd, 1883Shepherd, F. J. 1883. Short notes on the myology of the American black bear (Ursus americanus). Journal of Anatomy 18:103-117. ; Kelley, 1888Kelley, E. A. 1888. Notes on the myology of Ursus maritimus. The Proceedings of the Academy of Natural Sciences of Philadelphia 40:141-154. ; Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ; Davis, 1964Davis, D. 1964. The giant panda a morphological study of evolutionary mechanisms. Chicago, Natural History Museum Chicago 3:1-339.), herpestids (Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ), felids (Beswick-Perrin, 1871Beswick-Perrin, J. 1871. On the myology of the limbs of the kinkajou (Cercoleptes caudivolvulus). Proceedings of the Zoological Society of London 1871:547-559.; Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ; Barone, 1967Barone, R. 1967. La myologie du lion (Panthera leo). Mammalia 31:459-514.; Concha et al., 2004Concha, I.; Adaro, L.; Borroni, C. & Altamirano, C. 2004. Consideraciones anatómicas sobre la musculatura intrínseca del miembro torácico del puma (Puma concolor). Journal of Morphology 22:121-125. ; Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.; Cuff et al., 2016Cuff, A. R.; Sparkes, E. L.; Randau, M.; Pierce S. E.; Kitchener A. C.; Goswami, A. & Hutchinson, J. R. 2016. The scaling of postcranial muscles in cats (Felidae) I: forelimb, cervical, and thoracic muscles. Journal of Anatomy 229(1):128-141. ; Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ; Nazem et al., 2017Nazem, M. N.; Sajjadian, S. M. & Nakhaei, A. 2017. Anatomy, functional anatomy and morphometrical study of forelimb column in Asiatic cheetah (Acinonyx jubatus venaticus). The Italian Journal of Anatomy and Embryology 3:157-172.; Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ; Ari et al., 2019Ari, H.; Yurdakul, İ. & Aksoy, G. 2019. A macroscopic study on the muscles and tendons of forepaws in the anatolian bobcat (Lynx lynx). Slovenian Veterinary Research 56(4):153-162; Sánchez et al., 2019Sánchez, H. L.; Rafasquino, M. E. & Portiansky, E. L. 2019. Comparative anatomy of the forearm and hand of wildcat (Leopardus geoffroyi), ocelot (Leopardus pardalis) and jaguar (Panthera onca). Journal of Morphological Science 36:7-13. ), and viverrids of the genera Genetta (Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ) and Paradoxurus (Beswick-Perrin, 1871Beswick-Perrin, J. 1871. On the myology of the limbs of the kinkajou (Cercoleptes caudivolvulus). Proceedings of the Zoological Society of London 1871:547-559.). Whilst, it is a small or absent muscle in canids (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ; Vaz et al., 2011Vaz, M. G. R.; De Lima, A. R.; De Souza, A. C. B.; Pereira, L. C. & Branco, E. 2011. Estudo morfológico dos músculos do antebraço de cachorro-do-mato-de-orelhas-curtas (Atelocynus microtis) e cachorro-do-mato (Cerdocyon thous). Biotemas 24(4):121-127. ; Hermanson, 2013Hermanson, J. W. 2013. The Muscular System. In: Evans, H. E. & De Lahunta, A. eds. Miller’s anatomy of the dog. Missouri, Saunders Elsevier, p. 185-280.; Echeverry et al., 2015Echeverry, J. S.; Vélez, J. F. & Sánchez, C. A. 2015. Descripción anatómica de los músculos cráneo-laterales superficiales del antebrazo del zorro perruno (Cerdocyon thous). Revista Colombiana de Ciencia Animal 8(1):44-51.; Souza-Junior et al., 2015Souza-Junior, P. D.; Dos Santos, L. M.; Nogueira, D. M., Abidu-Figueiredo, M. & Santos, A. L. 2015. Occurrence and morphometrics of the brachioradialis muscle in wild carnivorans (Carnivora: Caniformia, Feliformia). Zoologia 32(1):23-32. , 2018 Souza Junior, P.; Santos, L. M. R. P. D.; Viotto‐Souza, W.; De Carvalho, N. D. C.; Souza, E. C.; Kasper, C. B.; Abidu-Figueiredo, M. & Santos, A. L. Q. 2018. Functional myology of the thoracic limb in Pampas fox (Lycalopex gymnocercus): a descriptive and comparative analysis. Journal of Anatomy 233(6):783-806.; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.; Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.), felids of the genus Acynonix (Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ; Taverne et al., 2018Taverne, M.; Fabre, A. C.; Herbin, M.; Herrel, A.; Peigmé, S.; Lacroux, C.; Lowi, A.; Pagès, F.; Theil, J. C. & Böhmer, C. 2018. Convergence in the functional properties of forelimb muscles in carnivorans: adaptations to an arboreal lifestyle? Biological Journal of the Linnean Society 125:250-263. ; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.), hyaenids (Watson & Young, 1879Watson, M. & Young, A. 1879. On the anatomy of the Hyaena crocuta (H. maculata). Journal of Zoology 47:79-107. ; Watson, 1882Watson, M. 1882. On the Muscular Anatomy of Proteles as compared with that of Hyeena and Viverra. Journal of Zoology 50(3):579-586. ; Spoor & Badoux, 1986Spoor, C. F. & Badoux, D. M. 1986. Descriptive and functional myology of the neck and forelimb of the striped hyena (Hyaena hyaena, L. 1758). Anatomischer Anzeiger 161:375-387.; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.), and viverrids of the genus Civettictis (Devis, 1868Devis, C. W. 1868. Notes on the myology of Viverra civetta. Journal of Anatomy 2:207-217. ; Young, 1880Young, A. H. 1880. Myology of Viverra civetta. Journal of Anatomy 14:166-177. ; Macalister, 1873Macalister, A. 1873. On the anatomy of Aonyx. Proceedings of the Royal Irish Academy 1:539-547.; Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ). In mustelids of the family Ictonychidae and subfamily Lutrinae, the origin is from the proximal third of the humerus (Windle & Parsons, 1897Souza-Junior, P. D.; Dos Santos, L. M.; Nogueira, D. M., Abidu-Figueiredo, M. & Santos, A. L. 2015. Occurrence and morphometrics of the brachioradialis muscle in wild carnivorans (Carnivora: Caniformia, Feliformia). Zoologia 32(1):23-32. ; Howard, 1973Howard, L. D. 1973. Muscular anatomy of the forelimb of the sea otter (Enhydra lutris). Proceedings of the California Academy of Sciences 39(20):411-500. ; Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.; Souza-Junior et al., 2015Souza-Junior, P. D.; Dos Santos, L. M.; Nogueira, D. M., Abidu-Figueiredo, M. & Santos, A. L. 2015. Occurrence and morphometrics of the brachioradialis muscle in wild carnivorans (Carnivora: Caniformia, Feliformia). Zoologia 32(1):23-32. ), while it originates only from the middle third in Galictis cuja (Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.), or from the cranial aspect of the lateral epicondyle in Taxidea taxus (Moore et al., 2013Moore, A. L.; Budny, J. E.; Russell, A. P. & Butcher, M. T. 2013. Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus). Journal of Morphology 274(1):35-48. ). In the ailurid Ailurus fulgens, it has two heads, in which one originates from the lateral supracondylar crest and the other from the m. brachialis (Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ). In ursids, it can also have two heads similar to Ailurus, such as Ursus maritimus (Kelley, 1888Kelley, E. A. 1888. Notes on the myology of Ursus maritimus. The Proceedings of the Academy of Natural Sciences of Philadelphia 40:141-154. ) and Ailuropoda melanoleuca (Davis, 1964Davis, D. 1964. The giant panda a morphological study of evolutionary mechanisms. Chicago, Natural History Museum Chicago 3:1-339.), whereas Ursus americanus only has one head from the lateral supracondylar crest (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ; Shepherd, 1883Shepherd, F. J. 1883. Short notes on the myology of the American black bear (Ursus americanus). Journal of Anatomy 18:103-117. ). The origin of the m. brachioradialis in felids reaches the middle third of the humerus (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.; Concha et al., 2004Concha, I.; Adaro, L.; Borroni, C. & Altamirano, C. 2004. Consideraciones anatómicas sobre la musculatura intrínseca del miembro torácico del puma (Puma concolor). Journal of Morphology 22:121-125. ; Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ; Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ; Ari et al., 2019Ari, H.; Yurdakul, İ. & Aksoy, G. 2019. A macroscopic study on the muscles and tendons of forepaws in the anatolian bobcat (Lynx lynx). Slovenian Veterinary Research 56(4):153-162; Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ), however, it could originate from the proximal third in Panthera and Leopardus (Barone, 1967Barone, R. 1967. La myologie du lion (Panthera leo). Mammalia 31:459-514.; Sánchez et al., 2019Sánchez, H. L.; Rafasquino, M. E. & Portiansky, E. L. 2019. Comparative anatomy of the forearm and hand of wildcat (Leopardus geoffroyi), ocelot (Leopardus pardalis) and jaguar (Panthera onca). Journal of Morphological Science 36:7-13. ; Smith et al., 2021Smith, H. F.; Townsend, K. B.; Adrian, B.; Levy, S.; Marsh, S.; Hassur, R.; Manfredi, K. & Echols, M. S. 2021. Functional adaptations in the forelimb of the snow leopard (Panthera uncia). Integrative and Comparative Biology 61(5):1852-1866. ) or only from the lateral supracondylar crest in Caracal, Acynonyx and Leopardus (Beswick-Perrin, 1871Beswick-Perrin, J. 1871. On the myology of the limbs of the kinkajou (Cercoleptes caudivolvulus). Proceedings of the Zoological Society of London 1871:547-559.; Hudson et al., 2011Hudson, P. E.; Corr, S. A.; Payne‐Davis, R. C.; Clancy, S. N.; Lane, E. & Wilson, A. M. 2011. Functional anatomy of the cheetah (Acinonyx jubatus) forelimb. Journal of Anatomy 218(4):375-385. ; Souza-Junior et al., 2015Souza-Junior, P. D.; Dos Santos, L. M.; Nogueira, D. M., Abidu-Figueiredo, M. & Santos, A. L. 2015. Occurrence and morphometrics of the brachioradialis muscle in wild carnivorans (Carnivora: Caniformia, Feliformia). Zoologia 32(1):23-32. ). Carnivorans present few variants in the insertion of m. brachioradialis, however, there are some differences, such as in herpestids (Ichneumia albicauda and Herpestes ichneumon), since the m. brachioradialis inserts onto the cranial surface of the distal extreme of the radius (Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ); in Ailurus it also inserts onto the m. pronator teres (Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ); in Leopardus pardalis, Leopardus. geoffroyi and Panthera onca it also inserts onto the proximal row of the carpus (Sánchez et al., 2019Sánchez, H. L.; Rafasquino, M. E. & Portiansky, E. L. 2019. Comparative anatomy of the forearm and hand of wildcat (Leopardus geoffroyi), ocelot (Leopardus pardalis) and jaguar (Panthera onca). Journal of Morphological Science 36:7-13. ) or in Lynx lynx only onto the radial carpal bone (Ari et al., 2019Ari, H.; Yurdakul, İ. & Aksoy, G. 2019. A macroscopic study on the muscles and tendons of forepaws in the anatolian bobcat (Lynx lynx). Slovenian Veterinary Research 56(4):153-162); and in L. pardalis onto the flexor retinaculum (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.). In the euplerid Cryptoprocta ferox, the muscle was only described as a muscle well developed (Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.).

The m. extensor carpi radialis in P. cancrivorus has been described as a single muscle (Lima et al., 2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.; Santos et al., 2010aSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ), such as occurs in other procyonid as Nasua nasua (Santos et al., 2010bSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ), some mustelids (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ; Macalister, 1873Macalister, A. 1873. On the anatomy of Aonyx. Proceedings of the Royal Irish Academy 1:539-547.; Howard, 1973Howard, L. D. 1973. Muscular anatomy of the forelimb of the sea otter (Enhydra lutris). Proceedings of the California Academy of Sciences 39(20):411-500. ; Leach, 1976Leach, D. 1976. The forelimb musculature of marten (Martes americana Turton) and fisher (Martes pennanti Erxleben). Canadian Journal of Zoology 55(1):31-41. ; Moore et al., 2013Moore, A. L.; Budny, J. E.; Russell, A. P. & Butcher, M. T. 2013. Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus). Journal of Morphology 274(1):35-48. ), canids (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ; Vaz et al., 2011Vaz, M. G. R.; De Lima, A. R.; De Souza, A. C. B.; Pereira, L. C. & Branco, E. 2011. Estudo morfológico dos músculos do antebraço de cachorro-do-mato-de-orelhas-curtas (Atelocynus microtis) e cachorro-do-mato (Cerdocyon thous). Biotemas 24(4):121-127. ; Hermanson, 2013Hermanson, J. W. 2013. The Muscular System. In: Evans, H. E. & De Lahunta, A. eds. Miller’s anatomy of the dog. Missouri, Saunders Elsevier, p. 185-280.; Echeverry et al., 2015Echeverry, J. S.; Vélez, J. F. & Sánchez, C. A. 2015. Descripción anatómica de los músculos cráneo-laterales superficiales del antebrazo del zorro perruno (Cerdocyon thous). Revista Colombiana de Ciencia Animal 8(1):44-51.; Souza-Junior et al., 2015Souza-Junior, P. D.; Dos Santos, L. M.; Nogueira, D. M., Abidu-Figueiredo, M. & Santos, A. L. 2015. Occurrence and morphometrics of the brachioradialis muscle in wild carnivorans (Carnivora: Caniformia, Feliformia). Zoologia 32(1):23-32. , 2018 Souza Junior, P.; Santos, L. M. R. P. D.; Viotto‐Souza, W.; De Carvalho, N. D. C.; Souza, E. C.; Kasper, C. B.; Abidu-Figueiredo, M. & Santos, A. L. Q. 2018. Functional myology of the thoracic limb in Pampas fox (Lycalopex gymnocercus): a descriptive and comparative analysis. Journal of Anatomy 233(6):783-806.; Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.), hyaenids (Watson & Young, 1879Watson, M. & Young, A. 1879. On the anatomy of the Hyaena crocuta (H. maculata). Journal of Zoology 47:79-107. ; Watson, 1882Watson, M. 1882. On the Muscular Anatomy of Proteles as compared with that of Hyeena and Viverra. Journal of Zoology 50(3):579-586. ; Spoor & Badoux 1986Spoor, C. F. & Badoux, D. M. 1986. Descriptive and functional myology of the neck and forelimb of the striped hyena (Hyaena hyaena, L. 1758). Anatomischer Anzeiger 161:375-387.), herpestids (Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ), viverrids (Devis, 1868Devis, C. W. 1868. Notes on the myology of Viverra civetta. Journal of Anatomy 2:207-217. ; Macalister, 1873Macalister, A. 1873. On the anatomy of Aonyx. Proceedings of the Royal Irish Academy 1:539-547.; Young, 1880Young, A. H. 1880. Myology of Viverra civetta. Journal of Anatomy 14:166-177. ; Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ), and some felids, such as Caracal caracal (Beswick-Perrin, 1871Beswick-Perrin, J. 1871. On the myology of the limbs of the kinkajou (Cercoleptes caudivolvulus). Proceedings of the Zoological Society of London 1871:547-559.), Acynonyx jubatus (Hudson et al., 2011Hudson, P. E.; Corr, S. A.; Payne‐Davis, R. C.; Clancy, S. N.; Lane, E. & Wilson, A. M. 2011. Functional anatomy of the cheetah (Acinonyx jubatus) forelimb. Journal of Anatomy 218(4):375-385. ; Nazem et al., 2017Nazem, M. N.; Sajjadian, S. M. & Nakhaei, A. 2017. Anatomy, functional anatomy and morphometrical study of forelimb column in Asiatic cheetah (Acinonyx jubatus venaticus). The Italian Journal of Anatomy and Embryology 3:157-172.; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.), and L. lynx (Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ). However, we observed two muscle bellies in the m. extensor carpi radialis of P. cancrivorus, one cranial and one caudal, which corresponded respectively to the m. extensor carpi radialis longus and m. extensor carpi radialis brevis described independently in other procyonids (without fusion), such as Procyon lotor (Allen, 1882Allen, H. 1882. The muscles of the limbs of the raccoon (Procyon lotor). Proceedings of the Academy of Natural Sciences of Philadelphia 34(2):115-144. ; Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.), N. nasua (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.), and Potos flavus (Beswick-Perrin, 1871; Julitz, 1909Julitz, C. 1909. Osteologie und myologie der Extremitäten und des Wickelschwanzes vom Wickelbären, Cercoleptes caudivolvulus, mit besondere Berücksichtigung der Anpassungserscheinungen an das Baumleben. Archiv für Naturgeschichte Berlin 75:143-188.; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). Therefore, based on the findings in P. cancrivorus, these muscles were not considered as independent muscles because they had intermixed fleshy fibers between them. Mackintosh (1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ) in Nasua narica describes that both muscle bellies are partly fused, similar to our findings in P. cancrivorus. In P. flavus, both muscles can have intermixed fibers as an anatomical variant, but in a very low proportion (Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). Some mustelids can have both independent muscles, such as Martes foina, Martes martes, Meles meles and a specimen of G. cuja (Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.; Böhmer et al., 2018Böhmer, C.; Fabre, A. C.; Taverne, M.; Herbin, M.; Peigne, S. & Herrel, A. 2018. Anatomical basis of differences in locomotor behavior in martens: a comparison of the forelimb musculature between two sympatric species of Martes. The Anatomical Record 301(3):449-472., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.). Although, both muscle bellies can be partly fused as in M. foina (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ), Eira barbara (Macalister, 1873Macalister, A. 1873. On the anatomy of Aonyx. Proceedings of the Royal Irish Academy 1:539-547.), and Enhydra lutris (Howard, 1973Howard, L. D. 1973. Muscular anatomy of the forelimb of the sea otter (Enhydra lutris). Proceedings of the California Academy of Sciences 39(20):411-500. ). Ursids such as U. americanus and U. maritimus, present a single muscle (Shepherd, 1883Shepherd, F. J. 1883. Short notes on the myology of the American black bear (Ursus americanus). Journal of Anatomy 18:103-117. ; Kelley, 1888Kelley, E. A. 1888. Notes on the myology of Ursus maritimus. The Proceedings of the Academy of Natural Sciences of Philadelphia 40:141-154. ), although it was described as two independent muscles in Ursus sp. (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ) and A. melanoleuca (Davis, 1964Davis, D. 1964. The giant panda a morphological study of evolutionary mechanisms. Chicago, Natural History Museum Chicago 3:1-339.). In Ailurus both muscle bellies are only separated on the middle of the forearm, but both can be completely separated as an anatomical variant (Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ). In felids, it was divided into two muscles (Concha et al., 2004Concha, I.; Adaro, L.; Borroni, C. & Altamirano, C. 2004. Consideraciones anatómicas sobre la musculatura intrínseca del miembro torácico del puma (Puma concolor). Journal of Morphology 22:121-125. ; Icvgan, 2017Icvgan - International Committee On Veterinary Gross Anatomical Nomenclature. 2017. Nomina Anatomica Veterinaria. 6ed. Hannover, World Association of Veterinary Anatomists. 160p.; Sánchez et al., 2019Sánchez, H. L.; Rafasquino, M. E. & Portiansky, E. L. 2019. Comparative anatomy of the forearm and hand of wildcat (Leopardus geoffroyi), ocelot (Leopardus pardalis) and jaguar (Panthera onca). Journal of Morphological Science 36:7-13. ; Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ), but both muscle bellies can be fused proximally in Felis catus (Barone, 1980Barone, R. 1980. Anatomie comparée des Mammifères Domestiques 2nd tome: Arthrologie et Myologie. Vigot, Paris. 984p. ), L. pardalis (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.), Panthera leo (Barone, 1980Barone, R. 1980. Anatomie comparée des Mammifères Domestiques 2nd tome: Arthrologie et Myologie. Vigot, Paris. 984p. ; Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ), Panthera uncia (Smith et al., 2021Smith, H. F.; Townsend, K. B.; Adrian, B.; Levy, S.; Marsh, S.; Hassur, R.; Manfredi, K. & Echols, M. S. 2021. Functional adaptations in the forelimb of the snow leopard (Panthera uncia). Integrative and Comparative Biology 61(5):1852-1866. ), Panthera tigris (Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ), and L. lynx (Ari et al., 2019Ari, H.; Yurdakul, İ. & Aksoy, G. 2019. A macroscopic study on the muscles and tendons of forepaws in the anatolian bobcat (Lynx lynx). Slovenian Veterinary Research 56(4):153-162); even the brevis belly may be fused with the m. extensor digitorum communis in L. pardalis (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.). Although, in P. leo both muscles were reported independently, similar to that described in the hyaenid Hyena hyaena and the herpestid H. auropunctatus (Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.).

The origin of the m. extensor digitorum communis of P. cancrivorus was similar to that observed by Lima et al. (2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.), however these authors did not report the origin from the intermuscular septa. Other authors only reported the origin from the lateral epicondyle of the humerus (Santos et al., 2010aSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ), similar to that observed in other procyonids such as N. nasua (Santos et al., 2010bSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ), N. narica (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ), and P. flavus (Julitz, 1909Julitz, C. 1909. Osteologie und myologie der Extremitäten und des Wickelschwanzes vom Wickelbären, Cercoleptes caudivolvulus, mit besondere Berücksichtigung der Anpassungserscheinungen an das Baumleben. Archiv für Naturgeschichte Berlin 75:143-188.; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). Although in P. flavus, origins from the adjacent intermuscular septa have also been reported (Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). Other studies in procyonids reported a restricted origin from the lateral supracondylar crest of the humerus in P. lotor (Allen, 1882Allen, H. 1882. The muscles of the limbs of the raccoon (Procyon lotor). Proceedings of the Academy of Natural Sciences of Philadelphia 34(2):115-144. ; Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.), N. nasua and N. narica (Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.). In mustelids, it can originate only from the lateral supracondylar crest (Leach, 1976Leach, D. 1976. The forelimb musculature of marten (Martes americana Turton) and fisher (Martes pennanti Erxleben). Canadian Journal of Zoology 55(1):31-41. ; Böhmer et al., 2018Böhmer, C.; Fabre, A. C.; Taverne, M.; Herbin, M.; Peigne, S. & Herrel, A. 2018. Anatomical basis of differences in locomotor behavior in martens: a comparison of the forelimb musculature between two sympatric species of Martes. The Anatomical Record 301(3):449-472.) or from lateral epicondyle (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Moore et al., 2013Moore, A. L.; Budny, J. E.; Russell, A. P. & Butcher, M. T. 2013. Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus). Journal of Morphology 274(1):35-48. ), whereas G. cuja and E. lutris has both origins (Howard, 1973Howard, L. D. 1973. Muscular anatomy of the forelimb of the sea otter (Enhydra lutris). Proceedings of the California Academy of Sciences 39(20):411-500. ; Ercoli et al, 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.), similar to that observed in P. cancrivorus. In A. fulgens, it only originates from the lateral epicondyle, however, it can originate from the m. extensor carpi radialis brevis or be fused with the m. extensor digitorum lateralis as anatomical variants (Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ). In Ursus, the m. extensor digitorum communis originates from the lateral epicondyle (Shepherd, 1883Shepherd, F. J. 1883. Short notes on the myology of the American black bear (Ursus americanus). Journal of Anatomy 18:103-117. ; Kelley, 1888Kelley, E. A. 1888. Notes on the myology of Ursus maritimus. The Proceedings of the Academy of Natural Sciences of Philadelphia 40:141-154. ), while in Ailuropoda it originates from the lateral supracondylar crest and it is proximally inseparable to the adjacent muscles (Davis, 1964Davis, D. 1964. The giant panda a morphological study of evolutionary mechanisms. Chicago, Natural History Museum Chicago 3:1-339.). In canids, it originates from the lateral epicondyle (Vaz et al., 2011Vaz, M. G. R.; De Lima, A. R.; De Souza, A. C. B.; Pereira, L. C. & Branco, E. 2011. Estudo morfológico dos músculos do antebraço de cachorro-do-mato-de-orelhas-curtas (Atelocynus microtis) e cachorro-do-mato (Cerdocyon thous). Biotemas 24(4):121-127. ; Hermanson, 2013Hermanson, J. W. 2013. The Muscular System. In: Evans, H. E. & De Lahunta, A. eds. Miller’s anatomy of the dog. Missouri, Saunders Elsevier, p. 185-280.; Souza-Junior et al., 2018 Souza Junior, P.; Santos, L. M. R. P. D.; Viotto‐Souza, W.; De Carvalho, N. D. C.; Souza, E. C.; Kasper, C. B.; Abidu-Figueiredo, M. & Santos, A. L. Q. 2018. Functional myology of the thoracic limb in Pampas fox (Lycalopex gymnocercus): a descriptive and comparative analysis. Journal of Anatomy 233(6):783-806.; Liebich et al., 2020Liebich, H. G.; Maierl, J. & König, H. E. 2020 Forelimb or thoracic limb (Membra thoracica). In: König, H. E. & Liebich, H. G. eds. Veterinary Anatomy of Domestic Mammals: Text Book and Colour Atlas. New York, Thieme, p. 171-242.; Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.), however it also originates from the intermuscular septum with the m. extensor carpi radialis and antebrachial fascia in Canis lupus familiaris (Hermanson et al., 2013Hermanson, J. W. 2013. The Muscular System. In: Evans, H. E. & De Lahunta, A. eds. Miller’s anatomy of the dog. Missouri, Saunders Elsevier, p. 185-280.) and also from the articular capsule of the elbow in Cerdocyon thous (Echeverry et al., 2015Echeverry, J. S.; Vélez, J. F. & Sánchez, C. A. 2015. Descripción anatómica de los músculos cráneo-laterales superficiales del antebrazo del zorro perruno (Cerdocyon thous). Revista Colombiana de Ciencia Animal 8(1):44-51.). In most felids, it originates from the lateral epicondyle, while in some species it originates from the lateral supracondylar crest, such as in L. pardalis (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.), A. jubatus (Hudson et al., 2011Hudson, P. E.; Corr, S. A.; Payne‐Davis, R. C.; Clancy, S. N.; Lane, E. & Wilson, A. M. 2011. Functional anatomy of the cheetah (Acinonyx jubatus) forelimb. Journal of Anatomy 218(4):375-385. ; Nazem et al., 2017Nazem, M. N.; Sajjadian, S. M. & Nakhaei, A. 2017. Anatomy, functional anatomy and morphometrical study of forelimb column in Asiatic cheetah (Acinonyx jubatus venaticus). The Italian Journal of Anatomy and Embryology 3:157-172.), P. leo (Barone, 1967Barone, R. 1967. La myologie du lion (Panthera leo). Mammalia 31:459-514.; Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ), P. uncia (Smith et al., 2021Smith, H. F.; Townsend, K. B.; Adrian, B.; Levy, S.; Marsh, S.; Hassur, R.; Manfredi, K. & Echols, M. S. 2021. Functional adaptations in the forelimb of the snow leopard (Panthera uncia). Integrative and Comparative Biology 61(5):1852-1866. ), and P. tigris (Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ). In L. lynx, the muscle can originate from the lateral epicondyle of the humerus (Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ) and lateral supracondylar crest (Ari et al., 2019Ari, H.; Yurdakul, İ. & Aksoy, G. 2019. A macroscopic study on the muscles and tendons of forepaws in the anatolian bobcat (Lynx lynx). Slovenian Veterinary Research 56(4):153-162), and it also has other origins either from the lateral margin of the radius (Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ), or from the ulna and olecranon (Ari et al., 2019), which is uncommon in carnivorans. In hyaenids and viverrids it originates from the lateral epicondyle (Devis, 1868Devis, C. W. 1868. Notes on the myology of Viverra civetta. Journal of Anatomy 2:207-217. ; Watson & Young, 1879Watson, M. & Young, A. 1879. On the anatomy of the Hyaena crocuta (H. maculata). Journal of Zoology 47:79-107. ; Young, 1880Young, A. H. 1880. Myology of Viverra civetta. Journal of Anatomy 14:166-177. ; Watson, 1882Watson, M. 1882. On the Muscular Anatomy of Proteles as compared with that of Hyeena and Viverra. Journal of Zoology 50(3):579-586. ; Spoor & Badoux 1986Spoor, C. F. & Badoux, D. M. 1986. Descriptive and functional myology of the neck and forelimb of the striped hyena (Hyaena hyaena, L. 1758). Anatomischer Anzeiger 161:375-387.). In C. crocuta, it also originates from the intermuscular septum (Watson & Young, 1879Watson, M. & Young, A. 1879. On the anatomy of the Hyaena crocuta (H. maculata). Journal of Zoology 47:79-107. ), whereas Taylor (1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ) observed in the viverrid Genetta and herpestids an origin from the lateral supracondylar crest. The m. extensor digitorum communis extends tendons to the digits II-V in most carnivorans, however it also extends a tendon to the digit I in M. foina (Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.), and L. lynx (Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ). Although in L. lynx that tendon can be absent (Ari et al., 2019), thus the tendon for the digit I is an anatomical variant in this species, being similar to that reported in P. leo (Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ) and the findings of this study in P. cancrivorus.

The origin of the m. extensor digitorum lateralis in P. cancrivorus has been reported from the lateral ligament of the elbow and the lateral tuberosity of the radius (Lima et al., 2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.), or from the lateral epicondyle of the humerus (Santos et al., 2010aSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ). This partially agrees with our findings, since the origin from the radius was not found, and the origins from the intermuscular septum and the antebrachial fascia was not reported by those studies. In P. flavus, the muscle also originates from the lateral collateral ligament of the elbow and intermuscular septum (Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.), similar to P. cancrivorus. In other procyonids, it only originates from the lateral epicondyle (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.; Santos et al., 2010bSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ) or the lateral supracondylar crest in P. lotor (Allen, 1882Allen, H. 1882. The muscles of the limbs of the raccoon (Procyon lotor). Proceedings of the Academy of Natural Sciences of Philadelphia 34(2):115-144. ). However, the muscle sends tendons to the digits III to V in all procyonids (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Allen, 1882; Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.; Lima et al., 2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.; Santos et al., 2010aSantos, A. C.; Bertassoli, B. & Rosa, R. A. 2010a. Miologia comparada do membro torácico do mão-pelada (Procyon cancrivorus G. Cuvier, 1798). Revista da FVZA 17(2):262-275.,bSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). In N. narica, it can form two muscles, one lateral that only extends to the digit V, and one medial that extends to the digits III and IV (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ). This disposition of N. narica can also occur in some mustelids, such as Aonyx (Macalister, 1870), G. cuja (Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.), and T. taxus (Moore et al., 2013Moore, A. L.; Budny, J. E.; Russell, A. P. & Butcher, M. T. 2013. Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus). Journal of Morphology 274(1):35-48. ), whereas one muscle extends tendons to the digits III-V in E. barbara (Macalister, 1873Macalister, A. 1873. On the anatomy of Aonyx. Proceedings of the Royal Irish Academy 1:539-547.), M. foina and M. meles (Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.). In Martes americana and Pekania penannti, it originates from the lateral epicondyle and the lateral proximal side of the radius (Leach et al., 1976Leach, D. 1976. The forelimb musculature of marten (Martes americana Turton) and fisher (Martes pennanti Erxleben). Canadian Journal of Zoology 55(1):31-41. ); whereas in M. foina and M. martes, it originates from the lateral supracondylar crest and only extends to the digits IV and V (Böhmer et al., 2018Böhmer, C.; Fabre, A. C.; Taverne, M.; Herbin, M.; Peigne, S. & Herrel, A. 2018. Anatomical basis of differences in locomotor behavior in martens: a comparison of the forelimb musculature between two sympatric species of Martes. The Anatomical Record 301(3):449-472.). In E. lutris, it originates from the lateral supracondylar crest and lateral epicondyle, and extends tendons to the digits IV and V (Howard, 1973Howard, L. D. 1973. Muscular anatomy of the forelimb of the sea otter (Enhydra lutris). Proceedings of the California Academy of Sciences 39(20):411-500. ). In A. melanolueca, it originates from the lateral epicondyle and condyle and only extends to the digits IV and V (Davis, 1964Davis, D. 1964. The giant panda a morphological study of evolutionary mechanisms. Chicago, Natural History Museum Chicago 3:1-339.), whereas in Ursus, it only originates from the lateral epicondyle and extends to the digits III-V (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ; Shepherd, 1883Shepherd, F. J. 1883. Short notes on the myology of the American black bear (Ursus americanus). Journal of Anatomy 18:103-117. ; Kelley, 1888Kelley, E. A. 1888. Notes on the myology of Ursus maritimus. The Proceedings of the Academy of Natural Sciences of Philadelphia 40:141-154. ), being similar to Ailurus (Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ). In canids, it originates from the lateral epicondyle (Vaz et al., 2011Vaz, M. G. R.; De Lima, A. R.; De Souza, A. C. B.; Pereira, L. C. & Branco, E. 2011. Estudo morfológico dos músculos do antebraço de cachorro-do-mato-de-orelhas-curtas (Atelocynus microtis) e cachorro-do-mato (Cerdocyon thous). Biotemas 24(4):121-127. ; Echeverry et al., 2015Echeverry, J. S.; Vélez, J. F. & Sánchez, C. A. 2015. Descripción anatómica de los músculos cráneo-laterales superficiales del antebrazo del zorro perruno (Cerdocyon thous). Revista Colombiana de Ciencia Animal 8(1):44-51.; Souza-Junior et al., 2018 Souza Junior, P.; Santos, L. M. R. P. D.; Viotto‐Souza, W.; De Carvalho, N. D. C.; Souza, E. C.; Kasper, C. B.; Abidu-Figueiredo, M. & Santos, A. L. Q. 2018. Functional myology of the thoracic limb in Pampas fox (Lycalopex gymnocercus): a descriptive and comparative analysis. Journal of Anatomy 233(6):783-806.; Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.), however, it also originates from the lateral collateral ligament of the elbow in C. l. familiaris (Hermanson, 2013Hermanson, J. W. 2013. The Muscular System. In: Evans, H. E. & De Lahunta, A. eds. Miller’s anatomy of the dog. Missouri, Saunders Elsevier, p. 185-280.), C. thous (Echeverry et al., 2015Echeverry, J. S.; Vélez, J. F. & Sánchez, C. A. 2015. Descripción anatómica de los músculos cráneo-laterales superficiales del antebrazo del zorro perruno (Cerdocyon thous). Revista Colombiana de Ciencia Animal 8(1):44-51.), and Lycaon pictus (Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.). Even it also originates from the intermuscular septum with the m. extensor digitorum communis in C. thous (Echeverry et al., 2015Echeverry, J. S.; Vélez, J. F. & Sánchez, C. A. 2015. Descripción anatómica de los músculos cráneo-laterales superficiales del antebrazo del zorro perruno (Cerdocyon thous). Revista Colombiana de Ciencia Animal 8(1):44-51.). In some canids as Cuon alpinus and Vulpes vulpes, the tendon to the digit III is absent (Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.). In felids, it originates from the lateral epicondyle (Beswick-Perrin, 1871Beswick-Perrin, J. 1871. On the myology of the limbs of the kinkajou (Cercoleptes caudivolvulus). Proceedings of the Zoological Society of London 1871:547-559.; Barone, 1986; Concha et al., 2004Concha, I.; Adaro, L.; Borroni, C. & Altamirano, C. 2004. Consideraciones anatómicas sobre la musculatura intrínseca del miembro torácico del puma (Puma concolor). Journal of Morphology 22:121-125. ; Hudson et al., 2011Hudson, P. E.; Corr, S. A.; Payne‐Davis, R. C.; Clancy, S. N.; Lane, E. & Wilson, A. M. 2011. Functional anatomy of the cheetah (Acinonyx jubatus) forelimb. Journal of Anatomy 218(4):375-385. ; Nazem et al., 2017Nazem, M. N.; Sajjadian, S. M. & Nakhaei, A. 2017. Anatomy, functional anatomy and morphometrical study of forelimb column in Asiatic cheetah (Acinonyx jubatus venaticus). The Italian Journal of Anatomy and Embryology 3:157-172.; Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ; Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ; Smith et al., 2021Smith, H. F.; Townsend, K. B.; Adrian, B.; Levy, S.; Marsh, S.; Hassur, R.; Manfredi, K. & Echols, M. S. 2021. Functional adaptations in the forelimb of the snow leopard (Panthera uncia). Integrative and Comparative Biology 61(5):1852-1866. ; Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ), or the lateral supracondylar crest (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.; Sánchez et al., 2019Sánchez, H. L.; Rafasquino, M. E. & Portiansky, E. L. 2019. Comparative anatomy of the forearm and hand of wildcat (Leopardus geoffroyi), ocelot (Leopardus pardalis) and jaguar (Panthera onca). Journal of Morphological Science 36:7-13. ; Liebich et al., 2020Liebich, H. G.; Maierl, J. & König, H. E. 2020 Forelimb or thoracic limb (Membra thoracica). In: König, H. E. & Liebich, H. G. eds. Veterinary Anatomy of Domestic Mammals: Text Book and Colour Atlas. New York, Thieme, p. 171-242.), however in L. pardalis it also originates from the m. supinator (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.). On the other side, the muscle sends tendons to the digits III to V in all felids (Beswick-Perrin, 1871Beswick-Perrin, J. 1871. On the myology of the limbs of the kinkajou (Cercoleptes caudivolvulus). Proceedings of the Zoological Society of London 1871:547-559.; Barone, 1986; Concha et al., 2004Concha, I.; Adaro, L.; Borroni, C. & Altamirano, C. 2004. Consideraciones anatómicas sobre la musculatura intrínseca del miembro torácico del puma (Puma concolor). Journal of Morphology 22:121-125. ; Hudson et al., 2011Hudson, P. E.; Corr, S. A.; Payne‐Davis, R. C.; Clancy, S. N.; Lane, E. & Wilson, A. M. 2011. Functional anatomy of the cheetah (Acinonyx jubatus) forelimb. Journal of Anatomy 218(4):375-385. ; Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.; Nazem et al., 2017Nazem, M. N.; Sajjadian, S. M. & Nakhaei, A. 2017. Anatomy, functional anatomy and morphometrical study of forelimb column in Asiatic cheetah (Acinonyx jubatus venaticus). The Italian Journal of Anatomy and Embryology 3:157-172.; Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ; Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ; Ari et al., 2019Ari, H.; Yurdakul, İ. & Aksoy, G. 2019. A macroscopic study on the muscles and tendons of forepaws in the anatolian bobcat (Lynx lynx). Slovenian Veterinary Research 56(4):153-162; Sánchez et al., 2019Sánchez, H. L.; Rafasquino, M. E. & Portiansky, E. L. 2019. Comparative anatomy of the forearm and hand of wildcat (Leopardus geoffroyi), ocelot (Leopardus pardalis) and jaguar (Panthera onca). Journal of Morphological Science 36:7-13. ; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.), although in F. catus, it can also extend a tendon to the digit II (Barone, 1980Barone, R. 1980. Anatomie comparée des Mammifères Domestiques 2nd tome: Arthrologie et Myologie. Vigot, Paris. 984p. ; Liebich et al., 2020Liebich, H. G.; Maierl, J. & König, H. E. 2020 Forelimb or thoracic limb (Membra thoracica). In: König, H. E. & Liebich, H. G. eds. Veterinary Anatomy of Domestic Mammals: Text Book and Colour Atlas. New York, Thieme, p. 171-242.), similar to L. pardalis (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.) and P. tigris (Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ). In herpestids, viverrids, and hyaenids, it originates from the lateral epicondyle (Devis, 1868Devis, C. W. 1868. Notes on the myology of Viverra civetta. Journal of Anatomy 2:207-217. ; Watson & Young, 1879Watson, M. & Young, A. 1879. On the anatomy of the Hyaena crocuta (H. maculata). Journal of Zoology 47:79-107. ; Watson, 1882Watson, M. 1882. On the Muscular Anatomy of Proteles as compared with that of Hyeena and Viverra. Journal of Zoology 50(3):579-586. ; Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ; Spoor & Badoux, 1986Spoor, C. F. & Badoux, D. M. 1986. Descriptive and functional myology of the neck and forelimb of the striped hyena (Hyaena hyaena, L. 1758). Anatomischer Anzeiger 161:375-387.), and extends tendons to the digits IV-V (Devis, 1868Devis, C. W. 1868. Notes on the myology of Viverra civetta. Journal of Anatomy 2:207-217. ; Watson & Young, 1879Watson, M. & Young, A. 1879. On the anatomy of the Hyaena crocuta (H. maculata). Journal of Zoology 47:79-107. ; Watson, 1882Watson, M. 1882. On the Muscular Anatomy of Proteles as compared with that of Hyeena and Viverra. Journal of Zoology 50(3):579-586. ; Spoor & Badoux, 1986Spoor, C. F. & Badoux, D. M. 1986. Descriptive and functional myology of the neck and forelimb of the striped hyena (Hyaena hyaena, L. 1758). Anatomischer Anzeiger 161:375-387.; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.). Although, it may also originate from the radius, near the insertion point of the lateral collateral ligament of the elbow in Hyaenae hyaenae (Spoor & Badoux, 1986Spoor, C. F. & Badoux, D. M. 1986. Descriptive and functional myology of the neck and forelimb of the striped hyena (Hyaena hyaena, L. 1758). Anatomischer Anzeiger 161:375-387.), and it can also extend a tendon to the digit III in the viverrid Civettictis civetta (Macalister, 1873Macalister, A. 1873. On the anatomy of Aonyx. Proceedings of the Royal Irish Academy 1:539-547.; Young, 1888), the herpestid Herpestes auropunctatus and the euplerid C. ferox (Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.).

The origin and insertion of the m. extensor carpi ulnaris observed in P. cancrivorus agree with other studies (Windle, 1888Windle, B. C. 1888. Notes on the Limb Myology of Procyon cancrivorus and of the Ursidœ. Journal of Anatomy 23(1):81-89. ; Santos et al., 2010aSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ), whereas other authors did not report an insertion onto the accessory carpal bone (Lima et al., 2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.). In other procyonids, it can have an origin from the olecranon, such as in N. narica (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ) and P. flavus (Julitz, 1909Julitz, C. 1909. Osteologie und myologie der Extremitäten und des Wickelschwanzes vom Wickelbären, Cercoleptes caudivolvulus, mit besondere Berücksichtigung der Anpassungserscheinungen an das Baumleben. Archiv für Naturgeschichte Berlin 75:143-188.); or from the body of the ulna in P. cancrivorus as an anatomical variant. Even the muscle also originates from the articular capsule of the elbow in P. flavus (Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). The muscle also inserts onto the accessory carpal bone in P. lotor (Allen, 1882Allen, H. 1882. The muscles of the limbs of the raccoon (Procyon lotor). Proceedings of the Academy of Natural Sciences of Philadelphia 34(2):115-144. ) and P. flavus (Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.), similar to our findings in P. cancrivorus. Although Mcclearn (1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.) only reports the insertion onto the metacarpal V in P. lotor and Nasua. The origin and insertion in P. cancrivorus are also similar to mustelids (Macalister, 1870; Howard, 1973Howard, L. D. 1973. Muscular anatomy of the forelimb of the sea otter (Enhydra lutris). Proceedings of the California Academy of Sciences 39(20):411-500. ; Leach et al., 1976Leach, D. 1976. The forelimb musculature of marten (Martes americana Turton) and fisher (Martes pennanti Erxleben). Canadian Journal of Zoology 55(1):31-41. ; Moore et al., 2013Moore, A. L.; Budny, J. E.; Russell, A. P. & Butcher, M. T. 2013. Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus). Journal of Morphology 274(1):35-48. ; Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.), ursids (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ; Shepherd, 1883Shepherd, F. J. 1883. Short notes on the myology of the American black bear (Ursus americanus). Journal of Anatomy 18:103-117. ; Kelley, 1888Kelley, E. A. 1888. Notes on the myology of Ursus maritimus. The Proceedings of the Academy of Natural Sciences of Philadelphia 40:141-154. ), Ailurus (Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ), canids (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ; Vaz et al., 2011Vaz, M. G. R.; De Lima, A. R.; De Souza, A. C. B.; Pereira, L. C. & Branco, E. 2011. Estudo morfológico dos músculos do antebraço de cachorro-do-mato-de-orelhas-curtas (Atelocynus microtis) e cachorro-do-mato (Cerdocyon thous). Biotemas 24(4):121-127. ; Hermanson, 2013Hermanson, J. W. 2013. The Muscular System. In: Evans, H. E. & De Lahunta, A. eds. Miller’s anatomy of the dog. Missouri, Saunders Elsevier, p. 185-280.; Echeverry et al., 2015Echeverry, J. S.; Vélez, J. F. & Sánchez, C. A. 2015. Descripción anatómica de los músculos cráneo-laterales superficiales del antebrazo del zorro perruno (Cerdocyon thous). Revista Colombiana de Ciencia Animal 8(1):44-51.; Souza-Junior et al., 2015Souza-Junior, P. D.; Dos Santos, L. M.; Nogueira, D. M., Abidu-Figueiredo, M. & Santos, A. L. 2015. Occurrence and morphometrics of the brachioradialis muscle in wild carnivorans (Carnivora: Caniformia, Feliformia). Zoologia 32(1):23-32. ; Souza-Junior et al., 2018 Souza Junior, P.; Santos, L. M. R. P. D.; Viotto‐Souza, W.; De Carvalho, N. D. C.; Souza, E. C.; Kasper, C. B.; Abidu-Figueiredo, M. & Santos, A. L. Q. 2018. Functional myology of the thoracic limb in Pampas fox (Lycalopex gymnocercus): a descriptive and comparative analysis. Journal of Anatomy 233(6):783-806.; Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.), felids (Beswick-Perrin, 1871Beswick-Perrin, J. 1871. On the myology of the limbs of the kinkajou (Cercoleptes caudivolvulus). Proceedings of the Zoological Society of London 1871:547-559.; Barone, 1986; Concha et al., 2004Concha, I.; Adaro, L.; Borroni, C. & Altamirano, C. 2004. Consideraciones anatómicas sobre la musculatura intrínseca del miembro torácico del puma (Puma concolor). Journal of Morphology 22:121-125. ; Hudson et al., 2011Hudson, P. E.; Corr, S. A.; Payne‐Davis, R. C.; Clancy, S. N.; Lane, E. & Wilson, A. M. 2011. Functional anatomy of the cheetah (Acinonyx jubatus) forelimb. Journal of Anatomy 218(4):375-385. ; Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ; Nazem et al., 2017Nazem, M. N.; Sajjadian, S. M. & Nakhaei, A. 2017. Anatomy, functional anatomy and morphometrical study of forelimb column in Asiatic cheetah (Acinonyx jubatus venaticus). The Italian Journal of Anatomy and Embryology 3:157-172.; Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ), herpestids (Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ), and viverrids (Devis, 1868Devis, C. W. 1868. Notes on the myology of Viverra civetta. Journal of Anatomy 2:207-217. ; Watson, 1882Watson, M. 1882. On the Muscular Anatomy of Proteles as compared with that of Hyeena and Viverra. Journal of Zoology 50(3):579-586. ; Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ). However, there are some differences with some mustelid species, such as in G. cuja, where the m. extensor carpi ulnaris originates from the articular capsule of the elbow (Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.). On the other hand, there was no carpal insertion in T. taxus (Moore et al., 2013Moore, A. L.; Budny, J. E.; Russell, A. P. & Butcher, M. T. 2013. Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus). Journal of Morphology 274(1):35-48. ), M. martes and M. foina (Böhmer et al., 2018Böhmer, C.; Fabre, A. C.; Taverne, M.; Herbin, M.; Peigne, S. & Herrel, A. 2018. Anatomical basis of differences in locomotor behavior in martens: a comparison of the forelimb musculature between two sympatric species of Martes. The Anatomical Record 301(3):449-472.). In the ursid A. melanoleuca, it also originates from the condyle and its fibers are inseparable from the anconeus and extensor digitorum lateralis muscles, and it does not insert onto the accessory carpal bone (Davis, 1976). In felids, such as L. pardalis it fuses with the articular capsule of the elbow and m. anconeus, and it does not insert on the accessory carpal bone (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.). In L. lynx, it can also originate from the ulna and insert onto the extensor retinaculum (Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ), but does not insert onto the accessory carpal bone (Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ; Ari et al., 2019Ari, H.; Yurdakul, İ. & Aksoy, G. 2019. A macroscopic study on the muscles and tendons of forepaws in the anatolian bobcat (Lynx lynx). Slovenian Veterinary Research 56(4):153-162). In P. uncia and P. tigris, it does not insert onto the accessory carpal bone (Smith et al., 2021Smith, H. F.; Townsend, K. B.; Adrian, B.; Levy, S.; Marsh, S.; Hassur, R.; Manfredi, K. & Echols, M. S. 2021. Functional adaptations in the forelimb of the snow leopard (Panthera uncia). Integrative and Comparative Biology 61(5):1852-1866. ; Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ), but in P. tigris, it inserts onto the accessory carpal ligament (“pisometacarpal ligament” Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ). In viverrids of the genus Genetta, it also originates from the ulna (Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ). In hyaenids, it does not insert onto the carpus (Watson & Young, 1876; Spoor & Badoux, 1986Spoor, C. F. & Badoux, D. M. 1986. Descriptive and functional myology of the neck and forelimb of the striped hyena (Hyaena hyaena, L. 1758). Anatomischer Anzeiger 161:375-387.), although in Proteles inserts onto the retinaculum extensor (Watson, 1882Watson, M. 1882. On the Muscular Anatomy of Proteles as compared with that of Hyeena and Viverra. Journal of Zoology 50(3):579-586. ).

The radial and ulnar origins of the m. abductor digiti I longus observed in P. cancrivorus has been previously described (Lima et al., 2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.), while it was also reported originated from the ulna and the interosseus membrane (Santos et al., 2010Santos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ). Therefore, both studies differ from our findings in P. cancrivorus, where the origin reaches both bones and the interosseus ligament, and an insertion onto the sesamoid bone was found. In other procyonids, such us in P. lotor, Nasua and P. flavus, the origin from the radius, the interosseus ligament and the ulna is common (Allen, 1882Allen, H. 1882. The muscles of the limbs of the raccoon (Procyon lotor). Proceedings of the Academy of Natural Sciences of Philadelphia 34(2):115-144. ; Julitz, 1909Julitz, C. 1909. Osteologie und myologie der Extremitäten und des Wickelschwanzes vom Wickelbären, Cercoleptes caudivolvulus, mit besondere Berücksichtigung der Anpassungserscheinungen an das Baumleben. Archiv für Naturgeschichte Berlin 75:143-188.; Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). Although in Nasua, the radial origin can be absent (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Santos et al., 2010bSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ). However, an insertion onto the sesamoid bone can occur (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ), similar to P. flavus (Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.), and P. cancrivorus. In P. flavus, it can also insert onto the radial carpal bone (Beswick-Perrin, 1981), similar to P. lotor (Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ). In mustelids, such as Martes and P. pennanti, the m. abductor digiti I longus originates from the radius and the ulna, and inserts onto the metacarpal bone I (Leach, 1976Leach, D. 1976. The forelimb musculature of marten (Martes americana Turton) and fisher (Martes pennanti Erxleben). Canadian Journal of Zoology 55(1):31-41. ; Böhmer et al., 2018Böhmer, C.; Fabre, A. C.; Taverne, M.; Herbin, M.; Peigne, S. & Herrel, A. 2018. Anatomical basis of differences in locomotor behavior in martens: a comparison of the forelimb musculature between two sympatric species of Martes. The Anatomical Record 301(3):449-472.). Although in M. foina, it can originate from the interosseous antebrachial ligament, and inserts onto the sesamoid bone (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ). In E. barbara, this muscle only originates from the ulna and inserts onto the metacarpal bone I, the sesamoid bone and carpal I (Macalister, 1873Macalister, A. 1873. On the anatomy of Aonyx. Proceedings of the Royal Irish Academy 1:539-547.). In G. cuja, Aonyx, and E. lutris, it originates from the radius and the ulna, and inserts onto the sesamoid bone and the metacarpal I (Macalister, 1870; Howard, 1973Howard, L. D. 1973. Muscular anatomy of the forelimb of the sea otter (Enhydra lutris). Proceedings of the California Academy of Sciences 39(20):411-500. ; Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.). In T. taxus, it is described as “extensor pollicis brevis”, which only originates from the radius and inserts onto the metacarpal bone I (Moore et al., 2013Moore, A. L.; Budny, J. E.; Russell, A. P. & Butcher, M. T. 2013. Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus). Journal of Morphology 274(1):35-48. ). In ursids, it originates from the radius, the ulna, and the interosseous membrane, and inserts onto the metacarpal I (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ; Shepherd, 1883Shepherd, F. J. 1883. Short notes on the myology of the American black bear (Ursus americanus). Journal of Anatomy 18:103-117. ; Kelley, 1888Kelley, E. A. 1888. Notes on the myology of Ursus maritimus. The Proceedings of the Academy of Natural Sciences of Philadelphia 40:141-154. ), although in A. melanoleuca, it only inserts onto the sesamoid bone (Davis, 1964Davis, D. 1964. The giant panda a morphological study of evolutionary mechanisms. Chicago, Natural History Museum Chicago 3:1-339.). In Ailurus, it has the same origins, but fuses with the m. supinator and inserts onto the sesamoid bone and the metacarpal bone I (Anton et al., 2006; Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ). In canids, it only originates from the radius and the ulna (Vaz et al., 2011Vaz, M. G. R.; De Lima, A. R.; De Souza, A. C. B.; Pereira, L. C. & Branco, E. 2011. Estudo morfológico dos músculos do antebraço de cachorro-do-mato-de-orelhas-curtas (Atelocynus microtis) e cachorro-do-mato (Cerdocyon thous). Biotemas 24(4):121-127. ; Souza-Junior et al., 2018 Souza Junior, P.; Santos, L. M. R. P. D.; Viotto‐Souza, W.; De Carvalho, N. D. C.; Souza, E. C.; Kasper, C. B.; Abidu-Figueiredo, M. & Santos, A. L. Q. 2018. Functional myology of the thoracic limb in Pampas fox (Lycalopex gymnocercus): a descriptive and comparative analysis. Journal of Anatomy 233(6):783-806.; Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.), although, it can also originate from the interosseus membrane and inserts onto the sesamoid bone and metacarpal bone I in C. l. familiaris (Hermanson, 2013Hermanson, J. W. 2013. The Muscular System. In: Evans, H. E. & De Lahunta, A. eds. Miller’s anatomy of the dog. Missouri, Saunders Elsevier, p. 185-280.) and L. pictus (Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.). In felids, it originates from the radius, the ulna, and the interosseus membrane (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.; Sánchez et al., 2019Sánchez, H. L.; Rafasquino, M. E. & Portiansky, E. L. 2019. Comparative anatomy of the forearm and hand of wildcat (Leopardus geoffroyi), ocelot (Leopardus pardalis) and jaguar (Panthera onca). Journal of Morphological Science 36:7-13. ; Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ), however, it is reported to only originate from the radius and the ulna in L. lynx (Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ; Ari et al., 2019Ari, H.; Yurdakul, İ. & Aksoy, G. 2019. A macroscopic study on the muscles and tendons of forepaws in the anatolian bobcat (Lynx lynx). Slovenian Veterinary Research 56(4):153-162), P. leo (Barone, 1986; Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ) and P. uncia (Smith et al., 2021Smith, H. F.; Townsend, K. B.; Adrian, B.; Levy, S.; Marsh, S.; Hassur, R.; Manfredi, K. & Echols, M. S. 2021. Functional adaptations in the forelimb of the snow leopard (Panthera uncia). Integrative and Comparative Biology 61(5):1852-1866. ). Whereas in Puma concolor, it only originates from the ulna and only inserts onto the metacarpal bone I (Concha et al., 2004Concha, I.; Adaro, L.; Borroni, C. & Altamirano, C. 2004. Consideraciones anatómicas sobre la musculatura intrínseca del miembro torácico del puma (Puma concolor). Journal of Morphology 22:121-125. ). In L. pardalis, P. leo and P. tigris, it also inserts onto the sesamoid bone (Barone, 1986; Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.; Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ), and in L. lynx onto the carpal bone I (Ari et al., 2019Ari, H.; Yurdakul, İ. & Aksoy, G. 2019. A macroscopic study on the muscles and tendons of forepaws in the anatolian bobcat (Lynx lynx). Slovenian Veterinary Research 56(4):153-162). In herpestids and viverrids of the genera Genetta and Civettictis, it originates from the radius and the ulna (Young, 1880Young, A. H. 1880. Myology of Viverra civetta. Journal of Anatomy 14:166-177. ; Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ). However, in C. civetta, it has been reported to only originate from the ulna, and insert onto the metacarpal bone I and the sesamoid bone (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ). In hyaenids, it originates from the ulna, the radius, and the interosseus membrane, and inserts onto the metacarpal bone I (Watson & Young, 1876; Spoor & Badoux, 1985). In H. hyaena, it can also have an insertion onto the sesamoid bone, similar to H. aurupunctatus (Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.).

The m. extensor digiti I et II was not reported by Lima et al. (2010Lima, V. M.; Pereira, F. C. & Pereira, K. F. 2010. Morphological study of the muscles of the forearm of crab eating raccoon Procyon cancrivorus Cuvier, 1798. Bioscience Journal 26(1):109-114.) and Santos et al. (2010aSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ) in P. cancrivorus, whereas Windle (1888Windle, B. C. 1888. Notes on the Limb Myology of Procyon cancrivorus and of the Ursidœ. Journal of Anatomy 23(1):81-89. ) reported this muscle as a deep digital extensor that originated from the radial border of the ulna with tendons to the digits I and II. However, this last author did not report a tendon extending to the digit III as our findings in four specimens did. In other procyonids, it also extends a tendon to the digit III, such in P. lotor, N. nasua, and N. narica (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Allen, 1882Allen, H. 1882. The muscles of the limbs of the raccoon (Procyon lotor). Proceedings of the Academy of Natural Sciences of Philadelphia 34(2):115-144. ; Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.), being similar to our findings in P. cancrivorus. Although, the tendon to the digit III can be absent in N. nasua (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.) and P. lotor (Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ), while in P. flavus the absence of this tendon is normal (Beswick-Perrin, 1871Beswick-Perrin, J. 1871. On the myology of the limbs of the kinkajou (Cercoleptes caudivolvulus). Proceedings of the Zoological Society of London 1871:547-559.; Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ; Julitz, 1909Julitz, C. 1909. Osteologie und myologie der Extremitäten und des Wickelschwanzes vom Wickelbären, Cercoleptes caudivolvulus, mit besondere Berücksichtigung der Anpassungserscheinungen an das Baumleben. Archiv für Naturgeschichte Berlin 75:143-188.; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). Interestingly, in P. flavus has been found an independent muscle to the digit III, but as an anatomical variant (Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). Böhmer et al. (2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.) only reported the tendon to the digit II in P. flavus, which may also be interpreted as an anatomical variant since it was always present in other studies (Beswick-Perrin, 1871Beswick-Perrin, J. 1871. On the myology of the limbs of the kinkajou (Cercoleptes caudivolvulus). Proceedings of the Zoological Society of London 1871:547-559.; Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ; Julitz, 1909Julitz, C. 1909. Osteologie und myologie der Extremitäten und des Wickelschwanzes vom Wickelbären, Cercoleptes caudivolvulus, mit besondere Berücksichtigung der Anpassungserscheinungen an das Baumleben. Archiv für Naturgeschichte Berlin 75:143-188.; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). Mackintosh (1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ) reported that this muscle is one-headed in Nasua, while Mcclearn (1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115.) describes it as two separate bellies in P. lotor and Nasua, similar to P. cancrivorus. In mustelids, it originates from the ulna and extends tendons to the digits I and II (Macalister, 1870, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Howard, 1973Howard, L. D. 1973. Muscular anatomy of the forelimb of the sea otter (Enhydra lutris). Proceedings of the California Academy of Sciences 39(20):411-500. ; Moore et al., 2013Moore, A. L.; Budny, J. E.; Russell, A. P. & Butcher, M. T. 2013. Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus). Journal of Morphology 274(1):35-48. ; Böhmer et al., 2018Böhmer, C.; Fabre, A. C.; Taverne, M.; Herbin, M.; Peigne, S. & Herrel, A. 2018. Anatomical basis of differences in locomotor behavior in martens: a comparison of the forelimb musculature between two sympatric species of Martes. The Anatomical Record 301(3):449-472., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.), however, in M. americana, P. pennanti, and G. cuja, it also originates from the m. abductor digiti I longus (Leach, 1976Leach, D. 1976. The forelimb musculature of marten (Martes americana Turton) and fisher (Martes pennanti Erxleben). Canadian Journal of Zoology 55(1):31-41. ; Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.), which is similar to Ailurus (Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ), and P. cancrivorus. Although in G. cuja, it also originates from the septum of the m. flexor digitorum profundus (Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.), and the case of Lutra vulgaris, it only goes to the digits II and III (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ). In Ursus it can be absent or fused with the m. abductor digiti I longus (Shepherd, 1883Shepherd, F. J. 1883. Short notes on the myology of the American black bear (Ursus americanus). Journal of Anatomy 18:103-117. ; Kelley, 1888Kelley, E. A. 1888. Notes on the myology of Ursus maritimus. The Proceedings of the Academy of Natural Sciences of Philadelphia 40:141-154. ), although when it is present, only extends the tendons to the digit I (Haughton, 1864Haughton, S. 1864. Notes on Animal Mechanics: No. 15. On the Muscular Anatomy of the Otter (Lutra vulgaris). Proceedings of the Royal Irish Academy 9:511-515. ); whereas in the genus Ailuropoda, it extends tendons to the digits I and II (Davis, 1964Davis, D. 1964. The giant panda a morphological study of evolutionary mechanisms. Chicago, Natural History Museum Chicago 3:1-339.). In canids, the muscle originates from the ulna, but it has different distribution of the tendons. In C. l. familiaris, C. thous, and L. gymnocercus, it forms two tendons to the digits I and II, and sometimes to the digit III, where the tendon to the digit I goes to the head of the metacarpal bone I and the other to the extensor digitorum communis tendon for digit II (Hermanson, 2013Hermanson, J. W. 2013. The Muscular System. In: Evans, H. E. & De Lahunta, A. eds. Miller’s anatomy of the dog. Missouri, Saunders Elsevier, p. 185-280.; Vélez et al., 2015Echeverry, J. S.; Vélez, J. F. & Sánchez, C. A. 2015. Descripción anatómica de los músculos cráneo-laterales superficiales del antebrazo del zorro perruno (Cerdocyon thous). Revista Colombiana de Ciencia Animal 8(1):44-51.; Souza-Junior et al., 2018 Souza Junior, P.; Santos, L. M. R. P. D.; Viotto‐Souza, W.; De Carvalho, N. D. C.; Souza, E. C.; Kasper, C. B.; Abidu-Figueiredo, M. & Santos, A. L. Q. 2018. Functional myology of the thoracic limb in Pampas fox (Lycalopex gymnocercus): a descriptive and comparative analysis. Journal of Anatomy 233(6):783-806.). In. C. thous, it also originates from the m. abductor digiti I longus and interosseous ligament (Vélez et al., 2015Echeverry, J. S.; Vélez, J. F. & Sánchez, C. A. 2015. Descripción anatómica de los músculos cráneo-laterales superficiales del antebrazo del zorro perruno (Cerdocyon thous). Revista Colombiana de Ciencia Animal 8(1):44-51.). In L. pictus, the medial tendon inserts onto the base of the metacarpal bone II (Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.). In C. alpinus and V. vulpes, the tendons to the digits I and II insert onto the distal phalanxes (Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.). In felids, it originates from the ulna and extends tendons to the digits I and II (Barone, 1967Barone, R. 1967. La myologie du lion (Panthera leo). Mammalia 31:459-514.; Concha et al., 2004Concha, I.; Adaro, L.; Borroni, C. & Altamirano, C. 2004. Consideraciones anatómicas sobre la musculatura intrínseca del miembro torácico del puma (Puma concolor). Journal of Morphology 22:121-125. ; Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.; Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ; Sánchez et al., 2019Sánchez, H. L.; Rafasquino, M. E. & Portiansky, E. L. 2019. Comparative anatomy of the forearm and hand of wildcat (Leopardus geoffroyi), ocelot (Leopardus pardalis) and jaguar (Panthera onca). Journal of Morphological Science 36:7-13. ; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.; Smith et al., 2021Smith, H. F.; Townsend, K. B.; Adrian, B.; Levy, S.; Marsh, S.; Hassur, R.; Manfredi, K. & Echols, M. S. 2021. Functional adaptations in the forelimb of the snow leopard (Panthera uncia). Integrative and Comparative Biology 61(5):1852-1866. ). However, the lateral tendon can send a small fascicle to the tendon for digit III of the m. extensor digitorum lateralis in P. tigris (Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ). In hyaenids, the m. extensor digiti I et II only goes to the digit II (Watson & Young, 1879Watson, M. & Young, A. 1879. On the anatomy of the Hyaena crocuta (H. maculata). Journal of Zoology 47:79-107. ; Spoor & Badoux, 1985; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.) or digit III in Proteles (Watson, 1882Watson, M. 1882. On the Muscular Anatomy of Proteles as compared with that of Hyeena and Viverra. Journal of Zoology 50(3):579-586. ). In viverrids, herpestids and euplerids the origin is also from the ulna and the muscle extends tendons to the digits I and II (Watson, 1882Watson, M. 1882. On the Muscular Anatomy of Proteles as compared with that of Hyeena and Viverra. Journal of Zoology 50(3):579-586. ; Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ; Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.).

The m. supinator in P. cancrivorus has been described as originating only from the orbicular ligament (Windle, 1888Windle, B. C. 1888. Notes on the Limb Myology of Procyon cancrivorus and of the Ursidœ. Journal of Anatomy 23(1):81-89. ) or only from the lateral epicondyle (Santos et al., 2010Santos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. a; Silva et al., 2015Silva, M. F.; Souza, W. V.; Almada, R. M.; Carvalho, A. D.; Souza Junior, P. & Rodovia, U. B. 2015. Anatomía comparada de los músculos supinador y pronador redondo de tres especies carnívoras silvestres. Revista Argentina de Anatomía Online 6(3):117-22.). We found a wide origin including the lateral collateral ligament of the elbow and the radial annular ligament, similar to P. flavus (Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). Whilst the insertion onto the proximal third of the radius was similar to that previously reported (Silva et al., 2015Silva, M. F.; Souza, W. V.; Almada, R. M.; Carvalho, A. D.; Souza Junior, P. & Rodovia, U. B. 2015. Anatomía comparada de los músculos supinador y pronador redondo de tres especies carnívoras silvestres. Revista Argentina de Anatomía Online 6(3):117-22.). In P. lotor, it originates from the orbicular ligament and inserts onto the proximal third (Allen, 1882Allen, H. 1882. The muscles of the limbs of the raccoon (Procyon lotor). Proceedings of the Academy of Natural Sciences of Philadelphia 34(2):115-144. ) or proximal half (Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ) of the body of the radius. In procyonids of the genus Nasua, it originates from the lateral epicondyle and inserts onto the proximal two-thirds of the radius (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ; Santos et al., 2010bSantos, A. C.; Bertassoli, B. M.; De Oliveira, V. C.; De Carvalho A. F.; Rosa, R. A. & Mançanares, C. A. F. 2010b. Morfologia dos músculos do ombro, braço e antebraço do quati (Nasua nasua Linnaeus, 1758). Biotemas 23(3):165-173. ), whereas in P. flavus it inserts onto the proximal half or proximal two-thirds (Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ; Julitz, 1909Julitz, C. 1909. Osteologie und myologie der Extremitäten und des Wickelschwanzes vom Wickelbären, Cercoleptes caudivolvulus, mit besondere Berücksichtigung der Anpassungserscheinungen an das Baumleben. Archiv für Naturgeschichte Berlin 75:143-188.; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). In mustelids, there are several origins and insertions, such as in M. foina, where it inserts onto the proximal half (Mackintosh, 1875Mackintosh, H. W. 1875. Notes on the Myology of the Coati-Mondi (Nasua narica and N. fusca) and Common Martin (Martes foina). Proceedings of the Royal Irish Academy 2:48-55. ); in T. taxus it originates from the humeral condyle and the radius, and inserts onto length of the radius (Moore et al., 2013Moore, A. L.; Budny, J. E.; Russell, A. P. & Butcher, M. T. 2013. Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus). Journal of Morphology 274(1):35-48. ); in G. cuja, it originates from the articular capsule of the elbow and the lateral collateral ligament, and inserts onto the proximal two-thirds (Ercoli et al., 2015Ercoli, M. D.; Álvarez, A.; Stefanini, M. I.; Busker, F. & Morales, M. M. 2015. Muscular anatomy of the forelimbs of the lesser grison (Galictis cuja), and a functional and phylogenetic overview of Mustelidae and other Caniformia. Journal of Mammalian Evolution 22(1):57-91.); in M. americana and P. pennanti, it originates from the lateral epicondyle and the lateral collateral ligament, and according to the figures inserts onto the proximal third of the radius (Leach, 1976Leach, D. 1976. The forelimb musculature of marten (Martes americana Turton) and fisher (Martes pennanti Erxleben). Canadian Journal of Zoology 55(1):31-41. ); while in M. foina and M. martes it originates from the humerus and inserts until the distal third of the radius (Böhmer et al., 2018Böhmer, C.; Fabre, A. C.; Taverne, M.; Herbin, M.; Peigne, S. & Herrel, A. 2018. Anatomical basis of differences in locomotor behavior in martens: a comparison of the forelimb musculature between two sympatric species of Martes. The Anatomical Record 301(3):449-472.); in Mustela putorius, L. vulgaris and Aonyx cinereus, it reaches the third quarter of the radius (Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ); in E. lutris it originates from the lateral epicondyle and inserts onto the proximal three fourths of the radius (Howard, 1973Howard, L. D. 1973. Muscular anatomy of the forelimb of the sea otter (Enhydra lutris). Proceedings of the California Academy of Sciences 39(20):411-500. ); and in Aonyx, it can inserts onto the distal third of the radius (Macalister, 1870). In Ailurus, it only originates from the lateral collateral and the radial annular ligament, and inserts onto the proximal half of the radius, fuses with the m. abductor digiti I longus (Fisher et al., 2009Fisher, R. E.; Adrian, B.; Barton, M.; Holmgren, J. & Tang, S. Y. 2009. The phylogeny of the red panda (Ailurus fulgens): evidence from the forelimb. Journal of Anatomy 215:611-635. ). In ursids, the origin is similar to that of Ailurus, but it inserts onto the proximal three-quarters of the radius (Shepherd, 1883Shepherd, F. J. 1883. Short notes on the myology of the American black bear (Ursus americanus). Journal of Anatomy 18:103-117. ; Kelley, 1888Kelley, E. A. 1888. Notes on the myology of Ursus maritimus. The Proceedings of the Academy of Natural Sciences of Philadelphia 40:141-154. ; Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ; Davis, 1964Davis, D. 1964. The giant panda a morphological study of evolutionary mechanisms. Chicago, Natural History Museum Chicago 3:1-339.). In canids, it originates from the lateral epicondyle and lateral collateral ligament, and inserts onto the proximal quarter of the radius (Hermanson et al., 2013Hermanson, J. W. 2013. The Muscular System. In: Evans, H. E. & De Lahunta, A. eds. Miller’s anatomy of the dog. Missouri, Saunders Elsevier, p. 185-280.; Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.); in L. gymnocercus and C. thous, it only originates from the lateral epicondyle and inserts onto the proximal third (Silva et al., 2015Silva, M. F.; Souza, W. V.; Almada, R. M.; Carvalho, A. D.; Souza Junior, P. & Rodovia, U. B. 2015. Anatomía comparada de los músculos supinador y pronador redondo de tres especies carnívoras silvestres. Revista Argentina de Anatomía Online 6(3):117-22.). In felids, it originates from the lateral epicondyle and inserts onto the middle third (Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ), until the distal third of the radius (Barone, 1967Barone, R. 1967. La myologie du lion (Panthera leo). Mammalia 31:459-514.). In L. lynx, it originates from the lateral epicondyle and lateral collateral ligament, and inserts onto almost length of the radius (Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ); in P. concolor onto the middle third (Concha et al., 2004Concha, I.; Adaro, L.; Borroni, C. & Altamirano, C. 2004. Consideraciones anatómicas sobre la musculatura intrínseca del miembro torácico del puma (Puma concolor). Journal of Morphology 22:121-125. ); in A. jubatus onto the quarter proximal (Hudson et al., 2011Hudson, P. E.; Corr, S. A.; Payne‐Davis, R. C.; Clancy, S. N.; Lane, E. & Wilson, A. M. 2011. Functional anatomy of the cheetah (Acinonyx jubatus) forelimb. Journal of Anatomy 218(4):375-385. ; Nazem et al., 2017Nazem, M. N.; Sajjadian, S. M. & Nakhaei, A. 2017. Anatomy, functional anatomy and morphometrical study of forelimb column in Asiatic cheetah (Acinonyx jubatus venaticus). The Italian Journal of Anatomy and Embryology 3:157-172.). In L. pardalis, it originates from the radial annular and lateral collateral ligaments, and inserts onto the proximal two-thirds (Julik et al., 2012Julik, E.; Zack, S.; Adrian, B.; Maredia, S.; Parsa, A.; Poole, M.; Starbuck, A. & Fisher, R. E. 2012. Functional anatomy of the forelimb muscles of the ocelot (Leopardus pardalis). Journal of Mammalian Evolution 19(4):277-304.; Sánchez et al., 2019Sánchez, H. L.; Rafasquino, M. E. & Portiansky, E. L. 2019. Comparative anatomy of the forearm and hand of wildcat (Leopardus geoffroyi), ocelot (Leopardus pardalis) and jaguar (Panthera onca). Journal of Morphological Science 36:7-13. ), while in P. onca, it inserts onto the distal third (Sánchez et al., 2019Sánchez, H. L.; Rafasquino, M. E. & Portiansky, E. L. 2019. Comparative anatomy of the forearm and hand of wildcat (Leopardus geoffroyi), ocelot (Leopardus pardalis) and jaguar (Panthera onca). Journal of Morphological Science 36:7-13. ). In P. uncia, it originates from the lateral epicondyle of the humerus and inserts onto the proximal two thirds of the radius (based on the figures of Smith et al., 2021Smith, H. F.; Townsend, K. B.; Adrian, B.; Levy, S.; Marsh, S.; Hassur, R.; Manfredi, K. & Echols, M. S. 2021. Functional adaptations in the forelimb of the snow leopard (Panthera uncia). Integrative and Comparative Biology 61(5):1852-1866. ). While in P. tigris, it originates from the elbow articular capsule and adjacent ligaments, and inserts onto the proximal half of the radius and m. abductor longus digiti I (Dunn et al., 2022Dunn, R. H.; Beresheim, A.; Gubatina, A.; Bitterman, K.; Butaric, A.; Bejes, K.; Kennedy, S.; Markham, S.; Miller, D.; Mrvoljak, M.; Roge-Jones, L.; Stumpner, J.; Walter, C. & Meachen, J. A. 2022. Muscular anatomy of the forelimb of tiger (Panthera tigris) . Journal of Anatomy. https://doi.org/10.1111/joa.13636
https://doi.org/10.1111/joa.13636... ). In herpestids, it inserts onto the proximal two-thirds, while in viverrids, it inserts onto the proximal third of the radius (Windle & Parsons, 1897Windle, B. C. A. & Parsons, F. G. 1897. On the Myology of the Terrestrial Carnivora. Part I. Muscles of the Head, Neck, and Fore‐Limb. Journal of Zoology 66(2):370-409. ; Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ) (Tab. I).

Functional analysis. Within the craniolateral forearm muscles of P. cancrivorus, the brachioradialis and supinator muscles are two muscles that should act as lateral rotators of the antebrachium and manus (supinators). Based on Kardong (2012Kardong, K. V. 2012. Vertebrates: comparative anatomy, function, evolution. 6ed. New York, McGraw Hill. 794p.), when the muscle is inserted proximally, it acts for fast movements, while when it is inserted distally, it acts for strong movements. Therefore, in P. cancrivorus, the proximal insertion of the m. supinator should give it more velocity to supination, while the m. brachioradialis due to its distal insertion gives it more force to supination. The proximal insertion of the m. supinator also is present in other carnivorans mainly with cursorial habits, such as canids, hyaenids, viverrids, and the felid A. jubatus. However, the permanent presence of a well-developed m. brachioradialis in P. cancrivorus has allowed it to perform more activities, such as manipulating its food with its hands, swimming, and climbing trees. Since carnivoran species with a well-developed m. brachioradialis can perform more activities with their thoracic limbs than just walking and running (Indrusiak & Eizirik, 2003Indrusiak, C. & Eizirik, E. 2003. Carnívoros. In: Fontana, C. S.; Bencke, G. A. & Reis, R. E. orgs. Livro vermelho da fauna ameaçada de extinção do RS. Porto Alegre, Edipucrs, p. 507-533.; Martinelli & Volpi, 2010Martinelli, M. M. & Volpi, T. A. 2010. Diet of racoon Procyon cancrivorus (Carnivora, Procyonidae) in a mangrove and restinga area in Espírito Santo state, Brazil. Natureza on line 8:150-151.; Pellanda et al., 2010Pellanda, M.; Castro-Almeida, C. M.; Dos Santos, M. D. & Hartz, S. M. 2010. Dieta do mão-pelada (Procyon cancrivorus, Procyonidae, Carnivora) no Parque Estadual de Itapuã, sul do Brasil. Neotropical Biology and Conservation 5(3):154-159. ; Souza et al., 2015Silva, M. F.; Souza, W. V.; Almada, R. M.; Carvalho, A. D.; Souza Junior, P. & Rodovia, U. B. 2015. Anatomía comparada de los músculos supinador y pronador redondo de tres especies carnívoras silvestres. Revista Argentina de Anatomía Online 6(3):117-22.; Souza-Junior et al., 2015Souza-Junior, P. D.; Dos Santos, L. M.; Nogueira, D. M., Abidu-Figueiredo, M. & Santos, A. L. 2015. Occurrence and morphometrics of the brachioradialis muscle in wild carnivorans (Carnivora: Caniformia, Feliformia). Zoologia 32(1):23-32. ; Taverne et al., 2018Taverne, M.; Fabre, A. C.; Herbin, M.; Herrel, A.; Peigmé, S.; Lacroux, C.; Lowi, A.; Pagès, F.; Theil, J. C. & Böhmer, C. 2018. Convergence in the functional properties of forelimb muscles in carnivorans: adaptations to an arboreal lifestyle? Biological Journal of the Linnean Society 125:250-263. ). Additionally, this muscle contributes to elbow flexion in carnivorans, but this action is secondary due to its insertion onto the distal part of the forearm (Saladin, 2010Saladin, K. S. 2010. Anatomy and Physiology: The Unity of Form and Function. New York, McGraw Hill . 1248p.; Souza et al., 2015Silva, M. F.; Souza, W. V.; Almada, R. M.; Carvalho, A. D.; Souza Junior, P. & Rodovia, U. B. 2015. Anatomía comparada de los músculos supinador y pronador redondo de tres especies carnívoras silvestres. Revista Argentina de Anatomía Online 6(3):117-22., 2020Souza-Junior, P.; De Souza Pahim, A. B.; Viotto‐Souza, W.; Pellenz, J.; Bernardes, F. C. S.; Abidu‐Figueiredo, M. & Santos, A. L. Q. 2021. Evolutionary history or function? Which preponderates in the expression of the muscle mass of the thoracic limb in wild carnivorans? The Anatomical Record 304(36):1344-1356. ). Interestingly, other mammals as Primates with similar attachments to P. cancrivorus, the primary function of the m. brachioradialis is to flex the elbow (Myatt et al., 2012Myatt, J. P.; Crompton, R. H.; Payne‐Davis, R. C.; Vereecke, E. E.; Isler, K., Savage, R. ... & Thorpe, S. K. 2012. Functional adaptations in the forelimb muscles of non‐human great apes. Journal of Anatomy 220(1):13-28.) and stabilize the elbow during flexion tasks (Boland et al., 2008Boland, M. R.; Spigelman, T. & Uhl, T. L. 2008. The function of brachioradialis. The Journal of Hand Surgery 33(10):1853-1859.). Therefore, the m. brachioradialis should flex and stabilize the elbow together to the extensor carpi radialis and extensor digitorum communis muscles in P. cancrivorus since these also originate from the lateral supracondylar crest. Thereby, procyonid species have a pronounced lateral supracondylar crest to give origin to these muscles (Taverne et al., 2018Taverne, M.; Fabre, A. C.; Herbin, M.; Herrel, A.; Peigmé, S.; Lacroux, C.; Lowi, A.; Pagès, F.; Theil, J. C. & Böhmer, C. 2018. Convergence in the functional properties of forelimb muscles in carnivorans: adaptations to an arboreal lifestyle? Biological Journal of the Linnean Society 125:250-263. ; Tarquini et al., 2019Tarquini, J.; Morgan, C. C.; Toledo, N. & Soibelzon, L. H. 2019. Comparative osteology and functional morphology of the forelimb of Cyonasua (Mammalia, Procyonidae), the first South American carnivoran. Journal of Morphology 280:446-470. ; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.), which is a characteristic of carnivorans with arboreal abilities (Taylor, 1976Taylor, M. E. 1976. The functional anatomy of the forelimb of some African Viverridae (Carnivora). Journal of Morphology 143(3):307-335. ; Argot, 2001Argot, C. 2001. Functional‐adaptive anatomy of the forelimb in the Didelphidae, and the paleobiology of the Paleocene marsupials Mayulestes ferox and Pucadelphys andinus. Journal of Morphology 247(1):51-79.; Fabre et al., 2015Fabre, A. C.; Cornette, R.; Goswami, A. & Peigné, S. 2015. Do constraints associated with the locomotor habitat drive the evolution of forelimb shape? A case study in musteloid carnivorans. Journal of Anatomy 226(6):596-610. ; Taverne et al., 2018Taverne, M.; Fabre, A. C.; Herbin, M.; Herrel, A.; Peigmé, S.; Lacroux, C.; Lowi, A.; Pagès, F.; Theil, J. C. & Böhmer, C. 2018. Convergence in the functional properties of forelimb muscles in carnivorans: adaptations to an arboreal lifestyle? Biological Journal of the Linnean Society 125:250-263. ). On the other hand, the proximal origins of brachioradialis, extensor carpi radialis and extensor digitorum communis muscles could be associated with the feeding habits of P. cancrivorus when the individual needs to be flexing the elbow to bring food to its mouth with its hands.

The m. extensor carpi radialis is mainly an extensor of the carpus and can be present as a single or double muscle in a common or variant manner in carnivorans. Therefore, there should be no functional differences among carnivorans, but the constant arrangement as a single muscle in P. cancrivorus allows to differentiate it of P. lotor. Thus, during the phylogenetic divergence of both species, the muscles extensor carpi radialis longus and brevis were separated in P. lotor (based on the descriptions of Allen, 1882Allen, H. 1882. The muscles of the limbs of the raccoon (Procyon lotor). Proceedings of the Academy of Natural Sciences of Philadelphia 34(2):115-144. , Mcclearn, 1985Mcclearn, D. 1985. Anatomy of raccoon (Procyon lotor) and coati (Nasua narica and N. nasua) forearm and leg muscles: Relations between fiber length, moment‐arm length, and joint‐angle excursion. Journal of Morphology 183(1):87-115. and Taverne et al., 2018Taverne, M.; Fabre, A. C.; Herbin, M.; Herrel, A.; Peigmé, S.; Lacroux, C.; Lowi, A.; Pagès, F.; Theil, J. C. & Böhmer, C. 2018. Convergence in the functional properties of forelimb muscles in carnivorans: adaptations to an arboreal lifestyle? Biological Journal of the Linnean Society 125:250-263. ) and remained partlty fused in P. cancrivorus.

The m. extensor carpi ulnaris in P. cancrivorus should act as an abductor of the carpal joint and extensor or flexor of the carpus when the carpal joint is already extended or flexed respectively, such as occur in other carnivorans (Singh, 2018Singh, B. 2018. Dyce, Sack and Wensing’ textbook of veterinary anatomy. 5ed. St. Louis, Elsevier. 854p.; Smith et al., 2020Smith, H. F.; Adrian, B.; Koshy, R.; Alwiel, R. & Grossman, A. 2020. Adaptations to cursoriality and digit reduction in the forelimb of the African wild dog (Lycaon pictus). Peer Journal 8:1-34.; Vélez-García et al., 2021Vélez‐García, J. F.; Chunganá‐Caicedo, D. & Saavedra‐Montealegre, S. 2021. Gross anatomy of the craniolateral antebrachial muscles in kinkajou (Potos flavus, Carnivora): Intra‐and interspecific variants within the family Procyonidae. Anatomia, Histologia, Embryologia 51(2):308-313.). The extensor carpi radialis and the abductor digiti I longus muscles could counteract the action of the m. extensor carpi ulnaris abducting the carpus in P. cancrivorus. Thereby, these actions allow more movements of its hands due to the high handling habilities of the genus Procyon (Mcclearn, 1992Mcclearn, D. 1992. Locomotion, posture, and feeding behavior of kinkajous, coatis, and raccoons. Journal of Mammalogy 73(2):245-261.).

The m. extensor digitorum communis extends the digits II to V and in some variant cases in P. cancrivorus, it also extends the digit I similar to M. foina (Böhmer et al., 2020Böhmer, C.; Theil, J. C.; Fabre, A. C. & Herrel, A. 2020. Atlas of terrestrial mammal limbs. Boca Raton, CRC Press. 383p.) and some felids (Viranta et al., 2016Viranta, S.; Lommi, H.; Holmala, K. & Laakkonen, J. 2016. Musculoskeletal anatomy of the Eurasian lynx, Lynx lynx (Carnivora: Felidae) forelimb: adaptations to capture large prey? Journal of Morphology 277(6):753-765. ; Vargas et al., 2017Vargas, J. F.; Quintana, O.; Barraza, C. & Olivares, R. 2017. Descripción anatómica de la musculatura intrínseca del miembro torácico de león (Panthera leo). International Journal of Morphology 35(3):1154-1160. ). Therefore, that tendon is a characteristic that could have had the common ancestor of the carnivorans when the digit I was more functional, and thus it can appear in species with high use of the digit I, such as musteloids and felids. However, the extension of the digit I in all carnivorans is always performed by the abductor digiti longus I and extensor digiti I et II muscles. This latter muscle, in the case of P. cancrivorus also supports the extension of the digit III, although this support is not always necessary since the tendon to this digit can be absent (Windle, 1888Windle, B. C. 1888. Notes on the Limb Myology of Procyon cancrivorus and of the Ursidœ. Journal of Anatomy 23(1):81-89. ). However, the higher proportion of presentation of this tendon in P. cancrivorus allows us to infer that the common ancestor of the caniformes had it, therefore it may be present in other caniformes species as an anatomical variant and a phylogenetic trait. On the other side, the extension of the digits III to V is supported by the m. extensor digitorum lateralis, such as occur in most carnivorans.

This study confirms that P. cancrivorus has intraspecific variations that anatomically are related to other carnivorans, such as the tendon for the digit I from the m. extensor digitorum communis, the origin from the ulna of the m. extensor carpi ulnaris, the origins from the antebrachial fascia and the intermuscular septa of the extensor digitorum communis and lateralis muscles. In contrast, another intraspecific variation was not related to other carnivorans, such as the origin of the m. abductor I digiti longus from the lateral collateral ligament of the elbow. Therefore, it could be a proper anatomical variation of P. cancrivorus based on the comparative review. On the other side, the brachioradialis, extensor carpi radialis, supinator, and extensor digiti I et II are the most anatomically variant muscles among carnivoran species. However, there are only functional differences when there is a well-developed m. brachioradialis, and when the distribution of tendons is different from the digital extensor muscles.

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