An optimized animal model for partial and total skin thickness burns studies

Campelo, Ana Paula Bomfim Soares; Campelo, Marcio Wilker Soares; Britto, Gerly Anne de Castro; Ayala, Alejandro Pedro; Guimarães, Sergio Botelho; Vasconcelos, Paulo Roberto Leitão de

doi:10.1590/S0102-86502011000700008

Abstracts

PURPOSE: Development of an improved animal model for studying skin burns in rats. METHODS: Twenty-four male Wistar rats were randomly assigned to four groups (n=6): G1-Control, G2- T100°C, G3-T150°C and G4-T200°C. Two 10 x 10 mm squares were outlined with a sterile surgical marker on each side and along the vertebral column using a prepared template positioned between the anterior and posterior limbs. G2-G4 rats were subjected to 100°C, 150°C and 200ºC thermal burns, respectively. G1 rats served as controls. Burns were inflicted by applying a copper plate connected to an electronic temperature controlling device to the dorsal skin of anesthetized rats. Four burns were produced on each animal (total area: 4 cm²/animal) leaving about 1 cm of undamaged skin between burn areas. Analgesia was administered during 24 h after burn injury by adding 30 mg codeine phosphate hemihydrate to 500 ml tap water. RESULTS: The application of 100°C and 150ºC resulted in partial thickness skin burns with central reepithelialization of the burned area only at 100°C. In G4 group the whole thickness of the skin was injured without central reepithelialization. However, there was marginal reepithelialization in all groups. CONCLUSION: The model studied is inexpensive and easily reproducible, enabling the achievement of controlled burns with partial or total impairment of the skin in experimental animals.

Models; Hot Temperature; Burns; Rats

OBJETIVO: Desenvolvimento de um modelo animal aperfeiçoado para estudo de queimaduras cutâneas em ratos. MÉTODOS: Vinte e quatro ratos Wistar, machos, foram distribuídos aleatoriamente em quatro grupos (n=6): G1-Controle, G2-T100°C, G3-T150°C e G4-T200°C. Dois quadrados medindo 10x10 mm foram delineados com um marcador cirúrgico estéril em cada lado e ao longo da coluna vertebral e posicionados entre os membros anteriores e posteriores, utilizando um molde previamente preparado. Os ratos dos grupos G2-G4 foram submetidos a queimaduras térmicas de 100°C, 150°C e 200°C, respectivamente. O grupo G1 foi utilizado como controle. As queimaduras foram infligidas pela aplicação de uma placa de cobre, ligada a um dispositivo de controle eletrônico de temperatura, na pele dorsal de ratos anestesiados. Quatro queimaduras foram produzidas em cada animal (área total: 4 cm2/animal), deixando cerca de 1 cm de pele intacta entre as áreas queimadas. Analgesia foi obtida durante 24 horas após a queimadura por adição de 30mg de fosfato hemi-hidratado de codeína a 500 ml de água potável. RESULTADOS: A aplicação 100°C e 150°C resultou na produção de queimaduras profundas comprometendo parte da espessura da pele, com reepitelização central da área queimada, somente a 100°C. No grupo G4 houve lesão de toda a espessura da pele sem reepitelização central. Entretanto, observou-se reepitelização marginal em todos os grupos estudados. CONCLUSÃO: O modelo estudado é de baixo custo e facilmente reproduzível, propiciando a obtenção controlada de queimaduras com comprometimento parcial ou total da pele, em animais experimentais.

Modelos Animais; Temperatura Alta; Queimaduras; Ratos

8 - ORIGINAL ARTICLE

MODELS, BIOLOGICAL

An optimized animal model for partial and total skin thickness burns studies¹ Correspondence: Paulo Roberto Leitão de Vasconcelos Federal University of Ceara Rua Professor Costa Mendes, 1608/3º andar 60430-140 Fortaleza - CE Brasil Tel.: (55 85)288-8063 Fax: (55 85)288-8064 paulo.vasconcelos@ufc.br

Um modelo animal aperfeiçoado para estudo de queimaduras superficiais e profundas da pele

Ana Paula Bomfim Soares Campelo^I; Marcio Wilker Soares Campelo^II; Gerly Anne de Castro Britto^III; Alejandro Pedro Ayala^IV; Sergio Botelho Guimarães^V; Paulo Roberto Leitão de Vasconcelos^VI

^IFellow Master Degree, Department of Surgery, Postgraduate Program, UFC, Fortaleza, Brazil. Technical procedures, acquisition and interpretation of data. The article is part of a Master Degree dissertation

^IIFellow PhD Degree, Department of Surgery, Postgraduate Program, UFC, Fortaleza, Brazil. Technical procedures and interpretation of data

^IIIPhD, Associate Professor, Department of Morphology, UFC, Fortaleza, Brazil.Technical procedures and interpretation of data

^IVPhD, Associate Professor, Department of Physics, UFC, Ceara, Brazil. Technical procedures and interpretation of data

^VPhD, Associate Professor, Department of Surgery, Head, LABCEX, UFC, Ceara, Brazil. Manuscript writing, statistical analysis, graphics design

^VIPhD, Associate Professor, Coordinator, Postgraduate Program, Department of Surgery, UFC, Ceara, Brazil. Tutor, responsible for conception, design, intellectual and scientific content of the study, critical analysis, final approval of manuscript

^{Correspondence} Correspondence: Paulo Roberto Leitão de Vasconcelos Federal University of Ceara Rua Professor Costa Mendes, 1608/3º andar 60430-140 Fortaleza - CE Brasil Tel.: (55 85)288-8063 Fax: (55 85)288-8064 paulo.vasconcelos@ufc.br

ABSTRACT

PURPOSE: Development of an improved animal model for studying skin burns in rats.

METHODS: Twenty-four male Wistar rats were randomly assigned to four groups (n=6): G1-Control, G2- T100°C, G3-T150°C and G4-T200°C. Two 10 x 10 mm squares were outlined with a sterile surgical marker on each side and along the vertebral column using a prepared template positioned between the anterior and posterior limbs. G2-G4 rats were subjected to 100°C, 150°C and 200ºC thermal burns, respectively. G1 rats served as controls. Burns were inflicted by applying a copper plate connected to an electronic temperature controlling device to the dorsal skin of anesthetized rats. Four burns were produced on each animal (total area: 4 cm²/animal) leaving about 1 cm of undamaged skin between burn areas. Analgesia was administered during 24 h after burn injury by adding 30 mg codeine phosphate hemihydrate to 500 ml tap water.

RESULTS: The application of 100°C and 150ºC resulted in partial thickness skin burns with central reepithelialization of the burned area only at 100°C. In G4 group the whole thickness of the skin was injured without central reepithelialization. However, there was marginal reepithelialization in all groups.

CONCLUSION: The model studied is inexpensive and easily reproducible, enabling the achievement of controlled burns with partial or total impairment of the skin in experimental animals.

Keywords: Models, Animal. Hot Temperature. Burns. Rats.

RESUMO

OBJETIVO: Desenvolvimento de um modelo animal aperfeiçoado para estudo de queimaduras cutâneas em ratos.

MÉTODOS: Vinte e quatro ratos Wistar, machos, foram distribuídos aleatoriamente em quatro grupos (n=6): G1-Controle, G2-T100°C, G3-T150°C e G4-T200°C. Dois quadrados medindo 10x10 mm foram delineados com um marcador cirúrgico estéril em cada lado e ao longo da coluna vertebral e posicionados entre os membros anteriores e posteriores, utilizando um molde previamente preparado. Os ratos dos grupos G2-G4 foram submetidos a queimaduras térmicas de 100°C, 150°C e 200°C, respectivamente. O grupo G1 foi utilizado como controle. As queimaduras foram infligidas pela aplicação de uma placa de cobre, ligada a um dispositivo de controle eletrônico de temperatura, na pele dorsal de ratos anestesiados. Quatro queimaduras foram produzidas em cada animal (área total: 4 cm2/animal), deixando cerca de 1 cm de pele intacta entre as áreas queimadas. Analgesia foi obtida durante 24 horas após a queimadura por adição de 30mg de fosfato hemi-hidratado de codeína a 500 ml de água potável.

RESULTADOS: A aplicação 100°C e 150°C resultou na produção de queimaduras profundas comprometendo parte da espessura da pele, com reepitelização central da área queimada, somente a 100°C. No grupo G4 houve lesão de toda a espessura da pele sem reepitelização central. Entretanto, observou-se reepitelização marginal em todos os grupos estudados.

CONCLUSÃO: O modelo estudado é de baixo custo e facilmente reproduzível, propiciando a obtenção controlada de queimaduras com comprometimento parcial ou total da pele, em animais experimentais.

Descritores: Modelos Animais. Temperatura Alta. Queimaduras. Ratos.

Introduction

Induction of experimental burns in animal models is an essential tool to understand the pathogenesis of skin damage due to burns in humans and for designing new methods of treatment. Animal models have been used to investigate burn wound pathology, local therapy¹, the influence of systemic drug application on the burn wound and the effect of burn trauma on the entire organism². Inconsistency and irreproducibility are commonly found in experimental studies. Two factors may be related to the controversial and different findings presented in the available literature: burn models are not identical or different modalities of treatment are used by researchers.

The present study was therefore undertaken to determine the optimal experimental model of burns heat-induced by direct conduction in rats, correlating standardized temperatures and lesion depths (partial or total skin thickness burn).

Methods

Approval for experimental use of laboratory animals was obtained on September, 2010 (Protocol #37/10) from the Ethics Committee on Animal Research (CEPA) of the Federal University of Ceara, now Ethics Committee on the Use of Animals (CEUA), in view of the Federal Law No. 11794 of October 8, 2008, http://www.planalto.gov.br/ccivil_03/_Ato2007-2010/2008/Lei/L11794.htm and Decree No. 6689 of July 15, 2009 that regulated the Law 11794, available at: http://www.planalto.gov.br/ccivil_03/_Ato2007-2010/2009/Decreto/D6899.htm.

The study was designed to minimize the number of animals required for the experiments. The animals were housed in polypropylene cages at ambient temperature of 24ºC on a 12 h light-dark cycle.

Study design

Twenty-four male Wistar rats were randomly assigned to four groups (n=6): G1-Control, G2-T100°C, G3-T150°C and G4-T200°C. Two 10 x 10 mm squares were outlined with a sterile surgical marker on each side and along the vertebral column using a prepared template (an X-ray film with a 10 x 10 mm grid) positioned between the anterior and posterior limbs. G2-G4 rats were subjected to 100°C, 150°C and 200°C thermal burns, respectively. G1 rats served as controls. Immediately before inflicting the burn, the area was shaved with a standard electric shaving machine to obtain a smooth surface and hairless skin. The dorsal skin was surgically prepared with successive applications of 2% chlorhexidine scrub. A previously described model^3,4 was used with some modifications. The original tip of an ordinary 40W soldering iron was replaced with tip and square 10 x 10mm copper plate. An electronic temperature controller with a thermocouple-type feedback sensor was connected 2 mm above the plate tip in order to allow precise optimal temperature monitoring at the tip of the instrument. Additionally, a digital multimeter with a K type thermocouple was fixed to the copper plate to assure real time optimal control of the temperature applied to the skin (surface counter). The desired stamp temperature (100°C, 150°C and 200°C) was reached 5 min after switching on the electric current. The device was positioned vertically under its own weight (85g) and applied to each skin burn site during 9 seconds to inflict the burns as outlined. Immediately after each burn injury, the respective wound was cooled off during 1 min with gauze embedded in isotonic saline at 22°C, as described elsewhere⁵. The plate produced a burn area of approximately 1 cm²/ wound. Four burns were produced on each animal (4 cm²/animal) leaving approximately 1 cm intact skin between burn areas. Following conclusion of the procedure, the animals were returned to their individual cages for recovery with free access to rat chow and tap water. Analgesia was administered during 24h after burn injury by adding 30 mg codeine phosphate hemihydrate to 500 ml tap water.

Anesthesia

Anesthesia was induced with an intramuscular injection of ketamine hydrochloride (90 mg/kg) and xylazine (10 mg/kg) to all rats.

Macroscopic analysis

Anesthetized rats were photographed in the seventh day post-burn under anesthesia and standard lighting conditions using a tripod-mounted digital camera (Sony DSC-W35, 7.2 mega pixels) with a constant 1.0 x zoom at 35 cm distance from the dorsum of the animal. The Images (format TIFF, 512 x 384 pixels) were calibrated and the wound surface area (mm²) and perimeter (mm) were calculated by computerized planimetry using the software Image Tool 3.0 (University of Texas Health Center at San Antonio).

Histopathology

At the end of the experiments all animals were killed by an overdose of anesthetics (Ketamine+xylazine). Tissue samples were collected from the dorsum with a surgical blade, removing skin fragments (20 mm x 5 mm), including the central scar, adjacent healthy tissue and underlying panniculus carnosus muscle. Tissue samples were fixed in formalin for 24 hours before being transferred to 70% ethanol solution. Further processing included paraffin embedding and sectioning, to generate 5-µm-thick tissue coronal sections to be mounted on glass slides. The slides were stained using hematoxylin and eosin. The extent of skin damage was assessed by a blind pathologist using a light microscope (Olympus, X100).

Statistical analysis

Graphpad Prism 5.0 (GraphPad Software, www.graphpad.com) was used for statistical analysis and graphics design. Data from images (wound surface area and perimeter) were tested for distribution (Kolmorogov-Smirnov test). Results were expressed as mean+SD. Groups were compared at different temperature (100 °C, 150 °C and 200 °C) using Student's t test for unpaired variables. The level of statistical significance was set at 5%. Histopathology findings were tabulated for descriptive analysis.

Results

No infection or mortality was observed during the experiments and no systemic complications were clinically detectable.

Macroscopic analysis

Wound surface area and perimeter (Figures 1 and 2) shown by digital planimetry did not differ significantly when comparing G2 (T100°C) and G3 (T150°C) groups (p > 0.05). However, wound surface area in G4 (T200°C) rats was larger than in G2 group by Student's paired t test (p< 0.03). The same was true for wound perimeter (p < 0.04) (Figure 3).

Microscopic analysis

Scars were present in all wounds along incipient marginal reepithelization (Figure 4, images E, G and J). Incipient central reepithelialization was present in G2 only (Figure 4, image F). The dermis presented obliterated vessels and partially damaged pilosebaceous units in groups G2 and G3 (Figure 4, images C, E and H). Total dermis and muscle damage were found in G4 rats (Figure 4, images J and L). Musculature layers were preserved in G2 and G3 rats (Figure 4, images D and I, respectively). Table 1 depicts the Presence/absence of skin structures and reepithelialization in G2-G4 rats.

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Discussion

Over the past decade much has been discovered concerning the pathophysiology and forms of treatment of burn lesions. Different burn models have been presented. Methods for producing experimental burns included boiling water⁶, heated brass bar⁷, heated (130°C) aluminum plate⁸, a constant-temperature hot plate (170ªC) placed over stainless steel rods⁹ and scalding over 45% of the body surface¹⁰.

In the present study, skin burns were inflicted by transference of energy (heat) using direct conduction (Copper/skin) utilizing different increasing temperatures (100°C, 150°C and 200°C). Thermal energy transfer by conduction from a solid structure to the skin surface does not depend on the pressure employed, but mainly on the temperature gradient between the skin, the solid structure and the distance between those elements¹¹. To the best of our knowledge, this is it the fist work where a copper template is used to induce thermal burns. Copper thermal conductivity is more efficient than other metals used by researchers^1,7,12.

The results clearly demonstrated that this experimental model provided excellent contrast between normal and burned tissue at different temperatures. Thus, the highest temperature used (200°C) producing lesions in all skin layers with damaged pilosebaceous units resulting in poor central reepithelialization, making being this method a good choice to evaluate drug effects in severe burnings.

Moreover, it was possible to obtain partial skin thickness burn with lesser temperatures (100°C and 150°C). However, burning at 150°C was more deeper than 100°C and the central reepithelialization occurred only when the plate was heated to 100°C. The partial-thickness burn model (using 100°C and 150°C) in this study spares some epithelial elements within the dermis, allowing for spontaneous regeneration (reepithelialization) via proliferation and migration of epithelial cells from dermal appendages remaining at the wound site and from the wound margins^13-14. Practically, it implies that a deep partial skin thickness burn should not be converted into a full skin thickness injury.

In order to achieve consistent reproducibility, the stamp pressure should be identical in all lesions and positions to ensure maximal skin contact. A major advantage of the hand-held stamp using the device weight to induce the burn lesion is that it remains constant throughout the procedure and is not related to the pressure exerted by the researcher that can present some changes due to the difficulty of figuring out the intensity of pressure that should be applied to the skin of the animal.

Conclusion

The model studied is inexpensive and easily reproducible, enabling the achievement of controlled burns with partial or total impairment of the skin in experimental animals.

Acknowledgements

We are in debt to Mrs Beatrice Nuto Nobrega (medical student, UFC, Ceara, Brazil), Maria do Socorro F. Monte and Conceição da Silva Martins (technicians, Laboratory of Morphology/UFC) for their helpful technical assistance.

Conflict of interest: none

Financial source: CNPq

1 Research performed at Experimental Surgery Laboratory (LABCEX), Faculty of Medicine, Federal University of Ceara (UFC), Fortaleza-CE, Brazil.

1. Kaufman T, Lusthaus SN, Sagher U, Wexler MR. Deep partial skin thickness burns: a reproducible animal model to study burn wound healing. Burns. 1990;16(1):13-6.
2. Aulick LH, Baze WB, Johnson AA, Wilmore DW, Mason AD Jr. A large animal model of burn hypermetabolism. J Surg Res. 1981;31(4):281-7.
3. Kistler D, Hafemann B, Schmidt K. A model to reproduce predictable full-thickness burns in an experimental animal. Burns Incl Therm Inj. 1988;14(4):297-302.
4. de Mesquita CJ, Leite JA, Fechine FV, de C Rocha JL, Leite JG, Leite Filho JA, Barbosa Filho RA. Effect of imiquimod on partial-thickness burns. Burns. 2010;36(1):97-108.
5. Jandera V, Hudson DA, de Wet PM, Innes PM, Rode H. Cooling the burn wound: evaluation of different modalites. Burns. 2000; 26 (3):265-70.
6. Barbosa RCC, Guimarães SB, Vasconcelos PRC de, Chaves CR, Vasconcelos PRL de. Efeitos metabólicos da glutamina em ratos submetidos à queimadura por água fervente (escaldadura). Acta Cir Bras. 2003;18(6):537-41.
7. Meyer TN, Silva AL da. A standard burn model using rats. Acta Cir Bras. 1999;14(4): Available from URL: http://www.scielo.br/acb
8. Medeiros AC, Ramos AMO, Dantas Filho AM, Azevedo RCF, Araújo FLFB. Tratamento tópico de queimaduras do dorso de ratos com ácido hialurônico. Acta Cir Bras. 1999;14(4). Available from: URL: http://www.scielo.br/acb
9. Sobral CS, Gragnani A, Morgan J, Ferreira LM. Inhibition of proliferation of Pseudomonas aeruginosa by KGF in an experimental burn model using human cultured keratinocytes. Burns. 2007;33(5):613-20.
10. Oliveira F de, Bevilacqua LR, Anaruma CA, Boldrini SC, Liberti EA. Morphological changes in distant muscle fibers following thermal injury in Wistar rats. Acta Cir Bras. 2010;25(6):525-8.
11. Davies JWL. Physiological response to burning injury. London: Academic Press; 1982.
12. Knabl JS, Bayer GS, Bauer WA, Schwendenwein I, Dado PF, Kucher C, Horvat R, Turkof E, Schossmann B, Meissl G. Controlled partial skin thickness burns: an animal model for studies of burn wound progression. Burns. 1999;25(3):229-35.
13. Dorsett-Martin WA, Wysocki A. Rat models of skin wound healing. In: Conn PM, editor. Sourcebook of models for biomedical research. Totowa: Humana Press; 2008. p.631-8.
14. Dorsett-Martin WA. Rat models of skin wound healing: a review. Wound Repair Regen. 2004;12(6):591-9.

Correspondence:

Paulo Roberto Leitão de Vasconcelos

Federal University of Ceara

Rua Professor Costa Mendes, 1608/3º andar

60430-140 Fortaleza - CE Brasil

Tel.: (55 85)288-8063

Fax: (55 85)288-8064

paulo.vasconcelos@ufc.br

Publication Dates

Publication in this collection
23 Sept 2011
Date of issue
2011

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Kaufman T, Lusthaus SN, Sagher U, Wexler MR. Deep partial skin thickness burns: a reproducible animal model to study burn wound healing. Burns. 1990;16(1):13-6.

[2] 2. Aulick LH, Baze WB, Johnson AA, Wilmore DW, Mason AD Jr. A large animal model of burn hypermetabolism. J Surg Res. 1981;31(4):281-7.

[3] 3. Kistler D, Hafemann B, Schmidt K. A model to reproduce predictable full-thickness burns in an experimental animal. Burns Incl Therm Inj. 1988;14(4):297-302.

[4] 4. de Mesquita CJ, Leite JA, Fechine FV, de C Rocha JL, Leite JG, Leite Filho JA, Barbosa Filho RA. Effect of imiquimod on partial-thickness burns. Burns. 2010;36(1):97-108.

[5] 5. Jandera V, Hudson DA, de Wet PM, Innes PM, Rode H. Cooling the burn wound: evaluation of different modalites. Burns. 2000; 26 (3):265-70.

[6] 6. Barbosa RCC, Guimarães SB, Vasconcelos PRC de, Chaves CR, Vasconcelos PRL de. Efeitos metabólicos da glutamina em ratos submetidos à queimadura por água fervente (escaldadura). Acta Cir Bras. 2003;18(6):537-41.

[7] 7. Meyer TN, Silva AL da. A standard burn model using rats. Acta Cir Bras. 1999;14(4): Available from URL: http://www.scielo.br/acb

[8] 8. Medeiros AC, Ramos AMO, Dantas Filho AM, Azevedo RCF, Araújo FLFB. Tratamento tópico de queimaduras do dorso de ratos com ácido hialurônico. Acta Cir Bras. 1999;14(4). Available from: URL: http://www.scielo.br/acb

[9] 9. Sobral CS, Gragnani A, Morgan J, Ferreira LM. Inhibition of proliferation of Pseudomonas aeruginosa by KGF in an experimental burn model using human cultured keratinocytes. Burns. 2007;33(5):613-20.

[10] 10. Oliveira F de, Bevilacqua LR, Anaruma CA, Boldrini SC, Liberti EA. Morphological changes in distant muscle fibers following thermal injury in Wistar rats. Acta Cir Bras. 2010;25(6):525-8.

[11] 11. Davies JWL. Physiological response to burning injury. London: Academic Press; 1982.

[12] 12. Knabl JS, Bayer GS, Bauer WA, Schwendenwein I, Dado PF, Kucher C, Horvat R, Turkof E, Schossmann B, Meissl G. Controlled partial skin thickness burns: an animal model for studies of burn wound progression. Burns. 1999;25(3):229-35.

[13] 13. Dorsett-Martin WA, Wysocki A. Rat models of skin wound healing. In: Conn PM, editor. Sourcebook of models for biomedical research. Totowa: Humana Press; 2008. p.631-8.

[14] 14. Dorsett-Martin WA. Rat models of skin wound healing: a review. Wound Repair Regen. 2004;12(6):591-9.