Polydioxanone-Based Membranes for Bone Regeneration.

Sybele Saska,Marta Dyszkiewicz Konwińska,Eduardo Finger,Livia Pilatti,Samy Tunchel,Alberto Blay,Jamil Awad Shibli,Edvaldo Santos De Sousa Silva,Bartosz Kempisty,Diana Câmara,Nelson Lizier,Magda Aline Nagasawa

doi:10.3390/polym13111685

Abstract

Resorbable synthetic and natural polymer-based membranes have been extensively studied for guided tissue regeneration. Alloplastic biomaterials are often used for tissue regeneration due to their lower immunoreactivity when compared with allogeneic and xenogeneic materials. Plenum® Guide is a synthetic membrane material based on polydioxanone (PDO), whose surface morphology closely mimics the extracellular matrix. In this study, Plenum® Guide was compared with collagen membranes as a barrier material for bone-tissue regeneration in terms of acute and subchronic systemic toxicity. Moreover, characterizations such as morphology, thermal analysis (Tm = 107.35 °C and crystallinity degree = 52.86 ± 2.97 %, final product), swelling (thickness: 0.25 mm ≅ 436% and 0.5 mm ≅ 425% within 24 h), and mechanical tests (E = 30.1 ± 6.25 MPa; σ = 3.92 ± 0.28 MPa; ε = 287.96 ± 34.68%, final product) were performed. The in vivo results revealed that the PDO membranes induced a slightly higher quantity of newly formed bone tissue than the control group (score: treated group = 15, control group = 13) without detectable systemic toxicity (clinical signs and evaluation of the membranes after necropsy did not result in differences between groups, i.e., non-reaction -> tissue-reaction index = 1.3), showing that these synthetic membranes have the essential characteristics for an effective tissue regeneration. Human adipose-derived stem cells (hASCs) were seeded on PDO membranes; results demonstrated efficient cell migration, adhesion, spread, and proliferation, such that there was a slightly better hASC osteogenic differentiation on PDO than on collagen membranes. Hence, Plenum® Guide membranes are a safe and efficient alternative for resorbable membranes for tissue regeneration.

Highlights

Guided tissue regeneration/guided bone regeneration (GTR/GBR) includes the stimulation of bone formation in bone defects using different types of membranes, associated or not with bone substitutes or grafts [1,2]
The corresponding scanning electron microscopy (SEM) and fluorescence images suggest a morphological structure with randomly oriented fibers at themicron level, similar to the extracellular matrix (ECM)
The structural morphology and superficial topography of the PDO membrane examined in this study are similar to those of the ECM (Figure 1), in which the physicochemical and morphological properties facilitate the diffusion of biological fluids and cell adhesion [4]

Summary

Introduction

Guided tissue regeneration/guided bone regeneration (GTR/GBR) includes the stimulation of bone formation in bone defects using different types of membranes (resorbable and non-resorbable), associated or not with bone substitutes or grafts [1,2]. This will further provide mechanical support and cellular exclusion at the affected location, where the surrounding healthy tissue will migrate and promote osteogenesis and osteoconduction [1,3]. Xenogeneic collagen matrix membranes indicate good tissue regeneration potential since they induce vascularization, cell migration, adhesion, and connective tissue formation [9,10]. Several advantages posed by synthetic polymers when compared to natural polymers lie in their reduced immunogenicity and disease transmission potential [14,15]

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Results

Discussion

Conclusion