Polylactide/polycaprolactone asymmetric membranes for guided bone regeneration

Domalik-Pyzik, Patrycja; Morawska-Chochół, A.; Chłopek, J.; Rajzer, I.; Wrona, Agata; Menaszek, E.; Ambroziak, Maciej

doi:10.1515/epoly-2016-0138

Cited by 25 publications

(17 citation statements)

References 34 publications

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“…This in vivo study showed no significant effect of pore size (10–200 µm) of PLA membrane on efficiency in treatment of diaphyseal defect in female rabbits ( ϕ 10 mm) within six months . Recent in vitro tests of the osteoblast‐like MG‐63 cell line performed on the porous PCL and PLA/PCL membranes (with pore diameters up to 30 μm) confirmed both biocompatibility and demonstrated that cells adhered well to the material surface of both types of membranes …”

Section: Resultsmentioning

confidence: 85%

“…11 Recent in vitro tests of the osteoblast-like MG-63 cell line performed on the porous PCL and PLA/PCL membranes (with pore diameters up to 30 lm) confirmed both biocompatibility and demonstrated that cells adhered well to the material surface of both types of membranes. 12 Thermal Properties Namely, PLA and PCL form a partially miscible blend, whereby an amount of amorphous PCL is dissolved in the PLA-rich phase leading to a depression of the glass and melting temperature shift to lower values. 16 Reportedly, PCL serves as a nucleating agent to promote PLA crystallization when blended with PLA.…”

Section: Structural Propertiesmentioning

confidence: 99%

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Supercritical CO₂ deposition and foaming process for fabrication of biopolyester–ZnO bone scaffolds

Ivanović

Rezwan

Kroll

2017

J of Applied Polymer Sci

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Subsequent supercritical CO2‐assisted deposition and foaming process followed by in situ synthesis was used to fabricate functional polylactide (PLA) and polylactide–poly(ɛ‐caprolactone) (PLA–PCL) bone scaffolds. Deposition of zinc bis(2‐thenoyltrifluoroacetonate) as a ZnO precursor onto biopolyester substrates (30 MPa; 110 °C) was followed by fast depressurization to create cellular structure. Contact time was optimized regarding the deposition yield (2 h), while PCL content in PLA was varied (1–10 wt %). Scaffolds impregnated with the precursor were treated with hydrazine alcoholic solution to obtain biopolyester–ZnO composites. Precursor synthesis and deposition onto the scaffolds was confirmed by Fourier‐transform infrared. Processed scaffolds had micron‐sized pores (d50 ∼ 20 μm). High open porosity (69–77%) and compressive strength values (2.8–8.3 MPa) corresponded to those reported for trabecular bone. PLA blending with PCL positively affected precursor deposition, crystallization rate, and compressive strength of the scaffolds. It also improved PLA surface roughness and wettability which are relevant for cell adhesion. ZnO improved compressive strength of the PLA scaffolds without significant effect on thermal stability. Analysis of structural, thermal, and mechanical properties of biopolyester–ZnO scaffolds testified a great potential of the obtained platforms as bone scaffolds. Proposed processing route is straightforward and ecofriendly, fast, easy to control, and suitable for processing of thermosensitive polymers. © 2017 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2018, 135, 45824.

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Section: Resultsmentioning

confidence: 85%

Section: Structural Propertiesmentioning

confidence: 99%

Supercritical CO₂ deposition and foaming process for fabrication of biopolyester–ZnO bone scaffolds

Ivanović

Rezwan

Kroll

2017

J of Applied Polymer Sci

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“…PCL, on the other hand, is semi-crystalline and elastic in nature; in addition to this, the processing temperature of PCL is also similar to the PLA and thus it is a perfect plasticizing agent for PLA not only in order to improve its elasticity but also to modulate its degradation rate (180)(181)(182). Pyzik and group (183) have prepared biodegradable and asymmetric membranes of PLA-PCL for guided bone regeneration. PLA matrix was prepared via electrospinning and PCL was fabricated using freeze drying method.…”

Section: Bps For Bone and Tissue Applicationsmentioning

confidence: 99%

A glimpse of biodegradable polymers and their biomedical applications

Shah

Vasava

2019

E-Polymers

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Over the past two decades, biodegradable polymers (BPs) have been widely used in biomedical applications such as drug carrier, gene delivery, tissue engineering, diagnosis, medical devices, and antibacterial/antifouling biomaterials. This can be attributed to numerous factors such as chemical, mechanical and physiochemical properties of BPs, their improved processibility, functionality and sensitivity towards stimuli. The present review intended to highlight main results of research on advances and improvements in terms of synthesis, physical properties, stimuli response, and/or applicability of biodegradable plastics (BPs) during last two decades, and its biomedical applications. Recent literature relevant to this study has been cited and their developing trends and challenges of BPs have also been discussed.

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“…Electrospinning is a simple, cost-effective and versatile method to prepare materials that mimic the native architecture of tissues. Electrospun scaffolds have attracted considerable interest in tissue engineering [ 21 ]. Moreover the possibility to modify the polymer solution used for electrospinning with bioactive substances or drugs make it an attractive method for nasal implant development.…”

Section: Introductionmentioning

confidence: 99%

Electrospun polycaprolactone membranes with Zn-doped bioglass for nasal tissues treatment

Rajzer

Dziadek

Kurowska

et al. 2019

J Mater Sci: Mater Med

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In this work, composite membranes were investigated as future components of a layered implant for the reconstruction of nasal septum. Incorporation of zinc ions into nasal implants could potentially provide antibacterial properties to decrease or eliminate bacterial infections and subsequent surgical complications. Two types of membranes were prepared using an electrospinning method: PCL with bioglass and PCL with bioglass doped with Zn. The aim of this work was to investigate the influence of bioglass addition on the morphology, fiber diameter and composition of the membranes. The apatite-forming ability was examined in Simulated Body Fluid (SBF). The cytotoxicity of the membranes, ALP activity and in vitro mineralization were evaluated in cell culture. The mineralization and ALP activity was higher for polycaprolactone membranes modified with Zn doped bioglass than compared to pure PCL membranes or control material. The results proved that the presence of Zn 2+ in the electrospun membranes = influence the osteogenic differentiation of cells.

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Polylactide/polycaprolactone asymmetric membranes for guided bone regeneration

Cited by 25 publications

References 34 publications

Supercritical CO₂ deposition and foaming process for fabrication of biopolyester–ZnO bone scaffolds

Supercritical CO₂ deposition and foaming process for fabrication of biopolyester–ZnO bone scaffolds

A glimpse of biodegradable polymers and their biomedical applications

Electrospun polycaprolactone membranes with Zn-doped bioglass for nasal tissues treatment

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Polylactide/polycaprolactone asymmetric membranes for guided bone regeneration

Cited by 25 publications

References 34 publications

Supercritical CO2 deposition and foaming process for fabrication of biopolyester–ZnO bone scaffolds

Supercritical CO2 deposition and foaming process for fabrication of biopolyester–ZnO bone scaffolds

A glimpse of biodegradable polymers and their biomedical applications

Electrospun polycaprolactone membranes with Zn-doped bioglass for nasal tissues treatment

Contact Info

Product

Resources

About

Supercritical CO₂ deposition and foaming process for fabrication of biopolyester–ZnO bone scaffolds

Supercritical CO₂ deposition and foaming process for fabrication of biopolyester–ZnO bone scaffolds