Porcine peritoneum as source of biocompatible collagen in mice

Jardelino, Cristina; Takamori, Esther Rieko; Hermida, Luiz Felipe; Lenharo, Ariel; Castro-Silva, Igor Iuco; Granjeiro, Jose Mauro

doi:10.1590/S0102-86502010000400006

Abstracts

PURPOSE: To investigate the biocompatibility and biodegradability of a membrane made from porcine peritoneum. METHODS: The membrane (5x5 mm) was inserted in the subcutaneous tissue on the back of 15 mice, which were killed after 1, 3 and 9 weeks (ISO 10993-6). The cellular components of the inflammatory response and degradation of the membrane were analyzed in hematoxylin-eosin-stained histological sections. RESULTS: After one week, mononuclear cells were observed inside the membrane. After three weeks, the material was almost completely absorbed. After nine weeks, there was no presence of material and there were signs of tissue remodeling. There was neither a foreign body reaction nor signs of tissue necrosis. CONCLUSION: The collagen membrane derived from porcine peritoneum is biocompatible and bioabsorbable when implanted in the subcutaneous tissue of mice.

Materials Testing; Biocompatible Materials; Subcutaneous Tissue; Peritoneum; Mice

OBJETIVO: Investigar a biocompatibilidade e biodegradabilidade de uma membrana feita de peritônio suíno. MÉTODOS: A membrana (5x5 mm) foi inserida no tecido subcutâneo dorsal de 15 camundongos, que foram mortos após uma, três e nove semanas (ISO 10993-6). Os componentes celulares da resposta inflamatória e a degradação da membrana foram analisados em cortes corados em hematoxilina-eosina. RESULTADOS: Após uma semana, células mononucleares foram observadas dentro da membrana. Após três semanas, o material foi quase completamente absorvido. Após nove semanas, não houve presença do material e houve sinais de remodelação tecidual. Não houve reação de corpo estranho nem sinais de necrose tecidual. CONCLUSÃO: A membrana colágena derivada de peritônio suíno é biocompatível e bioabsorvível quando implantada no tecido subcutâneo do camundongo.

Teste de Materiais; Materiais Biocompatíveis; Tela Subcutânea; Peritônio; Camundongos

6 - ORIGINAL ARTICLE

MATERIALS TESTING

Porcine peritoneum as source of biocompatible collagen in mice¹ Correspondence: Jose Mauro Granjeiro Hospital Universitário Antonio Pedro Unidade de Pesquisa Clínica Rua Marques do Paraná, 303 24033-900 Niterói - RJ Brazil Phone: (55 21)2629-9255 jmgranjeiro@gmail.com.br

Peritônio suíno como fonte de colágeno biocompatível em camundongos

Cristina Jardelino^I; Esther Rieko Takamori^II; Luiz Felipe Hermida^III; Ariel Lenharo^IV; Igor Iuco Castro-Silva^V; Jose Mauro Granjeiro^VI

^IFellow Master degree, Post-graduate Program in Dentistry, Dental School, UFF, Rio de Janeiro, Brazil

^IIPhD, National Institute of Experiments and Research in Odontology (INEPO), Brazil

^IIIScientific Initiation Student, Faculty of Veterinary Medicine, UFF, Rio de Janeiro, Brazil

^IVPhD, Head of National Institute of Experiments and Research in Odontology (INEPO), Brazil

^VMaster, Cell Therapy Center, Biology Institute and Unit of Clinical Research, UFF, Rio de Janeiro, Brazil

^VIAssociate Professor, Cell Therapy Center, Unit of Clinical Research and Biology Institute, UFF, Rio de Janeiro, Brazil

^{Correspondence} Correspondence: Jose Mauro Granjeiro Hospital Universitário Antonio Pedro Unidade de Pesquisa Clínica Rua Marques do Paraná, 303 24033-900 Niterói - RJ Brazil Phone: (55 21)2629-9255 jmgranjeiro@gmail.com.br

ABSTRACT

PURPOSE: To investigate the biocompatibility and biodegradability of a membrane made from porcine peritoneum.

METHODS: The membrane (5x5 mm) was inserted in the subcutaneous tissue on the back of 15 mice, which were killed after 1, 3 and 9 weeks (ISO 10993-6). The cellular components of the inflammatory response and degradation of the membrane were analyzed in hematoxylin-eosin-stained histological sections.

RESULTS: After one week, mononuclear cells were observed inside the membrane. After three weeks, the material was almost completely absorbed. After nine weeks, there was no presence of material and there were signs of tissue remodeling. There was neither a foreign body reaction nor signs of tissue necrosis.

CONCLUSION: The collagen membrane derived from porcine peritoneum is biocompatible and bioabsorbable when implanted in the subcutaneous tissue of mice.

Key words: Materials Testing. Biocompatible Materials. Subcutaneous Tissue. Peritoneum. Mice

RESUMO

OBJETIVO: Investigar a biocompatibilidade e biodegradabilidade de uma membrana feita de peritônio suíno.

MÉTODOS: A membrana (5x5 mm) foi inserida no tecido subcutâneo dorsal de 15 camundongos, que foram mortos após uma, três e nove semanas (ISO 10993-6). Os componentes celulares da resposta inflamatória e a degradação da membrana foram analisados em cortes corados em hematoxilina-eosina.

RESULTADOS: Após uma semana, células mononucleares foram observadas dentro da membrana. Após três semanas, o material foi quase completamente absorvido. Após nove semanas, não houve presença do material e houve sinais de remodelação tecidual. Não houve reação de corpo estranho nem sinais de necrose tecidual.

CONCLUSÃO: A membrana colágena derivada de peritônio suíno é biocompatível e bioabsorvível quando implantada no tecido subcutâneo do camundongo.

Descritores: Teste de Materiais. Materiais Biocompatíveis. Tela Subcutânea. Peritônio. Camundongos.

Introduction

Tissue regeneration has been a significant challenge for clinical and dental medicine. The use of absorbable and non-absorbable membranes is meant to guide tissue repair so to favor its regeneration despite the healing processes. These membranes are supposed to prevent fibroblast migration and invasion, exclude inhibiting factors, concentrate factors that stimulate growth on the site, have stimulating properties, and be rigid, but not to the point of hindering them from being handled¹.

Porcine peritoneum is a suitable tissue for the production of membranes that will be used in Guided Tissue Regeneration (GTR) and Guided Bone Regeneration (GBR), since its structure, which consists mainly of collagen, results in a biocompatible and absorbable material², when processed properly.

Collagen has been considered superior to other materials for working actively on clot formation and promoting fibroblast chemotaxis³. However, the enzymatic activity of macrophages and polymorphonuclear leukocytes results in fast biodegradation of native collagen, thus allowing undesired cell types to invade the graft area⁴. Several techniques have been used in order to extend the biodegradation time of collagen-based membranes. Physical and chemical treatments have been investigated with the purpose of controlling the degradation of the collagen membrane^5,6.

Despite its degradability, its potential for bladder reconstruction⁷, tissue engineering of the small intestine⁸, reconstruction of the flexor tendon sheath⁹ and for periodontal healing² has been investigated.

Recently, a collagen membrane produced from cortical bovine bone tissue promoted the complete regeneration of critical defects in rat skulls, demonstrating the potential this type of biomesh has for regeneration processes¹⁰.

The objective of this study is to evaluate tissue response and biodegradation of a membrane derived from acellular porcine peritoneum.

Methods

Porcine peritoneum membrane (PPM) was obtained in slaughterhouses certified by the Federal Inspection Service and that have a tracking system. The material was processed by means of mechanical cleaning, chemical treatment, liophylization (freeze-drying) and sterilization. The lyophilized membranes were cut into 5 mm x 5 mm sections, individually packed and sterilized by gamma radiation (25KGy).

The study used 15 Balb/c 60-day-old mice (around 75g) obtained from the UFF Animals Center, which throughout the entire experimental period were kept under proper hygiene and care conditions, according to Brazilian College of Animal Experimentation (COBEA) standards and as approved by the Committee on Animal Research and Ethics (Protocol N. 0035-8). The animals received food and water ad libitum.

The animals were sedated with a mixture of ketamine hydrochloride (Dopalen^®) and xylazine hydrochloride (Anasedan^®), in a 1:1 (v/v) proportion, which was applied by intramuscular route at 0.5 ml per kg of body weight. After the region submitted to the surgical procedure underwent trichotomy and antisepsis, the dorsal region of each animal received a 1.5cm-incision for the material implant. A PPM was implanted in the animals' subcutaneous tissue. The animals were killed 1, 3 and 9 weeks later through cervical dislocation. Whenever possible, palpation of the subcutaneous tissue allowed to locate the membrane, which was removed involved in granulation tissue with a safety margin of approximately 2 mm.

The histological sections containing the collected material were fixed in 10% buffered formalin solution, pH 7.2, and processed for inclusion in paraffin wax. 5µm-thick sections were stained with hematoxylin and eosin (HE) and evaluated in regards to type and intensity of the inflammatory infiltrate, presence and integrity of the membrane.

Results

In the first 24 hours following the surgery, all animals were clinically healthy, presenting a slight edema in the dorsal region, which is compatible with the surgical procedure that had been performed; they did not present any signs of necrosis, suppuration or infection. Seven days after surgery, the material was easy to locate through palpation of the animals dorsal region; this fact was not observed at the other points of the essay. After nine weeks, it was not possible to locate any signs indicating the presence of the membrane, even after extensive divulsion of the subcutaneous tissue.

1 week. At this point, it was observed that the material was not much integrated in the subcutaneous tissue, but was involved in vascularized granulation tissue. The microscopic analysis showed first signs of membrane degradation through the increase of intrafibrilar gaps, although a dense and compact region remained (Figure 1). There was an intensive inflammatory infiltrate with predominance of mononuclear cells that are compatible with the macrophages observed permeating PPM fibers. In this period, polymorphonuclear leukocytes were only occasionally observed (Figure 1).

3 weeks. The macroscopic analysis did not detect PPM in 3 of the 5 animals used at this point, but a fibrous tissue remained in the area of its likely location. The microscopic analysis showed an almost complete degradation of the material in 3 animals (Figure 2). However, in 2 animals there was still spacing between membrane fibers, edema areas and an intense mononuclear inflammatory infiltrate, mainly of macrophages, and some occasional multinuclear giant cells. Fibroblastic proliferation was intense and indicated tissue remodeling.

9 weeks. At this point of the essay, none of the animals presented presence of PPM. The conjunctive tissue was loosely organized and there were still some congested vessels, suggesting tissue remodeling, as well as the presence of skin annexes, such as the sweat duct (Figure 3).

Discussion

The objective of this study was to analyze the biocompatibility and biodegradability of a membrane processed from porcine peritoneum. Results have shown that the processed membrane is biocompatible and reabsorbable after a period of three weeks.

Since it is absorbable, PPM does not have to be removed after being implanted. This constitutes an advantage, particularly in implantodontics, periodontology and dental surgeries, since non-reabsorbable membranes, such as those made of polytetrafluorethylene, require a second surgical procedure to remove them, which may cause post-surgical complications, as well as discomfort for the patient¹¹.

For guided bone regeneration applications in dentistry, the membrane has to remain whole from the structural and functional point of view for, at least, six weeks in humans so to allow for the migration of osteogenic cells and promote the regeneration of the lost original tissue; this period is critical for the regeneration process. Studies emphasize that membranes with a very short reabsorption time, i.e. less than three weeks, should be avoided. Also, when used as a barrier, the dissolution of the reabsorbable membrane should occur in a time that is predictable and compatible with bone regeneration¹¹.

The chemical composition of a biodegradable membrane determines not only its stability, but also the inflammatory and immune response. The main characteristic of the peritoneum is that it consists mostly of collagen, the most common protein in the animal kingdom and the main constituent of bones, skin and conjunctive tissues of all mammals. Collagen has been largely used in the production of biomaterials and as vehicle for its biocompatibility and minimum immunological response¹². The use of this abundant source associated with the proper processing of these tissues may represent a significant source of new materials, which may be used in tissue engineering or in regeneration techniques^2,7-9.

Membrane derived from porcine type I and III collagen (Bioguide^®), implanted in mice subcutaneous tissue, presents excellent tissue integration, followed by fast vascularization by the end of one month, when a full biodegradation with a discrete reaction to a foreign body occurs. This fast degradation may be explained by the fact that this membrane has pores that favor its degradation, because they improve its interaction with the tissue¹³. In this study, the degradation of the evaluated membrane occurred after three weeks by a mononuclear inflammatory infiltrate and some occasional multinuclear giant cells.

The existence of crossed links does not necessarily mean that the material will be degraded faster. Tissue response to Bioguide^®, which has crossed links, promotes a faster degradation when compared to TutoDent^® (without crossed links), possibly because the latter is more compact, thus hindering cell penetration⁵. However, it has been shown that implants of type I bovine collagen membranes without crossed links promote the reabsorption of biomaterial in 42 days⁶.

In this study, the biodegradation process of the porcine collagen membrane in the subcutaneous tissue of mice was guided by mononuclear macrophage-like cells in week 1, but was amplified by the fibroblastic proliferation as of week three. A comparative study on rat subcutaneous tissue using membranes made of cortical bovine bones treated or not with tetracycline observed great similarity between both groups in regards to their inflammatory infiltrate; both groups presented a primary invasion of PMN and lymphocytes, which was quickly replaced by a mononuclear infiltrate and giant cells¹⁴. Another study, conducted on membrane from bovine pericardium, did not present giant cells as it occurs with bovine bioprostheses¹⁵.

Conclusion

The membrane from porcine peritoneum collagen is biocompatible and bioabsorbable in three weeks when implanted in the subcutaneous tissue of mice.

Acknowledgements

The researchers thank UFF for the research infrastructure, the veterinarians Carlos Augusto de Martino Campos and Maria Lucia Barreto, Heads of the Nucleo de Animais de Laboratorio [UFF Animals Center] for the infrastructure to perform the experimental surgeries and the INEPO for donation of test material.

Received: January 26, 2010

Review: March 23, 2010

Accepted: April 20, 2010

Conflict of interest: none

Financial source: CNPq, FAPERJ

1 Research performed at Cell Therapy Center, Biology Institute and Unit of Clinical Research, Fluminense Federal University (UFF), Rio de Janeiro, Brazil.

1. Wang HL, MacNeil RL. Guided tissue regeneration: absorbable barriers. Dent Clin North Am. 1998;42(3):505-22.
2. Paolantonio M, Scarano A, Di Placido G, Tumini V, D'Archivio D, Piattelli A. Periodontal healing in humans using anorganic bovine bone and bovine peritoneum-derived collagen membrane: a clinical and histologic case report. Int J Periodontics Restorative Dent. 2001;21(5):505-15.
3. Postlethwaite AE, Seyer JM, Kang AH. Chemotactic attraction of human fibroblasts to type I, II, and III collagens and collagen-derived peptides. Proc Natl Acad Sci USA. 1978;75(2):871-5.
4. Tatakis DN, Promsudthi A, Wikesjö UM. Devices for periodontal regeneration. Periodontol 2000. 1999;19:59-73.
5. Paul BF, Mellonig JT, Towle HJ 3rd, Gray JL. Use of collagen barrier to enhance healing in human periodontal furcation defects. Int J Periodontics Restorative Dent. 1992;12(2):123-31.
6. Palma PCR, Marques PC, Vidal BC, Riccetto CLZ, Dambros M, Netto-Jr NR. Histopathological alterations resulting from subcutaneous implant of collagen and autologous aponeurotic fascia: a comparative study in dogs. Braz J Urol. 2001;27(2):171-7.
7. Hattori K, Joraku A, Miyagawa T, Kawai K, Oyasu R, Akaza H. Bladder reconstruction using a collagen patch prefabricated within the omentum. Int J Urol. 2006;13(5):529-37.
8. Hori Y, Nakamura T, Matsumoto K, Kurokawa Y, Satomi S, Shimizu Y. Tissue engineering of the small intestine by acellular collagen sponge scaffold grafting. Int J Artif Organs. 2001;24(1):50-4.
9. Oei TS, Klopper PJ, Spaas JA, Buma P. Reconstruction of the flexor tendon sheath. An experimental study in rabbits. J Hand Surg. 1996;21(1):72-83.
10. Taga ML, Granjeiro JM, Cestari TM, Taga R. Healing of critical-size cranial defects in guinea pigs using a bovine bone-derived resorbable membrane. Int J Oral Maxillofac Implants 2008;23(3):427-36.
11. Aaboe M, Pinholt EM, Hjørting-hansen E, Solheim E, Praetorius F. Guided tissue regeneration using degradable and nondegradable membranes in rabbits. Clin Oral Implant Res. 1993;4(4)172-6.
12. Lemperle G, Morhenn V, Charrier U. Human histology and persistence of various injectable filler substances for soft tissue augmentation. Aesthetic Plast Surg. 2003;27(5):354-66.
13. Unsal B, Kurtis B, Ozcan G, Ozdemir A, Karaöz E. An investigation of resorption and tissue reaction after subcutaneous implantation of collagen based membrane materials in rats. J Marmara Univ Dent Fac. 1997;2(4):609-15.
14. Oliveira RC, Carneiro E, Cestari TM, Taga R, Granjeiro JM. Dynamics of subcutaneous tissue response to the implantation of tetracycline-treated or untreated membrane of demineralized bovine cortical bone in rats. J Biomater Appl. 2006;21(2):167-78.
15. Gasque KCS, Oliveira RC, Ceolin D, Cestari TM, Taga R, Taga EM, Correa A, Paiva KB, Takya CM, Granjeiro JM. Avaliação da biocompatibilidade de uma membrana de pericárdio bovino acelular e seu potencial carreador de fibroblastos. Cienc Odontol Bras. 2008;11(1):58-66.

Correspondence:

Jose Mauro Granjeiro

Hospital Universitário Antonio Pedro

Unidade de Pesquisa Clínica

Rua Marques do Paraná, 303

24033-900 Niterói - RJ Brazil

Phone: (55 21)2629-9255

jmgranjeiro@gmail.com.br

Publication Dates

Publication in this collection
26 July 2010
Date of issue
Aug 2010

History

Received
26 Jan 2010
Reviewed
23 Mar 2010
Accepted
20 Apr 2010

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

[1] 1. Wang HL, MacNeil RL. Guided tissue regeneration: absorbable barriers. Dent Clin North Am. 1998;42(3):505-22.

[2] 2. Paolantonio M, Scarano A, Di Placido G, Tumini V, D'Archivio D, Piattelli A. Periodontal healing in humans using anorganic bovine bone and bovine peritoneum-derived collagen membrane: a clinical and histologic case report. Int J Periodontics Restorative Dent. 2001;21(5):505-15.

[3] 3. Postlethwaite AE, Seyer JM, Kang AH. Chemotactic attraction of human fibroblasts to type I, II, and III collagens and collagen-derived peptides. Proc Natl Acad Sci USA. 1978;75(2):871-5.

[4] 4. Tatakis DN, Promsudthi A, Wikesjö UM. Devices for periodontal regeneration. Periodontol 2000. 1999;19:59-73.

[5] 5. Paul BF, Mellonig JT, Towle HJ 3rd, Gray JL. Use of collagen barrier to enhance healing in human periodontal furcation defects. Int J Periodontics Restorative Dent. 1992;12(2):123-31.

[6] 6. Palma PCR, Marques PC, Vidal BC, Riccetto CLZ, Dambros M, Netto-Jr NR. Histopathological alterations resulting from subcutaneous implant of collagen and autologous aponeurotic fascia: a comparative study in dogs. Braz J Urol. 2001;27(2):171-7.

[7] 7. Hattori K, Joraku A, Miyagawa T, Kawai K, Oyasu R, Akaza H. Bladder reconstruction using a collagen patch prefabricated within the omentum. Int J Urol. 2006;13(5):529-37.

[8] 8. Hori Y, Nakamura T, Matsumoto K, Kurokawa Y, Satomi S, Shimizu Y. Tissue engineering of the small intestine by acellular collagen sponge scaffold grafting. Int J Artif Organs. 2001;24(1):50-4.

[9] 9. Oei TS, Klopper PJ, Spaas JA, Buma P. Reconstruction of the flexor tendon sheath. An experimental study in rabbits. J Hand Surg. 1996;21(1):72-83.

[10] 10. Taga ML, Granjeiro JM, Cestari TM, Taga R. Healing of critical-size cranial defects in guinea pigs using a bovine bone-derived resorbable membrane. Int J Oral Maxillofac Implants 2008;23(3):427-36.

[11] 11. Aaboe M, Pinholt EM, Hjørting-hansen E, Solheim E, Praetorius F. Guided tissue regeneration using degradable and nondegradable membranes in rabbits. Clin Oral Implant Res. 1993;4(4)172-6.

[12] 12. Lemperle G, Morhenn V, Charrier U. Human histology and persistence of various injectable filler substances for soft tissue augmentation. Aesthetic Plast Surg. 2003;27(5):354-66.

[13] 13. Unsal B, Kurtis B, Ozcan G, Ozdemir A, Karaöz E. An investigation of resorption and tissue reaction after subcutaneous implantation of collagen based membrane materials in rats. J Marmara Univ Dent Fac. 1997;2(4):609-15.

[14] 14. Oliveira RC, Carneiro E, Cestari TM, Taga R, Granjeiro JM. Dynamics of subcutaneous tissue response to the implantation of tetracycline-treated or untreated membrane of demineralized bovine cortical bone in rats. J Biomater Appl. 2006;21(2):167-78.

[15] 15. Gasque KCS, Oliveira RC, Ceolin D, Cestari TM, Taga R, Taga EM, Correa A, Paiva KB, Takya CM, Granjeiro JM. Avaliação da biocompatibilidade de uma membrana de pericárdio bovino acelular e seu potencial carreador de fibroblastos. Cienc Odontol Bras. 2008;11(1):58-66.

Brasil

Brasil

Porcine peritoneum as source of biocompatible collagen in mice

Peritônio suíno como fonte de colágeno biocompatível em camundongos

Abstracts

Publication Dates

History