ABSTRACT
PURPOSE: This study was to evaluate the effects of bacterial cellulose (BC) membranes as a barrier membrane on guided bone regeneration (GBR) in comparison with those of the resorbable collagen membranes. MATERIALS AND METHODS: BC membranes were fabricated using biomimetic technology. Surface properties were analyzed, Mechanical properties were measured, in vitro cell proliferation test were performed with NIH3T3 cells and in vivo study were performed with rat calvarial defect and histomorphometric analysis was done. The Mann-Whitney U test and the Wilcoxon signed rank test was used (alpha<.05). RESULTS: BC membrane showed significantly higher mechanical properties such as wet tensile strength than collagen membrane and represented a three-dimensional multilayered structure cross-linked by nano-fibers with 60 % porosity. In vitro study, cell adhesion and proliferation were observed on BC membrane. However, morphology of the cells was found to be less differentiated, and the cell proliferation rate was lower than those of the cells on collagen membrane. In vivo study, the grafted BC membrane did not induce inflammatory response, and maintained adequate space for bone regeneration. An amount of new bone formation in defect region loaded with BC membrane was significantly similar to that of collagen membrane application. CONCLUSION: BC membrane has potential to be used as a barrier membrane, and efficacy of the membrane on GBR is comparable to that of collagen membrane.
Subject(s)
Animals , Rats , Biomimetics , Bone Regeneration , Cell Adhesion , Cell Proliferation , Cellulose , Collagen , Membranes , Osteogenesis , Porosity , Surface Properties , Tensile Strength , TransplantsABSTRACT
A fim de avaliar a resposta biológica da hidroxiapatita sintética (HAP-91) nos alvéolos de felinos domésticos, este biomaterial foi implantado após extração do terceiro pré-molar inferior direito em 12 gatos e mantida por meio de uma membrana de celulose bacteriana. No lado esquerdo, os alvéolos foram apenas recobertos com a membrana de celulose bacteriana, formando o grupo-controle. Observou-se, durante a avaliação clínica, que todos os animais voltaram a comer normalmente ração úmida, sem apresentarem sinais de dor ou desconforto após a recuperação anestésica. A cicatrização da ferida cirúrgica ocorreu de forma satisfatória, sendo que a membrana de celulose bacteriana evitou a saída precoce da hidroxiapatita. Radiograficamente, aos 50 dias, todos os animais apresentaram radiopacidade óssea homogênea em ambos os lados. À análise histomorfométrica, observou-se adiantamento do processo de reparo do osso alveolar nos oito primeiros dias do grupo-tratado quando comparado ao grupo-controle, bem como atraso aos 30 dias, porém, aos 50 dias, ambos os grupos apresentavam porcentagem de tecido ósseo semelhante e morfologicamente normal. Os resultados sugerem que a hidroxiapatita é biocompatível, integra-se ao tecido ósseo alveolar e pode ser utilizada em felinos.
The biocompatibility of a material depends on its characteristics, as well as the species and the environment recipient. In order to evaluate the biological response of the synthetic hydroxyapatite (HAP-91) in feline dental alveoli, it was implanted in the right inferior third premolar after extraction in 12 cats and maintained through a bacterial cellulose membrane. On the left side the alveoli was covered with a bacterial cellulose membrane (control group). During clinical evaluations it was observed that the animals started to eat after the anesthetic recovery time, without clinical signs of pain. There was a satisfactory cicatrization of the surgical wound and the bacterial cellulose membrane aided in repairing the gum, avoiding the loss of the hydroxyapatite. Radiographs taken 50 days post surgery presented homogeneous bone radiopacity on both sides. The histological and histomorfometrical analysis showed a positive progress of the alveolar repair in the first 8 days in the treated group when compared to the control group and a delay at 30 days, however at 50 days both presented a similar and morphologically normal percentage of bone tissue. These findings suggest that HAP-91 is biocompatible and integrates into the feline alveolar bone.
Subject(s)
Animals , Cats , Durapatite/analysis , Durapatite , Cats/metabolism , Cats/microbiology , Tooth Socket , Cellulose/analysisABSTRACT
A Regeneração Tecidual Guiada (RTG) consiste numa modalidade de tratamento regenerativo que requer a colocação de uma barreira física sobre o defeito ósseo, de modo que a proliferação de tecidos moles adjacentes para dentro da área protegida seja evitada. Assim, a regeneração óssea guiada permite que células com potencial osteogênico das margens ósseas existentes invadam o espaço criado e produzam osso. As barreiras físicas devem ser biocompatíveis, permitir a oclusão celular, manutenção do espaço, integração tecidual e facilidade de uso. Podem ser oclusivas ou permeáveis, absorvíveis ou não absorvíveis. Dentre os vários tipos de barreiras físicas existentes no mercado, a membrana biossintética a base de celulose vem se destacando, pois, além de possuir as características necessárias para a RTG, trata-se de um produto nacional desenvolvido a baixos custos.
Guided Tissue Regeneration (GTR) is a regenerative treatment modality that requires the placement of aphysical barrier over a bone defect in such a way that the proliferation of the surrounding soft tissuesinto the barrier-protected area is prevented. Thereby in the guided osseous regeneration allowing boneformingcells from the existent bone edges to invade the space and produce bone. The physical barriersshould be biocompatible, allow cellular occlusion, maintain adequate space, tissue integration and facilityin the application. They can be occlusive or permeable, absorbable or non-absorbable. Among varioustypes of physical barriers in the market, the cellulose biosynthetic membrane is emphasizing by thenecessary characteristics for GTR and to be a national product developed in low cost.
Subject(s)
Cartilage, Articular , Guided Tissue RegenerationABSTRACT
Styela clava, called non-native tunicate or sea squirt, is habitat which include bays and harbors in Korea and several sites in the sea faced world. We fabricate cellulose membrane nerve conduit (CMNC) from this native sea squirt skin, and evaluate the capacity of promoting peripheral nerve regeneration in the rat sciatic nerve defect model. After processing the pure cellulose membrane from the sea squirt skin as we already published before, CMNC was designed as a non-tubular sheet with 14 mm length and 4 mm width. Total eleven male Spraque-Dawley rats (12 weeks, weighing 250 to 300g) were divided into sham group (n=2), silicone tube grafted control group (n=3) and experimental group (n=6). Each CMNC grafted nerve was evaluated after 4, 8 and 12 weeks in the experimental group, and after 12 weeks, sciatic function was evaluated with sciatic function index (SFI) and gait analysis, and histomorphology of nerve conduit and the innervated tissues of sciatic nerve were all examined using image analyzer and electromicroscopic methods in the all groups. The regenerated axon and nerve sheath were found only in the inner surface of the CMNC after 4 weeks and became more thicker after 8 and 12 weeks. In the TEM study, CMNC grafted group showed more abundant organized myelinated nerve fibers with thickened extracellular matrix than silicone conduit grafted group after 12 weeks. The sciatic function index (SFI) and ankle stance angle (ASA) in the functional evaluation were -47.2+/-3.9, 35.5.+/-4.9.in CMNC grafted group (n=2) and -80.4+/-7.4, 29.2.+/-5.3.in silicone conduit grafted group (n=3), respectively. And the myelinated axon was 41.59% in CMNC group and 9.51% in silicone conduit group to the sham group. The development of a bioactive CMNC to replace autogenous nerve grafts offers a potential and available approach to improved peripheral nerve regeneration. As we already published before, small peptide fragment derived from the basement membrane matrix proteins of squirt skin, which is a kind of anchoring protein composed of glycocalyx, induced the effective axonal regeneration with rapid growth of Schwann cells beneath the inner surface of CMNC. So the possibilities of clinical application as a peripheral nerve regeneration will be able to be suggested.
Subject(s)
Animals , Humans , Male , Rats , Ankle , Axons , Basement Membrane , Bays , Cellulose , Ecosystem , Extracellular Matrix , Gait , Glycocalyx , Korea , Membranes , Myelin Sheath , Nerve Fibers, Myelinated , Peripheral Nerves , Regeneration , Schwann Cells , Sciatic Nerve , Silicones , Skin , Transplants , UrochordataABSTRACT
OBJECTIVES: To develop a bioactive membrane for guided bone regeneration (GBR), the biocompatibility and bone regenerating capacity of the cellulose membrane obtained from the Ascidians squirt skin were evaluated. MATARIALS AND METHODS: After processing the pure cellulose membrane from the squirt skin, the morphological study, amino acid analysis and the immunoreactivity of the cellulose membrane were tested. Total eighteen male Spraque-Dawley rats (12 weeks, weighing 250 to 300g) were divided into two control (n=8) and another two experimental groups (n=10). In the first experimental group (n=5), the cellulose membrane was applicated to the 8.0 mm sized calvarial bone defect and the same sized defect was left without cellulose membrane in the first control group (n=4). In the another experimental group (n=5), the cellulose membrane was applicated to the same sized calvarial bone defect after femoral bone graft and the same sized defect with bone graft was left without cellulose membrane in the another control group (n=4). Each group was sacrificed after 6 weeks, the histological study with HandE and Masson trichrome stain was done, and immunohistochemical stainings of angiogenin and VEGF were also carried out. RESULTS: The squirt skin cellulose showed the bio-inductive effect on the bone and mesenchymal tissues in the periosteum of rat calvarial bone. This phenomenon was found only in the inner surface of the cellulose membrane after 6 weeks contrast to the outer surface. Bone defect covered with the bioactive cellulose membrane showed significantly greater bone formation compared with control groups. Mesenchymal cells beneath the inner surface of the bioactive cellulose membrane were positive to the angiogenin and VEGF antibodies. CONCLUSION: We suppose that there still remains extremely little amount of peptide fragment derived from the basement membrane matrix proteins of squirt skin, which is a kind of anchoring protein composed of glycocalyx. This composition could prevent the adverse immunological hypersensitivity and also induce bioactive properties of cellulose membrane. These properties induced the effective angiogenesis with rapid osteogenesis beneath the inner surface of cellulose membrane, and so the possibilities of clinical application in dental field as a GBR material will be able to be suggested.