复层猪小肠黏膜下层可吸收膜的降解性能

doi:10.19723/j.issn.1671-167X.2020.03.025

Abstract

Abstract:

Objective: To study the biodegradation properties of multi-laminated small intestinal submucosa (mSIS) through in vitro and in vivo experiments, comparing with Bio-Gide, the most widely used collagen membrane in guided bone regeneration (GBR) technique, for the purpose of providing basis to investigate whether mSIS meets the requirements of GBR in dental clinics.Methods: The degradation properties were evaluated in vitro and in vivo. In vitro degradation was performed using prepared collagenase solution. Morphology of mSIS and Bio-Gide in degradation solution were observed and the degradation rate was calculated at different time points. In in vivo experiments, nine New Zealand rabbits were used for subcutaneous implantation and were divided into three groups according to observation intervals. Six unconnected subcutaneous pouches were made on the back of each animal and were embedded with mSIS and Bio-Gide respectively. At the end of weeks 4, 8, and 12 after operation, gross observation and HE staining were used to evaluate the degree of degradation and histocompatibility.Results: In vitro degradation experiments showed that mSIS membrane was completely degraded at the end of 12 days, while Bio-Gide was degraded at the end of 7 days. Besides, mSIS maintained its shape for longer time in the degradation solution than Bio-Gide, indicating that mSIS possessed longer degradation time, and had better ability to maintain space than Bio-Gide. In vivo biodegradation indicated that after 4 weeks of implantation, mSIS remained intact. Microscopic observation showed that collagen fibers were continuous with a few inflammatory cells that infiltrated around the membrane. Bio-Gide was basically intact and partially adhered with the surrounding tissues. HE staining showed that collagen fibers were partly fused with surrounding tissues with a small amount of inflammatory cells that infiltrated as well. Eight weeks after operation, mSIS was still intact, and was partly integrated with connective tissues, whereas Bio-Gide membrane was mostly broken and only a few residual fibers could be found under microscope. Only a small amount of mSIS debris could be observed 12 weeks after surgery, and Bio-Gide could hardly be found by naked eye and microscopic observation at the same time.Conclusion: In vitro degradation time of mSIS is longer than that of Bio-Gide, and the space-maintenance ability of mSIS is better. The in vivo biodegradation time of subcutaneous implantation of mSIS is about 12 weeks and Bio-Gide is about 8 weeks, both of which possess good biocompatibility.

Key words: Small intestinal submucosa, Biocompatible materials, Guided bone regeneration

CLC Number:

R318.021

Wei-yi WU,Bo-wen LI,Yu-hua LIU,Xin-zhi WANG. Biodegradation properties of multi-laminated small intestinal submucosa[J].Journal of Peking University (Health Sciences), 2020, 52(3): 564-569.

Figures/Tables 5

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Table 1

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References 34

[1]	Lopez-Martinez F, Gomez Moreno G, Olivares-Ponce P, et al. Implants failures related to endodontic treatment. An observational retrospective study[J]. Clin Oral Implants Res, 2015,26(9):992-995.
[2]	Palachur D, Prabhakara Rao KV, Murthy KR, et al. A comparative evaluation of bovine-derived xenograft (Bio-Oss collagen) and type Ⅰ collagen membrane (Bio-Gide) with bovine-derived xenograft (Bio-Oss collagen) and fibrin fibronectin sealing system (tisseel) in the treatment of intrabony defects: A clinico-radiographic study[J]. J Indian Soc Periodontol, 2014,18(3):336-343.
[3]	Amoian B, Moudi E, Majidi MS, et al. A histologic, histomorphometric, and radiographic comparison between two complexes of cenoboen/cenomembrane and bio-oss/Bio-Gide in lateral ridge augmentation: A clinical trial[J]. Dent Res J (Isfahan), 2016,13(5):446-453.
[4]	Oortgiesen DA, Plachokova AS, Geenen C, et al. Alkaline phosphatase immobilization onto Bio-Gide^® and Bio-Oss^® for periodontal and bone regeneration [J]. J Clin Periodontol, 2012,39(6):546-555.
[5]	詹雅琳, 胡文杰, 甄敏, 等. 去蛋白牛骨基质与可吸收胶原膜的磨牙拔牙位点保存效果影像学评价[J]. 北京大学学报(医学版), 2015,47(1):19-26.
[6]	Strietzel FP, Khongkhunthian P, Khattiya R, et al. Healing pattern of bone defects covered by different membrane types: a histologic study in the porcine mandible[J]. J Biomed Mater Res B Appl Biomater, 2006,78(1):35-46.
[7]	Owens KW, Yukna RA. Collagen membrane resorption in dogs: A comparative study[J]. Implant Dent, 2001,10(1):49-58. doi: 10.1097/00008505-200101000-00016 pmid: 11307648
[8]	吴唯伊, 李博文, 刘玉华, 等. 猪小肠黏膜下层可吸收膜性能及修复骨缺损的效果评价[C]. 中华口腔医学会口腔修复学专业委员会.第十一次全国口腔修复学学术会议论文汇编.南京: 2017.
[9]	Olaechea A, Doza-Azpur GM, Valdivia E, et al. Biodegradation of three different collagen membranes: A histological study[J]. Journal of Osseointegration, 2016,8(2):15-19.
[10]	Pilipchuk SP, Plonka AB, Monje A, et al. Tissue engineering for bone regeneration and osseointegration in the oral cavity[J]. Dent Mater, 2015,31(4):317-338. pmid: 25701146
[11]	Mcallister BS, Haghighat K. Bone augmentation techniques[J]. J Periodontol, 2007,78(3):377-396. pmid: 17335361
[12]	Bresaola MD, Matsumoto MA, Zahoui A, et al. Influence of rapid- and slow-rate resorption collagen membrane in maxillary sinus augmentation[J]. Clin Oral Implants Res, 2017,28(3):320-326. doi: 10.1111/clr.12801 pmid: 26916561
[13]	Moses O, Vitrial D, Aboodi G, et al. Biodegradation of three different collagen membranes in the rat calvarium: A comparative study[J]. J Periodontol, 2008,79(5):905-911. pmid: 18454670
[14]	Sheikh Z, Hamdan N, Ikeda Y, et al. Natural graft tissues and synthetic biomaterials for periodontal and alveolar bone reconstructive applications: A review[J]. Biomater Res, 2017,21:9. doi: 10.1186/s40824-017-0095-5 pmid: 28593053
[15]	Bozkurt A, Apel C, Sellhaus B, et al. Differences in degradation behavior of two non-cross-linked collagen barrier membranes: An in vitro and in vivo study[J]. Clin Oral Implants Res, 2014,25(12):1403-1411.
[16]	Bozkurt A, Lassner F, O’dey D, et al. The role of microstructured and interconnected pore channels in a collagen-based nerve guide on axonal regeneration in peripheral nerves[J]. Biomaterials, 2012,33(5):1363-1375. doi: 10.1016/j.biomaterials.2011.10.069 pmid: 22082619
[17]	Bozkurt A, Deumens R, Beckmann C, et al. In vitro cell alignment obtained with a schwann cell enriched microstructured nerve guide with longitudinal guidance channels[J]. Biomaterials, 2009,30(2):169-179.
[18]	Verissimo DM, Leitao RF, Ribeiro RA, et al. Polyanionic collagen membranes for guided tissue regeneration: Effect of progressive glutaraldehyde cross-linking on biocompatibility and degradation[J]. Acta Biomater, 2010,6(10):4011-4018. pmid: 20433958
[19]	Glynn JJ, Polsin EG, Hinds MT. Crosslinking decreases the hemocompatibility of decellularized, porcine small intestinal submucosa[J]. Acta Biomater, 2015,14:96-103.
[20]	Moses O, Pitaru S, Artzi Z, et al. Healing of dehiscence-type defects in implants placed together with different barrier membranes: A comparative clinical study[J]. Clin Oral Implants Res, 2005,16(2):210-219.
[21]	Valentin JE, Stewart-Akers AM, Gilbert TW, et al. Macrophage participation in the degradation and remodeling of extracellular matrix scaffolds[J]. Tissue Eng Part A, 2009,15(7):1687-1694. pmid: 19125644
[22]	Valentin JE, Badylak JS, Mccabe GP, et al. Extracellular matrix bioscaffolds for orthopaedic applications. A comparative histologic study[J]. J Bone Joint Surg Am, 2006,88(12):2673-2686. pmid: 17142418
[23]	Bai H, Wang D, Delattre B, et al. Biomimetic gradient scaffold from ice-templating for self-seeding of cells with capillary effect[J]. Acta Biomater, 2015,20:113-119. doi: 10.1016/j.actbio.2015.04.007 pmid: 25871536
[24]	Badylak SF, Gilbert TW. Immune response to biologic scaffold materials[J]. Semin Immunol, 2008,20(2):109-116. pmid: 18083531
[25]	Yan HJ, Casalini T, Hulsart-Billstrom G, et al. Synthetic design of growth factor sequestering extracellular matrix mimetic hydrogel for promoting in vivo bone formation[J]. Biomaterials, 2018,161:190-202. doi: 10.1016/j.biomaterials.2018.01.041 pmid: 29421555
[26]	Rothamel D, Benner M, Fienitz T, et al. Biodegradation pattern and tissue integration of native and cross-linked porcine collagen soft tissue augmentation matrices: An experimental study in the rat[J]. Head Face Med, 2014(10):10.
[27]	Siar CH, Toh CG, Romanos G, et al. Subcutaneous reactions and degradation characteristics of collagenous and noncollagenous membranes in a macaque model[J]. Clin Oral Implants Res, 2011,22(1):113-120. doi: 10.1111/j.1600-0501.2010.01970.x pmid: 20678135
[28]	Olde Damink LH, Dijkstra PJ, Van Luyn MJ, et al. In vitro degradation of dermal sheep collagen cross-linked using a water-soluble carbodiimide[J]. Biomaterials, 1996,17(7):679-684. doi: 10.1016/0142-9612(96)86737-8 pmid: 8672629
[29]	Li J, Ren N, Qiu J, et al. Carbodiimide crosslinked collagen from porcine dermal matrix for high-strength tissue engineering scaffold[J]. Int J Biol Macromol, 2013,61:69-74. doi: 10.1016/j.ijbiomac.2013.06.038 pmid: 23820178
[30]	闫建伟. 牙种植引导骨再生心包胶原膜的制备及理化性能研究[D]. 济南: 山东大学, 2017.
[31]	Kozlovsky A, Aboodi G, Moses O, et al. Bio-degradation of a resorbable collagen membrane (Bio-Gide) applied in a double-layer technique in rats[J]. Clin Oral Implants Res, 2009,20(10):1116-1123. doi: 10.1111/j.1600-0501.2009.01740.x pmid: 19719734
[32]	Gilbert TW, Stewart-Akers AM, Simmons-Byrd A, et al. Degradation and remodeling of small intestinal submucosa in canine achilles tendon repair[J]. J Bone Joint Surg Am, 2007,89(3):621-630. doi: 10.2106/JBJS.E.00742 pmid: 17332112
[33]	Record RD, Hillegonds D, Simmons C, et al. In vivo degradation of c-14-labeled small intestinal submucosa (sis) when used for urinary bladder repair[J]. Biomaterials, 2001,22(19):2653-2659. doi: 10.1016/S0142-9612(01)00007-2
[34]	Mewaldt R, Shi L, Carson D. Enzymatic degradation study of single layer and multi-layer small intestine submucosa (sis) matrices[J]. Wound Repair Regen, 2011,19(2):A39.

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Group	0 d	1 d	2 d	3 d	4 d	5 d	7 d	10 d	12 d
mSIS	0.027±0.008	0.025± 0.008	0.024±0.006	0.023±0.004	0.022±0.004	0.021±0.003	0.016±0.004	0.005±0.003	0
Bio-Gide	0.022±0.007	0.017±0.003	0.016±0.003	0.013±0.002	0.007±0.002	0.003±0.002	0	0	0
P	0.437	0.238	0.104	0.023	0.004	<0.001	0.001	0.048

Biodegradation properties of multi-laminated small intestinal submucosa

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