Preparation and Properties of a Novel Biodegradable Polyester Elastomer with Functional Groups

A novel biodegradable poly(sebacate-glycerol-citrate) (PGSC) elastomer with functional groups was prepared in this study. First, moldable mixtures were obtained by mixing citric acid with the poly(glycerol-sebacate) (PGS) pre-polymers synthesized in our lab. The PGSC elastomers were obtained from moldable mixtures that were thermally cured in the moulds. Then, the structures, compositions and properties of the elastomers were studied by Fourier transformation infrared spectroscopy (FT-IR), swelling test, differential scanning calorimeter (DSC), tensile test, water contact angle measurement, water absorption experiments and a in vitro degradation test. It showed that the hydroxyl groups remained in the elastomers which would endow the polymer chains with functionality such as good surface modification. By controlling the thermal curing time, the compositions of the PGSC elastomers were adjusted for different mechanical and biodegradable properties. Therefore, PGSC elastomers might be used as anti-conglutination films in surgery, guided tissue regeneration membranes and drug-delivery matrices.     

Synthesis and properties of biodegradable poly(ester-urethane)s based on poly(ε-caprolactone) and aliphatic diurethane diisocyanate for long-term implant application: effect of uniform-size hard segment content

Abstract

In this article, a series of medical poly(ester-urethane)s (PEUs) with varying uniform-size hard segment content were prepared via one-step chain extension of poly(ε-caprolactone)s with aliphatic urethane diisocyanate, and the corresponding films were obtained by solvent evaporation technique. The chemical structures of polymers were confirmed by ¹H NMR, FT-IR and GPC. The effect of uniform-size hard segment content on the physicochemical properties of PEU films, including thermal properties, mechanical properties, crystallization behavior, water-swelling behavior and in vitro degradability, was extensively researched. The PEU films exhibiting similar thermal transition and thermal stability indicated that the uniform-size hard segment content had little effect on the thermal properties. Two obvious glass transition temperatures observed in DSC curves manifested a microphase separation structure, which endowed the PEU films excellent mechanical properties with ultimate stress of 34.6–51.2?MPa and strain at break of 898–1485%. And with the increase of uniform-size hard segment content, the initial modulus and ultimate stress increased, while the strain at break decreased. Due to the compact physical-linking network structure formed by the denser hydrogen bonds, the PEU films exhibited low water-swellability of less than 1.5?wt% and low degradation rate in vitro. The weight loss of the PEU films in degradation test was less than 1?wt% at the first four months and the time of films becoming fragments was more than 15?months. Cytotoxicity test of film extracts was conducted with L929 mouse fibroblasts, and the relative growth rate approached or exceeded 75%, indicating an acceptable cytocompatibility. For the excellent mechanical properties, slow biodegradability, non-toxic degradation products and adequate cytocompatibility, the PEUs containing uniform-size hard segments possess a high potential to be applied as long-term implant biomaterials.     

Characterization of a resorbable poly(ester urethane) with biodegradable hard segments

The rapid growth of regenerative medicine and drug delivery fields has generated a strong need for improved polymeric materials that degrade at a controlled rate into safe, non-cytotoxic by-products. Polyurethane thermoplastic elastomers offer several advantages over other polymeric materials including tunable mechanical properties, excellent fatigue strength, and versatile processing. The variable segmental chemistry in developing resorbable polyurethanes also enables fine control over the degradation profile as well as the mechanical properties. Linear aliphatic isocyanates are most commonly used in biodegradable polyurethane formulations; however, these aliphatic polyurethanes do not match the mechanical properties of their aromatic counterparts. In this study, a novel poly(ester urethane) (PEsU) synthesized with biodegradable aromatic isocyanates based on glycolic acid was characterized for potential use as a new resorbable material in medical devices. Infrared spectral analysis confirmed the aromatic and phase-separated nature of the PEsU. Uniaxial tensile testing displayed stress–strain behavior typical of a semi-crystalline polymer above its T_g, in agreement with calorimetric findings. PEsU outperformed aliphatic PCL-based polyurethanes likely due to the enhanced cohesion of the aromatic hard domains. Accelerated degradation of the PEsU using 0.1?M sodium hydroxide resulted in hydrolysis of the polyester soft segment on the surface, reduced molecular weight, surface cracking, and a 30% mass loss after four weeks. Calorimetric studies indicated a disruption of the soft segment crystallinity after incubation which corresponded with a drop in initial modulus of the PEsU. Finally, cytocompatibility testing with 3T3 mouse fibroblasts exhibited cell viability on PEsU films comparable to a commercial poly(ether urethane urea) after 24?h followed by 85% cell viability at 72?h. Overall, this new resorbable polyurethane shows strong potential for use in wide range of biomedical applications.     

Robust,Transparent, Thermally Healable Copolyacrylate Elastomer: The Effect of β‐Hydroxyethyl Acrylate on its Properties

The contradiction between mechanical properties, transparency, and healing effects for polyacrylate elastomers is not solved yet. The copolyacrylate elastomers are prepared based on the bulk copolymerization with methyl methacrylate (MMA) and butyl acrylate (BA), incorporating the β‐hydroxyethyl acrylate (HEA) monomer. Compared with PMMA‐co‐PBA, with the incorporation of HEA, the copolymer elastomer decreases in tensile strength, while increasing in healing efficiency and visible‐light transmittance. Therefore, the high transparency and healing efficiency of the copolyacrylate elastomer are achieved under the condition of ensuring robust mechanical properties.     

Tissue-compatible multiblock copolymers for medical applications,controllable in degradation rate and mechanical properties

A class of degradable, phase-segregated multiblock copolymers is presented. The new copoly(ester-urethane)s, termed DegraPol^TM/btgc, consist of crystallizable poly[(3-R -hydroxybutyrate)-co-(3-R-hydroxyvalerate)]-segments and amorphous segments from ε-caprolactone, diglycolide and ethylene glycol. As junction unit an aliphatic diisocyanate, TMDI, is applied. The copoly(ester-urethane)s are thermoplastic elastomers (T_m = 120–136°C) and are processable without degradation. For medical applications, materials are needed in which the degradation rate and the mechanical properties are independently adjustable to the medical needs. The mechanical properties of DegraPol^TM/btgc, e.g., elasticity and toughness, can be controlled by the weight fraction of crystallizable segment; the elastic moduli of DegraPol/btcg are adjustable between 50 MPa and 500 MPa and were only little influenced by the chemical structure and the composition of the soft segment. By insertion of ‘weak links’ in the form of easily hydrolyzable glycolyl-glycolate ester bonds into the amorphous segments, we attempted to synthesize degradable polymers in which the hydrolytic degradation rate can be controlled by the amount and the sequence distribution of these bonds. We report on the synthesis and on the thermal and mechanical properties of such polymers.     

The preparation of PLL–GRGDS modified PTSG copolymer scaffolds and their effects on manufacturing artificial salivary gland

We prepared two-dimentional (2D) and three-dimentional (3D) scaffolds with biodegradable poly(butylene terephthalate)-co-poly(butylene succinate)-b-poly(ethylene glycol) (i.e. PTSG), mainly for the purpose of investigating its cytocompatibility and mechanical property as artificial salivary gland material. The surface of 2D scaffold (i.e. PTSG film) was modified by O₂ plasma treatment and the following coating of Gly–Arg–Gly–Asp–Ser (GRGDS) decorated poly(L-lysine) (i.e. PLL–GRGDS). The obtained film was named PLL–GRGDS/PTSG (O). Its surface properties were characterized using contact angles, surface energies, X-ray photoelectron spectroscopy and Fourier transform infrared; and cytocompatibility tests in vitro including morphology, attachment and proliferation of human salivary gland (HSG) epithelial cells were further performed on PTSG films. Meanwhile, 3D scaffold with the shape of porous tube was constructed using hydrogel-rapid prototyping and the performance of 3D scaffold including mechanical property, pore structure, degradation and water uptake was also evaluated. Results revealed that PLL–GRGDS/PTSG (O) possessed the high surface free energy (63.89?mJ/m²) and could immobilize a great amount of PLL–GRGDS, which attributed to the formation of some polar oxygen-containing groups such as carboxyl and carbonyl ones in the process of O₂ plasma treatment. Cell tests in vitro suggested the efficiency of surface modification in enhancing the cytocompatibility of PTSG. Furthermore, the manufacturing scaffold was proved to possess excellent pore structures (porosity 88.9%, connectivity 97.5% and average pore size 35.4?μm) and good mechanical properties (E-modulus 88.4?±?4.1?kPa, yield stress 45.7?±?2.3?kPa, yield strain 56?±?2%, fracture stress 52.2?±?3.5?kPa and fracture strain 63?±?3%). After four weeks hydrolysis reaction, the degradation of the scaffold reached 8% and equilibrium water uptake declined from 51 to 45%. The decline of water uptake was probably caused by the decrease of the hydrophilic units in PTSG copolymer during degradation. These results satisfied the demands for constructing the artificial salivary gland scaffold.     

Preparation and properties of biomedical segmented polyurethanes based on poly(ether ester) and uniform-size diurethane diisocyanates

This study describes the preparation and properties of a novel aliphatic cost-effective segmented polyurethanes (SPUs) based on poly(ether ester) (poly-(ε-caprolactone-co-l-lactide)-poly(ethylene glycol)-poly-(ε-caprolactone-co-l-lactide), PECLA) and uniform-size diurethane diisocyanates (HDI-BDO-HDI). PECLA was synthesized via bulk ring-opening polymerization with poly(ethylene glycol) (PEG) as an initiator and ε-caprolactone, l-lactide as monomers. By chain extension of PECLA diol with HDI-BDO-HDI, three SPUs with different hydrophilic segments content and hard segments content were obtained. The chemical structures of the chain extender, PECLA and SPUs were confirmed by ¹H NMR, ¹³C NMR, FT-IR, HR-TOF-MS and GPC. The influences of PEG content and uniform-size hard segments on in vitro degradability and mechanical properties of SPU films were researched. Similar thermostability observed in TGA curves of SPU films indicated that the hard segments and PEG content had little influence on the thermostability. The formation of microsphase-separated morphologies, which were demonstrated by the results of DSC and XRD, and physical-linking (H-bonds) network structures led to better mechanical properties of SPU films (ultimate stress: 23.1–17.9 MPa; elongation at break: 840–1130%). The results of water absorption and water contact angle showed that the bulk and surface hydrophilicity were closely related with the hydrophilic PEG content in SPU backbone. And the water absorption being less than 10 wt% indicated that the SPU films had low swelling property. In vitro hydrolytic degradation studies showed that the time of the SPU films becoming fragments was 34–19 days and the degradation rate increased with the increasing content of hydrophilic segments in SPUs, indicating that the degradation rate of SPU films could be controlled by adjusting PEG content. Cytotoxicity test of film extracts were conducted using L929 cells, and the relative growth rate exceeded 90% after incubation for 24, 48 and 72 h, showing excellent cytocompatibility. The acceptable mechanical properties, controllable biodegradability and excellent cytocompatibility of the polyurethanes can make them good candidates for further biomedical applications.     

Mechanical properties evolution of a PLGA-PLCL composite scaffold for ligament tissue engineering under static and cyclic traction-torsion in vitro culture conditions

This study aims to investigate the in vitro degradation of a poly(L-lactic-co-glycolic acid)-poly(L-lactic-co-?-caprolactone) (PLGA-PLCL) composite scaffold’s mechanical properties under static culture condition and 2?h period per day of traction-torsion cyclic culture conditions of simultaneous 10% uniaxial strain and 90° of torsion cycles at 0.33?Hz. Scaffolds were cultured in static conditions, during 28?days, with or without cell seeded or under dynamic conditions during 14?days in a bioreactor. Scaffolds’ biocompatibility and proliferation were investigated with Alamar Blue tests and cell nuclei staining. Scaffolds’ mechanical properties were tested during degradation by uniaxial traction test. The PLGA-PLCL composite scaffold showed a good cytocompatibility and a high degree of colonization in static conditions. Mechanical tests showed a competition between two process of degradation which have been associated to hydrolytic and enzymatic degradation for the reinforce yarn in poly(L-lactic-co-glycolic acid) (PLGA). The enzymatic degradation led to a decrease effect on mechanical properties of cell-seeded scaffolds during the 21st days, but the hydrolytic degradation was preponderant at day 28. In conclusion, the structure of this scaffold is adapted to culture in terms of biocompatibility and cell orientation (microfiber) but must be improved by delaying the degradation of it reinforce structure in PLGA.     

The Polycondensing Temperature rather than Time Determines the Degradation and Drug Release of Poly(Glycerol–Sebacate) Doped with 5-Fluorouracil

Poly(glycerol–sebacate) (PGS) is an elastomeric biodegradable polyester that could be used as biodegradable drug carrier. We have previously prepared PGS implants doped with 5-fluorouracil (5-FU-PGSs) and found that 5-FU-PGSs exhibited an initial burst of 5-FU release during in vitro degradation. The synthesis temperature and time are two of the most important reaction conditions for polymer synthesis. Therefore, in order to establish a controllable drug-release manner, we prepared a series of 5-FU-PGS with 2% weight of 5-FU under synthesis conditions with different polycondensing temperature and time and characterized the infrared spectrum properties, in vitro degradation and drug release. Results showed that the polycondensing temperature determined the mechanical properties, degradation and drug release of 5-FU-PGSs. With the polycondensing temperature increasing, the elastic modulus and hardness of 5-FU-PGSs increased, and the mass loss and 5-FU release rate decreased. The polycondensing time had no significant influence on the mechanical property, degradation and drug release of 5-FU-PGSs. We suggest that the polycondensing temperature is the factor to control the drug-release manner.     

Developing novel Ca-zeolite/poly(amino acid) composites with hemostatic activity for bone substitute applications

Abstract

The novel Ca-zeolite/poly(amino acid) (CaY/PAA) composites for bone substitute applications with hemostatic activity were prepared using the in situ melting polymerization method. In this study, Ca-zeolite (CaY) loaded with Ca²⁺ was obtained from Y-type zeolite (NaY) by ion-exchange method. The properties of the CaY/PAA composites and PAA, including composition, structure, compressive strength, in vitro degradability in phosphate-buffered solution (PBS), bioactivity, cytocompatibility and in vitro coagulation tests were characterized and investigated. The results showed that compressive strength of the CaY/PAA composites ranged from 145 to 186?MPa, demonstrating sufficient mechanical strength for load-bearing bone substitute. After soaking in PBS for 16 weeks, the weight loss of 25CaY/PAA and 50CaY/PAA were 4.1 and 1.6?wt%, respectively, and the pH values for CaY/PAA composites increased to about 8.0 in 2 weeks and then gradually stabilized around 7.4, indicating good stability in PBS. Scanning electron microscope and energy dispersive spectrometer results showed that the composites were bioactive and new apatite layers attached on their surfaces. Mesenchymal stem cells (MSCs) exhibited high-proliferation in the extract solution of the CaY/PAA composites and were well spread on the surfaces of the composites. Cells on the CaY/PAA composite groups showed higher alkaline phosphatase (ALP) activity indicating the potential to promote cell differentiation. The in vitro coagulation tests showed that CaY/PAA composites have shorter clotting time and better performance of promoting blood coagulation than other samples, presenting improved hemostatic activity. In summary, the results demonstrated that the CaY/PAA composites had good mechanical strength, stability, bioactivity, cytocompatibility and hemostatic activity for bone substitute applications.     

Preparation,mechanical properties and in vitro cytocompatibility of multi-walled carbon nanotubes/poly(etheretherketone) nanocomposites

Desired bone repair material must have excellent biocompatibility and high bioactivity. Moreover, mechanical properties of biomaterial should be equivalent to those of human bones. For developing an alternative biocomposite for load-bearing orthopedic application, combination of bioactive fillers with polymer matrix is a feasible approach. In this study, a series of multi-walled carbon nanotubes (MWCNTs)/poly(etheretherketone) (PEEK) bioactive nanocomposites were prepared by a novel coprecipitation-compounding and injection-molding process. Scanning electron microscope (SEM) images revealed that MWCNTs were adsorbed on the surface of PEEK particles during the coprecipitation-compounding process and dispersed homogeneously in the nanocomposite because the conjugated PEEK polymers stabilized MWCNTs by forming strong π–π stack interactions. The mechanical testing revealed that mechanical performance of PEEK was significantly improved by adding MWCNTs (2–8 wt%) and the experimental values obtained were close to or higher than that of human cortical bone. In addition, incorporation of MWCNTs into PEEK matrix also enhanced the roughness and hydrophilicity of the nanocomposite surface. In vitro cytocompatibility tests demonstrated that the MWCNTs/PEEK nanocomposite was in favor of cell adhesion and proliferation of MC3T3-E1 osteoblast cells, exhibiting excellent cytocompatibility and biocompatibility. Thus, this MWCNTs/PEEK nanocomposite may be used as a promising bone repair material in orthopedic implants application.     

Cellulose-based film modified by succinic anhydride for the controlled release of domperidone

Succinic anhydride (SAD) modified microcrystalline cellulose (MCC) films was prepared and used for the controlled release of the drug domperidone (dom). The morphology and chemical structure of the modified materials were characterized by SEM, FTIR, XRD and TG/DSC techniques. The physical properties, such as water uptake and swelling, light barrier properties, mechanical testing, in vitro degradation behavior, have been investigated. Results showed that the modified cellulose membranes exhibited good anti-UV properties, higher water uptake values, improved mechanical capacity and anti-biodegradability. In addition, the modified MCC films (MS) as the drug carrier indicated the controlled release of domperidone and the release mechanism was proposed using Korsmeyer–Peppas equation at pH 7.4. The developed drug delivery system possessed the profound significance in improving pharmacodynamics and bioavailability of drugs.     

Long-Term Effect of Gamma Irradiation on the Functional Properties and Cytocompatibility of Multiblock Co-Polymer Films

Abstract

The purpose of this work was to investigate the long-term effect of gamma-irradiation treatment on the functional properties of PEG-PDLLA and PEG-PLGA films and to evaluate the cytocompatibility of sterilized samples. Chemical and thermal properties, and cytocompatibility of sterilized films were detected for samples at time zero and after storage at 5 ± 3°C for 60 days. An in vitro degradation study was carried out on polymer samples to examine the effect of sterilization on the degradation performances of co-polymer films. Incubated samples were characterized in terms of film surface structure (SEM), chemical (GPC) and thermal (DSC) properties. The study performed on films upon gamma sterilization showed no significant changes of the PEG-PDLLA and PEG-PLGA film structure, while GPC analysis highlighted that the effect of gamma irradiation was dependent on the M_w and composition of polymers. DSC traces suggested more pronounced gamma-ray effects on the PEG-PLGA multiblock co-polymer. During the stability study important changes in terms of structure surface, thermal properties and cytocompatibility were observed and investigated. Data collected during the in vitro degradation study emphasized the need to know and investigate the degradation performances and behaviour of polymer or polymer systems (as DDS, scaffolds and bandage) treated with gamma rays.     

Synthesis and Characterization of Shape Memory (Meth)Acrylate Co-Polymers and their Cytocompatibility In Vitro

A series of novel transparent shape memory co-polymers, made from (meth)acrylate monomers, intended to be used as intraocular lens, was synthesized. The thermo-mechanical properties, shape memory properties and optical properties of the co-polymers could be adjusted by using monomers with various alkyl chain lengths. The cytocompatibility of the prepared co-polymers to L929 mouse connective tissue fibroblasts was demonstrated in vitro, and the co-polymers exhibited favorable cytocompatibility, supporting cell viability and proliferation. This study showed that the prepared co-polymers, which exhibited good flexibility, adjustable shape memory properties, high transparency and favorable cytocompatibility, could find great promising applications as intraocular lens.     

Preparation of Polyisobutene‐graft‐Poly(methyl methacrylate) and Polyisobutene‐graft‐Polystyrene with Different Compositions and Side Chain Architectures through Atom Transfer Radical Polymerization (ATRP)

Polyisobutene‐graft‐poly(methyl methacrylate) and polyisobutene‐graft‐polystyrene with controlled compositions and side chain architectures were prepared through atom transfer radical polymerization (ATRP). Poly[isobutene‐co‐(p‐methylstyrene)‐co‐(p‐bromomethylstyrene)] (PIB) was used as a macroinitiator in the presence of CuCl or CuBr as a catalyst and dNbpy as a ligand. The compositions were controlled by the conversion of the monomer with polymerization time. The molecular weight distributions of the side chains were controlled through ATRP in the presence/absence of a halogen exchange reaction. DSC and DMA measurements showed that graft copolymers have two glass transition temperatures suggesting microphase separated behavior, which was also confirmed by SAXS measurements. The phase and dynamic mechanical behaviors were strongly affected by the compositions and/or the side chain architectures. The properties of the graft copolymers were controlled in a wide range leading to toughened glassy polymers or elastomers.     

Preparation,in vitro degradability,cytotoxicity, and in vivo biocompatibility of porous hydroxyapatite whisker-reinforced poly(L-lactide) biocomposite scaffolds

Biodegradable and bioactive scaffolds with interconnected macroporous structures, suitable biodegradability, adequate mechanical property, and excellent biocompatibility have drawn increasing attention in bone tissue engineering. Hence, in this work, porous hydroxyapatite whisker-reinforced poly(L-lactide) (HA-w/PLLA) composite scaffolds with different ratios of HA and PLLA were successfully developed through compression molding and particle leaching. The microstructure, in vitro mineralization, cytocompatibility, hemocompatibility, and in vivo biocompatibility of the porous HA-w/PLLA were investigated for the first time. The SEM results revealed that these HA-w/PLLA scaffolds possessed interconnected pore structures. Compared with porous HA powder-reinforced PLLA (HA-p/PLLA) scaffolds, HA-w/PLLA scaffolds exhibited better mechanical property and in vitro bioactivity, as more formation of bone-like apatite layers were induced on these scaffolds after mineralization in SBF. Importantly, in vitro cytotoxicity displayed that porous HA-w/PLLA scaffold with HA/PLLA ratio of 1:1 (HA-w₁/PLLA₁) produced no deleterious effect on human mesenchymal stem cells (hMSCs), and cells performed elevated cell proliferation, indicating a good cytocompatibility. Simultaneously, well-behaved hemocompatibility and favorable in vivo biocompatibility determined from acute toxicity test and histological evaluation were also found in the porous HA-w₁/PLLA₁ scaffold. These findings may provide new prospects for utilizing the porous HA whisker-based biodegradable scaffolds in bone repair, replacement, and augmentation applications.     

Effects of hydrolysis on a new biodegradable co-polymer

The aim of this study was to examine the feasibility of using a new low-modulus biodegradable thermoplastic elastomer for in vivo application as a stent cover. The new polymer, a thermoplastic elastomer, consists of a three-armed co-polymer of poly(lactide)acid (PLLA), poly(trimethylene carbonate) (PTMC) and poly(caprolactone) (PCL). A degradation study was performed in a buffer solution at 37°C for 4 and 6 weeks. The effect of degradation on mechanical properties was studied by stress-strain measurements and explained by using modulated DSC, GPC and mass measurements. A tapered block of PLLA and trimethylene carbonate connecting the crystalline outer part and the inner elastic part was highly susceptible to hydrolysis and caused rapid degradation and subsequent loss of mechanical properties. Random chain scission and homogenous hydrolysis resulted in a loss in mass and molecular weight. After 6 weeks of in vitro hydrolysis the molecular weight had decreased 54% and the elongation-at-break dropped from more than 300% to 90%. A medium free cell seeding study showed that endothelial cells adhered well to the polymeric material. An indicative animal study with the polymer acting as a stent cover showed very low levels of inflammation; however, pronounced neointima thickening was observed which was probably due to the premature failure of the material.     

Triblock Copolymers Based on 1,3‐Trimethylene Carbonate and Lactide as Biodegradable Thermoplastic Elastomers

Summary: Biodegradable triblock copolymers based on 1,3‐trimethylene carbonate (TMC) and different lactides (i.e. D ,L ‐lactide(DLLA), L ‐lactide (LLA), D ‐lactide (DLA)) designated as poly(DLLA‐TMC‐DLLA), poly(LLA‐TMC‐LLA) and poly(DLA‐TMC‐DLA) were prepared and their mechanical and thermal properties were compared with those of high molecular weight poly(TMC) and poly(TMC‐co‐DLLA) statistical copolymers. Triblock copolymers containing crystallizable LLA or DLA segments perform as thermoplastic elastomers (TPEs) when the poly(lactide) blocks are long enough to crystallize. In blends of poly(LLA‐TMC‐LLA) and poly(DLA‐TMC‐DLA) triblock copolymers, stereo‐complex formation between the enantiomeric poly(lactide) segments occurs as demonstrated by differential scanning calorimetry and light microscopy. These blends have good tensile properties and excellent resistance to creep under static and dynamic loading conditions.

Permanent deformation (after 2 h recovery) of compression‐molded poly(TMC) and solvent‐cast poly(LLA‐TMC‐LLA) and poly(ST‐TMC‐ST) films.     

Photopolymerizable and injectable polyurethanes for biomedical applications: Synthesis and biocompatibility

Two types of photopolymerizable and injectable polyurethane acrylates (PUAs), based on poly(propylene glycol) or poly(caprolactone diol) and hydroxyethyl methacrylate, were synthesized and characterized in order to obtain information regarding their use as an injectable material for biomedical applications. Structural characteristics of the biomaterials, including the degree of phase separation, were evaluated by Fourier transform infrared spectroscopy. The viscosities of the obtained biomaterials make them suitable for injection, molding and photopolymerization using visible light, as demonstrated by the injection test. The cured polymers had mechanical properties comparable to those of certain soft tissues, such as skin. An in vitro cell–polyurethane cytotoxicity study was carried out with mesenchymal stem cells from rat tibias and femurs. The proliferation/viability of the cells in the presence of the synthesized material was assessed by the MTT assay, collagen synthesis analysis and the expression of alkaline phosphatase. The results that were obtained through the in vitro tests indicated that PUAs are cytocompatible. The in vivo experiments were correlated with the in vitro tests and showed low levels of toxicity for the obtained biomaterials. Histology cross-sections showed that the biomaterials induced no significant inflammatory reaction. Our study demonstrates the potential for using synthesized photocurable polyurethanes in biomedical applications. Furthermore, the obtained injectable polymer systems employ minimally invasive procedures and can be molded in situ before photopolymerization with visible light.     

Electrospinning of poly(lactic acid)/polyhedral oligomeric silsesquioxane nanocomposites and their potential in chondrogenic tissue regeneration

The study was conducted to evaluate the cytocompatibility and hydrolytic degradability of the new poly(lactic acid)/polyethylene glycol-polyhedral oligomeric silsesquioxane (peg-POSS/PLLA) nanocomposite as potential material for cartilage regeneration. PLLA scaffolds containing 0 to 5% of peg-POSS were fabricated by electrospinning. Human mesenchymal stem cells (hMSC’s) were cultured in vitro to evaluate the cytocompatibility of the new nanocomposite material. Hydrolytic degradation studies were also carried out to analyze the mass loss rate of the nanocomposites through time. The addition of the peg-POSS to the PLLA did not affect the processability of the nanocomposite by electrospinning. It was also observed that peg-POSS did not show any relevant change in fibers morphology, concluding that it was well dispersed. However, addition of peg-POSS caused noticeable decrease in mean fiber diameter, which made the specific surface area of the scaffold to rise. hMSC’s were able to attach, to proliferate, and to differentiate into chondrocytes in a similar way onto the different types of electrospun peg-POSS/PLLA and pure PLLA scaffolds, showing that the peg-POSS as nano-additive does not exhibit any cytotoxicity. The hydrolytic degradation rate of the material was lower when peg-POSS was added, showing a higher durability of the nanocomposites through time. Results demonstrate that the addition of peg-POSS to the PLLA scaffolds does not affect its cytocompatibility to obtain hyaline cartilage from hMSC’s.