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Surgical Endoscopy
Published in: Surgical Endoscopy 2/2014

01-02-2014

Postimplantation host tissue response and biodegradation of biologic versus polymer meshes implanted in an intraperitoneal position

Authors: G. Pascual, B. Pérez-Köhler, M. Rodríguez, S. Sotomayor, Juan M. Bellón

Published in: Surgical Endoscopy | Issue 2/2014

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Abstract

Background

This study compared the in vitro and in vivo behaviors at the peritoneal interface of a new polymer material (Bio-A) and of two biologic non-cross-linked materials (Tutomesh [Tuto] and Strattice [St]), all biodegradable.

Methods

Omentum mesothelial cells from rabbits were seeded onto the three prosthetic materials tested. At 1, 4, 8, 16, and 24 h after implantation, mesothelial cover was performed using a scanning electron microscope (SEM). In the in vivo study, 3 × 3 cm mesh fragments were placed on the parietal peritoneum of the same rabbits and fixed at the four corners with individual stitches. The implants were randomized such that six fragments of each material were implanted in nine animals (2 per animal). Adhesion formation was quantified by sequential laparoscopy and image analysis 3, 7, and 14 days after implantation. The animals were killed at 90 days, and the meshes were subjected to microscopy and immunohistochemistry.

Results

The in vitro mesothelial cover was significantly greater for St than for Bio-A at each time point. The percentage of cover for St was also higher than for Tuto 16 and 24 h after seeding and higher for Tuto than for Bio-A at all time points. Compared with the biologic meshes, significantly higher adhesion percentages were recorded for Bio-A. At 90 days after implantation, differences in absorption measured as percentage of reduction in mesh thickness were detected among all the meshes. The least absorbed was St. The neoperitoneum thickness was significantly greater for the biologic meshes than for the polymer mesh, although this variable also differed significantly between St and Tuto. Macrophage counts were higher for Bio-A than for the biologic meshes.

Conclusions

Greater mesothelial cover was observed in vitro for St. In vivo, adhesion formation and the macrophage response induced by Bio-A were greater than those elicited by the biologic materials. Bio-A and Tuto showed substantial biodegradation compared with St.
Literature
1.
Liang HCh, Chang Y, Hsu ChK, Lee MH, Sung HW (2004) Effects of crosskicking degree of an acellular biological tissue on its tissue regeneration pattern. Biomaterials 25:3541–3552PubMedCrossRef
2.
De Castro LE, Shurey S, Sibbons PD (2012) Evaluation of cross-linked and non-cross-linked biologic prostheses for abdominal hernia repair. Hernia 16:77–89CrossRef
3.
Cavallaro A, Lo Menzo E, Di Vita M, Zanghì A, Cavallaro V, Veroux PF, Cappellani A (2010) Use of biological meshes for abdominal wall reconstruction in highly contaminated fields. World J Gastroenterol 21:1928–1933CrossRef
4.
Franklin M, Russek K (2011) Use of porcine small intestine submucosa as a prosthetic material for laparoscopy hernia repair in infected and potentially contaminated fields: long-term follow-up assessment. Surg Endosc 25:1693–1694PubMedCrossRef
5.
Han JG, Wang ZJ, Gao ZG, Xu HM, Yang ZH, Jin ML (2010) Pelvic floor reconstruction using human acellular dermal matrix after cylindrical abdominoperineal resection. Dis Colon Rectum 53:219–223PubMedCrossRef
6.
Wille-Jorgensen P, Pilsgaarda B, Moller P (2009) Reconstruction of the pelvic floor with a biological mesh after abdominoperineal excision of rectal cancer. Int J Colorectal Dis 24:323–325PubMedCrossRef
7.
Ott V, Groebli Y, Schneider R (2005) Late intestinal fistula formation after incisional hernia using intraperitoneal mesh. Hernia 9:103–104PubMedCrossRef
8.
Orenstein SB, Qiao Y, Kaur M, Klueh U, Kreutzer DL, Novitsky YW (2010) Human monocyte activation by biologic and biodegradable meshes in vitro. Surg Endosc 24:805–811PubMedCrossRef
9.
López-Cano M, Armengol M, Quiles MT, Biel A, Velasco J, Huguet P, Mestre A, Dlgado LM, Gil FX, Arbos MA (2013) Preventive midline laparotomy closure with a new bioabsorbable mesh: an experimental study. J Surg Res 181:160–169PubMedCrossRef
10.
Pascual G, Sotomayor S, Rodriguez M, Pérez-Khöler B, Bellón JM (2012) Repair of abdominal wall defects with biodegradable laminar prostheses: polymeric or biological? PLoS One 7(12):e52628. doi:10.​137 PubMedCentralPubMedCrossRef
11.
Peeters E, Van Barneveld KW, Schreinemacher MH, De Hertogh G, Ozog Y, Bouvy N, Miserez M (2013) One-year outcome of biological and synthetic bioabsorbalbe meshes for augmentation of large abdominal wall defects in a rabbit model. J Surg Res 180:274–283PubMedCrossRef
12.
Efthimiou M, Symeonidis D, Koukoulis G, Tepetes K, Zacharoulis D, Tzovaras G (2011) Open inguinal hernia repair with the use of a polyglycolic acid-trimethylene carbonate absorbable mesh: a pilot study. Hernia 15:181–184PubMedCrossRef
13.
Burgess PL, Brockmeyer JR, Johnson EK (2011) Amyand hernia repaired with Bio-A: a case report and review. J Surg Educ 68:62–66PubMedCrossRef
14.
Negro P, Gossetti F, Dassatti MR, Andreuccetti J, D’Amore L (2012) Bioabsorbable Gore Bio-A plug and patch hernia repair in young adults. Hernia 16:121PubMedCrossRef
15.
Bellón JM, García-Honduvilla N, López R, Corrales C, Jurado F, Buján J (2003) In vitro mesothelialization of prosthetic materials designed for the repair of abdominal wall defects. J Mater Sci Mater Med 14:359–364PubMedCrossRef
16.
Bellón JM, Contreras LA, Buján J, Jurado F (1996) Effect of phosphatidylcholine on the process of peritoneal adhesion following implantation of a polypropylene mesh prosthesis. Biomaterials 17:1369–1372PubMedCrossRef
17.
Bellón JM, García-Carranza A, Jurado F, García-Honduvilla N, Carrera-San Martín A, Buján J (2001) Peritoneal regeneration after implant of a composite prosthesis in the abdominal wall. World J Surg 25:147–152PubMedCrossRef
18.
Baptista ML, Bonsack ME, Felmovicious I, Delaney JP (2000) Abdominal adhesions to prosthetic mesh evaluated by laparoscopy and electron microscopy. J Am Coll Surg 190:271–280PubMedCrossRef
19.
Felemovicius I, Bonsack ME, Hageman G, Delaney JP (2004) Prevention of adhesions to polypropylene mesh. J Am Coll Surg 198:53–58CrossRef
20.
Mattews BD, Pratt BL, Pollinger HS, Backus CL, Kercher KW, Sing RF, Henifford BT (2003) Assessment of adhesions formation to intraabdominal polypropylene mesh and polytetrafluoroethylene mesh. J Surg Res 114:126–132CrossRef
21.
Bellón JM, Contreras LA, Pascual G, Buján J (2000) Evaluation of the acute scarring response to the implant of different types of biomaterial in the abdominal wall. J Mat Sci Mat Med 11:25–29CrossRef
22.
Petter-Puchner AH, Fortelny RH, Walder N, Morales Conde S, Gruber-Blum S, Ohlinger W, Redl H (2010) Small intestine submucosa (SIS) implants in experimental IPOM repair. J Surg Res 161:264–271PubMedCrossRef
23.
Bellón JM, Rodríguez M, Gómez-Gil V, Sotomayor S, Buján J, Pascual G (2012) Postimplant intraperitoneal behavior of collagen-based meshes followed by laparoscopy. Surg Endosc 26:27–35PubMedCrossRef
24.
Klinge U, Schumpelick V, Klosterhalfen B (2001) Functional assessment and tissue response of short- and long-term absorbable surgical meshes. Biomaterials 22:1415–1424PubMedCrossRef
25.
Annor AH, Tang ME, Pui ChL, Ebersole GC, Frisella MM, Matthews BD, Deeken CR (2012) Effect of enzymatic degradation on the mechanical properties of biological scaffold materials. Surg Endosc 26:2767–2778PubMedCentralPubMedCrossRef
Metadata
Title
Postimplantation host tissue response and biodegradation of biologic versus polymer meshes implanted in an intraperitoneal position
Authors
G. Pascual
B. Pérez-Köhler
M. Rodríguez
S. Sotomayor
Juan M. Bellón
Publication date
01-02-2014
Publisher
Springer US
Published in
Surgical Endoscopy / Issue 2/2014
Print ISSN: 0930-2794
Electronic ISSN: 1432-2218
DOI
https://doi.org/10.1007/s00464-013-3205-z

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