Preparation, characterization and biocompatibility of calcium peroxide-loaded polycaprolactone microparticles / 浙江大学学报·医学版

OBJECTIVES@#To explore the physicochemical characteristics and biocompatibility of calcium peroxide (CPO)-loaded polycaprolactone (PCL) microparticle.@*METHODS@#The CPO/PCL particles were prepared. The morphology and elemental distribution of CPO, PCL and CPO/PCL particles were observed with scanning electron microscopy and energy dispersive spectroscopy, respectively. Rat adipose mesenchymal stem cells were isolated and treated with different concentrations (0.10%, 0.25%, 0.50%, 1.00%) of CPO or CPO/PCL particles. The mesenchymal stem cells were cultured in normal media or osteogenic differentiation media under the hypoxia/normoxia conditions, and the amount of released O2 and H2O2 after CPO/PCL treatment were detected. The gene expressions of alkaline phosphatase (ALP), Runt-associated transcription factor 2 (RUNX2), osteopontin (OPN) and osteocalcin (OCN) were detected by realtime RT-PCR. SD rats were subcutaneously injected with 1.00% CPO/PCL particles and the pathological changes and infiltration of immune cells were observed with HE staining and immunohistochemistry at day 7 and day 14 after injection.@*RESULTS@#Scanning electron microscope showed that CPO particles had a polygonal structure, PCL particles were in a small spherical plastic particle state, and CPO/PCL particles had a block-like crystal structure. Energy dispersive spectroscopy revealed that PCL particles showed no calcium mapping, while CPO/PCL particles showed obvious and uniform calcium mapping. The concentrations of O2 and H2O2 released by CPO/PCL particles were lower than those of CPO group, and the oxygen release time was longer. The expressions of Alp, Runx2, Ocn and Opn increased with the higher content of CPO/PCL particles under hypoxia in osteogenic differentiation culture and normal culture, and the induction was more obvious under osteogenic differentiation conditions (all P<0.05). HE staining results showed that the muscle tissue fibers around the injection site were scattered and disorderly distributed, with varying sizes and thicknesses at day 7 after particle injection. Significant vascular congestion, widened gaps, mild interstitial congestion, local edema, inflammatory cell infiltration, and large area vacuolization were observed in some tissues of rats. At day 14 after microparticle injection, the muscle tissue around the injection site and the tissue fibers at the microparticle implantation site were arranged neatly, and the gap size was not thickened, the vascular congestion, local inflammatory cell infiltration, and vacuolization were significantly improved compared with those at day 7. The immunohistochemical staining results showed that the expressions of CD3 and CD68 positive cells significantly increased in the surrounding muscle tissue, and were densely distributed in a large area at day 7 after particle injection. At day 14 of microparticle injection, the numbers of CD3 and CD68 positive cells in peripheral muscle tissue and tissue at the site of particle implantation were lower than those at day 7 (all P<0.01).@*CONCLUSIONS@#CPO/PCL particles have good oxygen release activity, low damage to tissue, and excellent biocompatibility.

Effect of CDM3 on the co-culture of human induced pluripotent stem cells with matrigel-coated polycaprolactone to make cardiac patch / 中国胸心血管外科临床杂志

@#Objective    To provide experimental data and theoretical support for further studying the maturity of cardiac patches in other in vitro experiments and the safety in other in vivo animal experiments, through standard chemically defined and small molecule-based induction protocol (CDM3) for promoting the differentiation of human induced pluripotent stem cells (hiPSCs) into myocardium, and preliminarily preparing cardiac patches. Methods    After resuscitation, culture and identification of hiPSCs, they were inoculated on the matrigel-coated polycaprolactone (PCL). After 24 hours, the cell growth was observed by DAPI fluorescence under a fluorescence microscope, and the stemness of hiPSCs was identified by OCT4 fluorescence. After fixation, electron microscope scanning was performed to observe the cell morphology on the surface of the patch. On the 1st, 3rd, 5th, and 7th days of culture, the cell viability was determined by CCK-8 method, and the growth curve was drawn to observe the cell growth and proliferation. After co-cultured with matrigel-coated PCL for 24 hours, hiPSCs were divided into a control group and a CDM3 group, and continued to culture for 6 days. On the 8th day, the cell growth was observed by DAPI fluorescence under a fluorescence microscope, and hiPSCs stemness was identified by OCT4 fluorescence, and cTnT and α-actin for cardiomyocyte marker identification. Results    Immunofluorescence of hiPSCs co-cultured with matrigel-coated PCL for 24 hours showed that OCT4 emitted green fluorescence, and hiPSCs remained stemness on matrigel-coated PCL scaffolds. DAPI emitted blue fluorescence: cells grew clonally with uniform cell morphology. Scanning electron microscope showed that hiPSCs adhered and grew on matrigel-coated PCL, the cell outline was clearly visible, and the morphology was normal. The cell viability assay by CCK-8 method showed that hiPSCs proliferated and grew on PCL scaffolds coated with matrigel. After 6 days of culture in the control group and the CDM3 group, immunofluorescence showed that the hiPSCs in the control group highly expressed the stem cell stemness marker OCT4, but did not express the cardiac markers cTnT and α-actin. The CDM3 group obviously expressed the cardiac markers cTnT and α-actin, but did not express the stem cell stemness marker OCT4. Conclusion    hiPSCs can proliferate and grow on matrigel-coated PCL. Under the influence of CDM3, hiPSCs can be differentiated into cardiomyocyte-like cells, and the preliminary preparation of cardiac patch can provide a better treatment method for further clinical treatment of cardiac infarction.

Formulation and evaluation of the vascular endothelial growth factor loaded polycaprolactone nanoparticles

Abstract In an attempt to increase molecular stability and provide controlled release, vascular endothelial growth factor (VEGF) was encapsulated into polycaprolactone (PCL) nanoparticles. Both VEGF-free and VEGF-loaded PCL nanoparticles were formulated by w/o/w double emulsion of the dichloromethane-water system in the presence of polyvinyl alcohol (PVA) and rat serum albumin. To achieve the optimal formulation concerning particle size and monodispersity, studies were carried out with different formulation parameters, including PVA concentration, homogenization time and rate. Scanning electron microscopy and dynamic light scattering analysis showed respectively that particles had a spherical shape with a smooth surface and particle size varying between 58.68-751.9 nm. All of the formulations were negatively charged according to zeta potential analysis. In vitro release study was performed in pH 7.4 phosphate-buffered saline at 37°C and released VEGF amount was measured by enzyme-linked immunosorbent assay (ELISA) method. At the end of the 35th day, 10% of total encapsulated VEGF was released with a sustained-release profile, which fitted the Korsmeyer-Peppas kinetic model. The bioactivation of the nanoparticles was evaluated using XTT and ELISA methods. As a result, the released VEGF was biologically active and also VEGF loaded PCL nanoparticles enhanced proliferation of the human umbilical vein endothelial cells in cell culture.

Formulation development and pharmacokinetic studies of long acting in situ depot injection of risperidone

Abstract Risperidone is an atypical antipsychotic drug widely prescribed all over the world due to its clinical advantages. The currently available long acting marketed depot formulation of risperidone is a microsphere based preparation using poly-[lactide-co-glycolide] (PLGA) as drug release barrier. It is however, a cold chain product due to thermal instability of PLGA at room temperature. After beginning the depot injection therapy it is administered every two weeks but associated with another drawback of about 3 weeks lag time due to which its tablets are also administered for three weeks so as to attain and maintain therapeutic drug concentration in the body. The present work attempts to develop a long acting depot delivery system of risperidone for once a month administration based on the combination of sucrose acetate isobutyrate and polycaprolactone dissolved in benzyl benzoate to provide an effective drug release barrier for one month without any lag time and which can be stored at room temperature precluding the requirement of cold supply chain. The developed depot formulation showed a sustained in vitro drug release profile with 88.95% cumulative drug release in 30 days with little burst release. The in vivo pharmacokinetic studies of the developed formulation conducted on rats showed attainment of mean peak plasma drug concentration of 459.7 ng/mL in 3 days with a mean residence time of 31.2 days, terminal half-life of 20.6 days, terminal elimination rate constant of 0.0336 per day, and a good in vitro- in vivo correlation.

Use of modified gelatin/PCL electrospun membranes in engineering bilayered skin graft / 中华医学美学美容杂志

Objective:For severe skin defects which are deep to dermis, engineered skin with epidermis and dermis (bilayered) is required. Based on the success of engineering epidermis with GT/PCL electrospun membranes, our study was to investigate whether this membrane could be also used for engineering bilayered skin graft.Methods:From 2013 to 2019, we first prepared three GT/PCL electrospun membranes with different proportion (70∶30; 50∶50; 30∶70) in our laboratory; the biocompatibility of the membrane was evaluated in vitro by seeding fibroblasts or keratinocytes on the membranes. Then the outcome of GT/PCL membranes repairing skin defects in the nude mouse was investigated.Results:Cell attachment and proliferation were significantly improved with increase of gelatin. Histological analyses showed that bilayered skin engineered with GT/PCL (70∶30) group could form relatively better structure after 3 weeks of cultivation in vitro. Further in vivo transplantation studies revealed that scaffolds were not degraded in all three groups, indicating that these materials were not suitable for engineering bilayered skin although they had good biocompatibility.Conclusions:The higher gelatin membranes possess better biocompatibility. Further in vivo transplantation studies reveal that bilayered skin engineered with GT/PCL membranes is able to repair skin defects in the nude mouse.

Electrospun gelatin polycaprolactone nanofiber aerogel combined with cartilage extracellular matrix for repair of cartilage injury in rabbits / 中华创伤杂志

Objective:To investigate the repair effect of electrospun gelatin polycaprolactone (GT/PCL) nanofiber aerogels (NFA) combined with cartilage extracellular matrix (ECM) for treatment of cartilage injuries in rabbits.Methods:Firstly, the GT/PCL electrospun membrane was prepared by electrospinning and was ground into the short fiber at high speed. ECM was extracted and separated from fresh bovine articular cartilage, which mixed with the short fiber solution (10 ∶1). Subsequently, it was used to prepared GT/PCL/ECM (NFA) three-dimensional scaffold. Finally, the physical characteristics of the three different scaffolds (GT/PCL, ECM and GT/PCL/ECM) were detected by scanning electron microscope and Fourier-transform infrared (FTIR) spectrometer, including the composition, microstructure, swelling rate, porosity, compressive strength and degradation rates. And the biocompatibility research was getting on by co-culturing the scaffold with chondrocytes. Fifteen male New Zealand white rabbits were divided into blank control group (Group A, n=5), ECM group (group B, n=5) and composite scaffold(GT/PCL/ECM)group (Group C, n=5) according to the random number table. An injury model was established and three types of bio-scaffold materials were implanted into different groups. At 3 weeks, the cartilage repair was evaluated among groups by semi quantitative global MRI scoring system (WORMS). After the animals were killed, the knee joints of each group were scored by the international society for cartilage repair histological score (ICRs); the ICRs histological score was performedby HE staining and safranine green staining. Results:Three scaffolds showed a porous three-dimensional structure under the scanning electron microscope. FIRT showed that GT and PCL were introduced into the scaffolds successfully. The GT/PCL NAF was loose and unable to be characterized by materials science. The swelling rate of GT/PCL/ECM scaffold [(1, 092.0±32.2)%] was higher than that of ECM scaffold [(933.6±16.3)%] ( P<0.01). The porosity of GT/PCL/ECM scaffold [(92.3±2.3)%] was higher than that of ECM scaffold [(85.9±2.2)%] ( P<0.05). The compressive strength of ECM scaffold [(2.7±0.1)kPa] and of GT/PCL/ECM scaffold [(2.4±0.1)kPa] showed no statistical difference ( P>0.05). The degradation rate of ECM scaffold was higher than that of GT/PCL/ECM scaffold, but the difference was not statistically significant ( P>0.05). The cytotoxicity rating of GT/PCL/ECM scaffold was grade I, indicating that its biocompatibility was better. At 3 weeks, the MRI WORMS score in Group C [(49.0±11.4)points] was significantly higher than that in Group B [(40.0±6.7)points] and that in Group A [(24.0±6.5) points] ( P<0.05 or 0.01); the general ICRS score of group C was [(7.4±1.1) points], which was significantly higher than that of group B [(4.6±1.1)points] and group A [(3.0±1.2)points] ( P<0.01); The ICRS histological scores of group C and group B were [(6.8±0.8)points] and [(4.2±0.8)points] respectively compared with group A [(2.8±0.8)points] were significantly higher ( P<0.05 or 0.01). Conclusion:GT/PCL/ECM (NFA) scaffold has similar tissue structure to natural cartilage and is superior to traditional ECM scaffold in physical properties and biocompatibility, which provides a stable environment for chondrocyte adhesion and growth, promotes collagen regeneration, and thus accelerates the repair of cartilage injury.

Understanding the use of polycaprolactone in East Asian Structural Rhinoplasty: Questions and Answers

@#Surgery as an art in rhinoplasty involves grafting techniques wherein materials (usually autologous) are taken from the septum and supplemented by conchal cartilage. However, not all noses have adequate cartilage material. The quest for materials as possible replacement for human tissue have led to invention of synthetic (e.g. silicone, e-PTFE, porous polyethelene) and non-synthetic products (e.g. processed homograft and xenograft). In this era of advanced medical science, tissue engineering has started the use polycaprolactone (PCL) as a template and scaffold for tissue growth. Because of this characteristic feature, PCL as a mesh has a significant role in structural rhinoplasty.

PI3K/Akt Signaling Involved with Osteoinductive Effects of Achatina fulica Mucus

Abstract Mesenchymal stem cells and osteoblasts play important roles in bone formation. Achatina fulica mucus presented the property of osteoinduction. This study aimed to examine the effects of A. fulica mucus on human mesenchymal stem cell (hMSC) and human fetal osteoblastic cell line (HFOB) differentiation. The integrated effects of A. fulica mucus and polycaprolactone (PCL) on the differentiation of hMSCs were tested. The cell viability of hMSCs treated with A. fulica mucus was investigated by the MTT assay. The cell mineralization was observed by Alizarin Red S staining, the gene expression was investigated using RT-PCR, and the PI3K activation was studied using flow cytometry. The results indicated that A. fulica mucus induced osteogenic differentiation in hMSCs and HFOBs by upregulation of the osteogenic markers; osteopontin (OPN) and osteocalcin (OCN). The results of the Alizarin Red S staining indicated that A. fulica mucus supported mineralization in both hMSCs and HFOBs. The hMSCs cultured on PCL supplemented with A. fulica mucus showed significantly increased RUNX2 and OPN expressions. A. fulica mucus was observed to increase PI3K activation in hMSCs. The findings of this study suggested that A. fulica mucus and biomaterials could be applied together for use in bone regeneration in the future.

In vitro biocompatibility of 3D printed polycaprolactone/nano-hydroxyapatite composite scaffold with bone marrow mesenchymal stem cells / 中国组织工程研究

BACKGROUND: Polycaprolactone/nano-hydroxyapatite composite is a new composite scaffold material prepared based on common bone tissue engineering materials using 3D printing technology. At present, little is reported on the in vitro biocompatibility of the composite material. OBJECTIVE: To investigate the cytocompatibility of 3D printed polycaprolactone/nano-hydroxyapatite composite scaffolds. METHODS: Polycaprolactone and polycaprolactone/nano-hydroxyapatite composite scaffolds were prepared by 3D printing technology to characterize the microstructure, porosity and mechanical properties of the two materials. Rat bone marrow mesenchymal stem cells were inoculated on the surface of the 3D-printed polycaprolactone and polycaprolactone/nano-hydroxyapatite composite scaffolds. Cell proliferation rate was detected by CCK-8 method. Cell growth on the scaffolds was observed by scanning electron microscopy and Live/Dead cell staining. RESULTS AND CONCLUSION: Two kinds of scaffolds had a three-dimensional network and interconnected structure. The fibers were arranged in a regular order and interlaced. There was no gap on the fiber surface, and the fiber spacing and diameter were relatively uniform. There was no significant difference in the porosity between two kinds of scaffolds (P > 0. 05). The elastic modulus of the composite scaffold was higher than that of the simple polycaprolactone scaffold (P < 0. 05). There was no significant difference in cell proliferation between two kinds of scaffolds after 1 day of culture. After 4 and 7 days of culture, cell proliferation on the composite scaffold was significantly faster than that on the simple polycaprolactone scaffold (P < 0. 05). Live/Dead cell staining showed that both polycaprolactone and polycaprolactone/nano-hydroxyapatite composite scaffolds had good cytocompatibility and high cell viability. A larger number of cells adhered to the polycaprolactone/nano-hydroxyapatite composite scaffolds. Scanning electron microscopy showed that cells grew well on two kinds of scaffolds and distributed on the surface and micropores of the scaffold. The secreted extracellular matrix appeared in filaments and surrounded the cells. These findings suggest that the polycaprolactone/nano-hydroxyapatite composite material prepared by 3D printing technology has abundant pores, exhibit good mechanical properties, and have good cytocompatibility and can be used as a scaffold material for tissue engineering.

Fabrication and evaluation of biomimetic biodegradable tissue-engineered annulus fibrosus scaffold / 中国组织工程研究

BACKGROUND: It is still difficult to construct tissue-engineered anulus fibrosus scaffolds which have bionic structure, suitable biodegradability and good biocompatibility. OBJECTIVE: To fabricate bionic biodegradable scaffolds with polycaprolactone (PCL) and polydioxanone (PDS) and evaluate the feasibility as a tissue-engineered annulus fibrosus scaffold. METHODS: Five groups of scaffolds at different PCL/PDS proportions were prepared by melt spinning technique: PCL, PCL/PDS70/30, PCL/PDS50/50, PCL/PDS30/70, and PDS groups. Scanning electron microscopy was used to observe the structure and measure the fiber diameter and pore size of these prepared scaffolds. The mechanical properties and contact angle of the scaffolds were measured. The in vitro and in vivo biodegradation of the scaffolds were observation by in vitro simulation and subcutaneous implantation. The expression of inflammatory factors interleukin-1β and tumor necrosis factor-α in the biodegraded tissues was detected. Human Wharton’s jelly mesenchymal stem cells were cultured for 7 days. Cell viability and proliferation was determined by live/dead cell staining. This study was approved by the Medical Ethics Committee of Tianjin Hospital, China on March 2, 2016. RESULTS AND CONCLUSION: Scanning electron microscopy results showed that the thickness of the scaffold fibers was uniform and the angle between fibers was 60°. The mechanical properties analysis showed that the tensile and compressive modulus of the PDS group was the lowest, which did not meet the mechanical requirements of the anulus fibrosus; the tensile and compressive modulus in the PCL group was the highest, and those in the PCL/PDS70/30 and PCL/PDS50/50 group were moderate. Hydrophilicity test showed that higher PDS proportion led to better hydrophilicity. Biodegradation test showed that the biodegradation of pure PDS and PCL/PDS30/70 was too fast, that of PCL was too slow, and that of PCL/PDS70/30 and PCL/PDS50/50 was appropriate. Analysis of inflammatory response around the biodegraded tissue showed that higher proportion of PCL in the scaffold resulted in more severe inflammatory response. CCK-8 and live/dead cell staining showed that human Wharton’s jelly mesenchymal stem cells had good proliferative activity and high survival rate in the PCL/PDS70/30, PCL/PDS50/50, and PCL/PDS30/70 groups. These results suggest that scaffolds in the PCL/PDS70/30 and PCL/PDS50/50 groups can simulate the structure of natural annulus fibrosus, have appropriate biodegradability, excellent mechanical properties and good biocompatibility, which make it a suitable candidate for tissue-engineered annulus fibrosus scaffold.

Construction and characterization of nano-hydroxyapatite/chitosan/polycaprolactone composite scaffolds by 3D printing / 中国组织工程研究

BACKGROUND: At present, there are many types of bone defect repair scaffolds, but a single type of material is difficult to meet the requirements of bone tissue engineering scaffold materials. Several suitable materials can be combined into a composite material by appropriate methods, taking into account the advantages and disadvantages of various materials. It is the focus of scholars in recent years. OBJECTIVE: To construct nano-hydroxyapatite/chitosan/polycaprolactone composite scaffolds and analyze characterization of composite scaffolds. METHODS: Nano-hydroxyapatite/chitosan/polycaprolactone porous ternary composite scaffold material was prepared by 3D printing and molding technology. The characterization of scaffold material was studied from X-ray diffraction analysis, stent water absorption rate, stent compressive strength, stent degradation performance in vitro, stent aperture analysis, scanning electron microscope analysis and other dimensions. RESULTS AND CONCLUSION: (1) X-ray diffraction analysis showed that the crystal-shaped peak map of nano-hydroxyapatite/chitosan/ polycaprolactone scaffold materials was similar to the hydroxyapatite powder diffraction standard card, suggesting that the scaffold materials were integrated with each other through physical interaction, and did not affect the biological function of hydroxyapatite. (2) The average water absorption rate of the scaffold was 18.28%, and the hydrophilicity was good. The maximum pressure that the scaffold could withstand was 1 415 N, and the degradation rate was similar to the osteogenic rate. (3) Under a microscope, a ternary scaffold material with an aperture of 250 µm was successfully produced. The pore size was uniform and distributed regularly. (4) Scanning electron microscope demonstrated that the fibers composed of chitosan and polycaprolactone were arranged orderly and grid like, hydroxyapatite was distributed uniformly on the fiber surface in granular form, and the ternary composite material presented uniform and loose microporous structure. (5) Nano-hydroxyapatite/chitosan/polycaprolactone ternary composite scaffold material can be successfully prepared through 3D printing and molding technology, which has moderate compressive strength, certain porosity, appropriate degradation rate and water absorption rate, and can lay a foundation for repairing bone defects.

3D printing technology and tissue engineering technology in tracheal replacement: Application and hotspot research / 中国组织工程研究

BACKGROUND: Functional tracheal reconstruction remains a surgical challenge due to the lack of satisfactory tracheal substitutes. OBJECTIVE: To review the research hotspot, clinical application, and main obstacles of tissue-engineered trachea METHODS: A computer-based search of PubMed, Medline, and WanFang databases was performed to retrieve relevant articles published from 2004 to 2019 with the search terms “3D printing, tissue-engineered trachea, trachea reconstruction, tracheal replacement” in English and Chinese. A total of 47 literatures were included in the final analysis. RESULTS AND CONCLUSION: At present, the methods of tracheal reconstruction mainly include artificial tracheal transplantation, allotransplantation, autologous tissue transplantation and tissue-engineered tracheal transplantation. Artificial trachea transplants often fail due to rupture, infection and narrowing of the trachea. Allotransplantation requires long-term immunosuppressive therapy, and death is often caused by necrosis and infection because of insufficient angiogenesis after transplantation. Autogenous tissue has limited ability to replicate the structure and function of the trachea and also has surgical trauma. Tissue-engineered trachea can simulate the biological structure and function similar to natural trachea by selecting suitable scaffold materials and implanting seed cells evenly in the scaffold. It seems to be an ideal tracheal substitute. An intact tracheal scaffold was prepared with biodegradable material using 3D printing technology combined with tissue engineering technology and then implanted into the tissue-engineered trachea cultured with mesenchymal stem cells. This provides a new approach to long-segment tracheal defect reconstruction.

Effects of sustained-release atorvastatin calcium nanofiber scaffold on cell adhesion and proliferation / 中国组织工程研究

BACKGROUND: Statins plays a significant role in regulating blood lipids, treating and preventing cardiovascular and cerebrovascular diseases. Studies have shown that statins has certain potential in promoting bone formation and treating osteoporosis. OBJECTIVE: To prepare the drug release scaffolds for the sustained release of atorvastatin calcium, which consist of bovine serum albumin microspheres and polycaprolactone electrostatic spinning fibers, and to investigate the effects of the drug sustained release scaffolds on osteoblast adhesion and proliferation. METHODS: Bovine serum albumin microspheres containing atorvastatin calcium were prepared by desolvation. A layer of chitosan was coated on the surface of the bovine serum albumin microspheres by electrostatic adsorption, which can increase the stability of the microspheres. Bovine serum albumin microspheres were purified and lyophilized for later use. The lyophilized powder of microspheres was dissolved in organic solvent. An appropriate amount of hydroxyapatite was added in the solvent. The nanofiber scaffolds for sustained release of atorvastatin calcium were prepared via electrospinning. The micromorphology, degradation performance, and sustained-release performance of the nanofiber scaffolds were characterized. The prepared nanofiber scaffolds for sustained-release of atorvastatin calcium were co-cultured with MC3T3-E1 cells to observe cell adhesion and proliferation. RESULTS AND CONCLUSION: (1) Transmission electron microscopy revealed that the shape of the bovine serum albumin nanospheres was regular and circular. Bovine serum albumin nanospheres were discarded in the electrostatic spinning fibers. The basic morphology of the microspheres was retained. (2) Scanning electron microscopy revealed that the nanofibers used for preparation of nanofiber scaffolds for sustained-release of atorvastatin calcium were composed of filaments with uniform diameters and continuous smooth surface. Filaments were intertwined to form a network structure. (3) The nanofiber scaffolds exhibited the fastest degradation in the first month. The material was incomplete when degraded for 3 months. (4) The nanofiber scaffolds had the ability to slow down the release of drugs. The effect could last for more than 1 month. The overall process of drug release was similar to the zero-order kinetic process. (5) The nanofiber scaffolds for sustained-release of atorvastatin calcium can promote MC3T3-E1 cell adhesion and proliferation. (6) These results suggest that the nanofiber scaffolds for sustained-release of atorvastatin calcium have good biocompatibility and can promote the adhesion and proliferation of osteoblasts.

Effect of graphene oxide/polycaprolactone composite electrospun nanofibrous materials on the differentiation of rat brown adipose stem cells into cardiomyocytes / 国际药学研究杂志

Objective: To prepare graphene oxide(GO)/polycaprolactone(PCL)composite matrix nanomaterials with different concentrations, and investigate effects of the nanomaterials on the myocardial differentiation of rat brown adipose stem cells (BASC)in vitro. Methods: The GO/PCL composite nanofiber materials were prepared by electrospinning technology. The biocompatibility of the nanomaterials was tested by the CCK-8 assay after cultivation of the BASC on the pure PCL and GO/PCL composite nanofibers, and the characterization of the nanofiber materials was performed by the scanning electron microscopy(SEM)and electrical conductivity measurement. The expression of cardiomyocyte-related proteins was examined by the cytological method and immunofluorescence staining. The GO/PCL composite nanofiber materials were systematically evaluated for their effect on the viability, proliferation and myocardial differentiation of BASC. Results: The GO/PCL composite nanofiber materials showed no obvious cytotoxicity at the 0.1 mg/ml GO concentration. The statistical results for the protein fluorescence intensities showed that the expression of the cardiomyocyte specific protein, α-actinin, and the intercalated disc-related protein, connexin-43(CX-43), was significantly increased in the GO/PCL group than in the PCL group(P<0.05). The cytoskeletal staining results showed that, compared with the PCL group, the cells in the GO/PCL group showed a long spindle-like stretch similar to the natural myocardial cell bundle, and the growth direction had a certain polarity. Conclusion: This study successfully prepared GO/PCL composite nanomaterials, which could promote the differentiation of BASCs into cardiomyocytes and the expression of intercalated disc-related proteins.

Proliferation and differentiation of mouse spermatogonial stem cells on a three-dimensional surface composed of PCL/gel nanofibers / Proliferación y diferenciación de células madre espermatogónicas de ratón en una superficie tridimensional compuesta de nanofibras PCL / gel

Spermatogonial stem cells (SSCs) have self-renewal and differentiation capacity essential for sperm production throughout the male reproductive life. The electrospun polycaprolactone/gelatin (PCL/Gel) nanofibrous scaffold mimics important features of the extracellular matrix (ECM), which can provide a promising technique for the proliferation and differentiation of SSCs in vitro. The goal of the present study was to investigate the effects of PCL/Gel nanofibrous scaffold on the propagation and differentiation of neonate mouse SSCs (mSSCs). mSSCs were enzymatically isolated, and the cells were purified by differential plating method and seeded on scaffold. After 2 weeks, viability, colony number and diameter, and expression of specific spermatogonial cell genes were investigated. After mSSCs propagation, the cells were cultivated in a differentiation medium on the scaffold for another 2 weeks, and differentiating cells were analyzed by real-time PCR. The number of mSSC colony (P<0.01) and expression levels of specific spermatogonial genes Plzf and Inga6 (P<0.01) and also differentiation genes c-Kit, Tp1 and Ptm1 (P<0.05) were higher in scaffold group compared with control during the culture period. We conclude that mSSCs can be expanded and can differentiate toward spermatid cells on PCL/Gel nanofibrous scaffold with improved developmental parameters.

Las células madre espermatogónicas (CME) tienen capacidad de auto renovación y diferenciación esenciales para la producción de esperma a lo largo de la vida reproductiva masculina. El «scaffold¼ nanofibroso de policaprolactona / gelatina (PCL / Gel) electrohilado imita características importantes de la matriz extracelular (MEC), que puede proporcionar una técnica prometedora para la proliferación y diferenciación de CME in vitro. El objetivo del presente estudio fue investigar los efectos del «scaffold¼ nanofibroso PCL / Gel en la propagación y diferenciación de CME de ratones neonatos (mSSC). Los mSSC se aislaron enzimáticamente y las células se purificaron mediante un método de siembra diferencial y se sembraron en un «scaffold¼. Después de 2 semanas, se investigaron la viabilidad, el número y el diámetro de las colonias y la expresión de genes específicos de células espermatogónicas. Después de la propagación de mSSC, las células se cultivaron en un medio de diferenciación en el «scaffold¼ durante otras 2 semanas, y las células se analizaron mediante PCR en tiempo real. El número de colonias mSSC (P <0,01) y los niveles de expresión de los genes espermatogónicos específicos Plzf e Inga6 (P <0,01) y también los genes de diferenciación c-Kit, Tp1 y Ptm1 (P <0,05) fueron mayores en el grupo de «scaffold¼ en comparación con el control durante el período de cultivo. Concluimos que los mSSC pueden expandirse y diferenciarse en células espermátidas en un «scaffold¼ de nanofibras PCL / Gel con parámetros de desarrollo mejorados.

Estudio de la dosificación del almidón extraído del banano en un polímero de tipo termoplástico / Study of the starch dose extracted from banano in a thermoplastic type polymer / Estudo da dosagem do amido extraído de bananas em um polímero de tipo termoplástico

Resumen La presente investigación tiene como objetivo la extracción del almidón de los residuos del banano y la dosificación en una matriz polimérica termoestable (policaprolactona (PCL)), con el propósito de determinar la formulación adecuada. El almidón extraído se modificó mediante la acetilación y posteriormente se comparó con el almidón sin modificar mediante espectroscopia infrarroja (IR). El almidón modificado presentó una pequeña disminución en el ancho de las bandas comprendido entre 3000 y 3700 cm-1 correspondiente a las vibraciones por estiramiento y por flexión de los grupos hidroxilo, debido a la introducción de los grupos C-O, lo cual indica que se realizó la acetilación. Los dos tipos de almidones se dosificaron en un 10% con PCL y se analizaron a través de calorimetría diferencial de barrido (DSC) analizando los parámetros térmicos más importantes. La dosificación con almidón modificado presentó valores más altos: para la temperatura de transición vítrea presentó un valor de 33 °C y para la temperatura de fusión 66 °C. Sin embargo, el biopolímero con mayor grado de reticulación fue la formulación con almidón sin modificar con un valor de 12%, por lo que resultó ser la mejor formulación.

Abstract In this research both the extraction of starch from banana residues and the dosage in a thermostable polymer matrix (policaprolactone (PCL)) was evaluated with the purpose of determining the appropriate formulation. The extracted starch was modified by acetylation and subsequently compared with the unmodified starch by infrared spectroscopy (IR). The modified starch showed a small decrease in the bands width between 3000 and 3700 cm-1 corresponding to the vibrations by stretching and bending of the hydroxyl groups, due to the introduction of C-O groups, which means that acetylation was successful. The two types of starches were dosed in 10% with polycaprolactone and analyzed through differential scanning calorimetry (DSC) analyzing the most important thermal parameters. The dosage with modified starch presented higher values: for the glass transition temperature it presented a value of 33 °C and for the fusion temperature 66 °C. However, the biopolymer with the highest degree of crosslinking was the unmodified starch formulation with a value of 12%, so it turned out to be the best formulation.

Resumo O objetivo desta pesquisa é a extração de amido de resíduos de banana e dosagem em matriz de polímero termoestável, como a Policaprolactona (PCL), com a finalidade de determinar a formulação adequada. O amido extraído foi modificado por acetilação e posteriormente comparado com o amido não modificado por espectroscopia de infravermelho (IV); onde foi observado que o amido modificado apresentou uma pequena diminuição na largura das bandas entre 3000 e 3700 cm-1, correspondendo às vibrações por estiramento e flexão dos grupos hidroxila, devido à introdução dos grupos CO, o que significa que a acetilação foi realizada. Os dois tipos de amido foram dosados em 10% com policaprolactona, que foi analisada em um DSC, analisando os parâmetros térmicos mais importantes; sendo a dosagem com amido modificado aquela que apresentou maiores valores, assim, para a temperatura de transição vítrea apresentou um valor de 33 °C e 66 °C para a temperatura de fusão; no entanto, o biopolímero com o maior grau de reticulação foi a formulação de amido não modificado com um valor de 12%, de modo que o biopolímero com amido não modificado foi a melhor formulação.

Finite element analysis of stress-strain characteristics of polycaprolactone meniscus scaffold / 吉林大学学报(医学版)

Objective: To analyze the stress-strain characteristics of the polycaprolactone (P C D meniscus scaffold in the knee joint, and to evaluate its feasibility as an implant material. Methods: The magnetic resonance imaging (MRI) scan of volunteer knee joints was used to obtain the planar image data. A three-dimensional finite element model including the femur, tibia, fibula, femoral condyle and tibial plateau articular cartilage, medial and lateral menisci, and ligaments was established. The validity of the model was verified by calculating the contact area of the tibial plateau and comparing with the previous literatures. On this basis, the three-dimensional finite element model of the knee joint after medial meniscectomy was established by deleting the medial meniscus unit and node of the normal knee joint. The knee joint model was established after replacement of the PCL meniscus. The changes of meniscal displacement and contact pressure in three types of knee joint models under 1 400 N femoral axial vertical pressure and the changes of compressive stresses on the femoral articular cartilage and tibial plateau articular cartilage were compared Results: The displacements of the medial and lateral menisci of the healthy knee joint under the axial compression load of 1 400 N femur were 0. 83 and 1. 76 mm, respectively. The displacements of the medial and lateral meniscus of the PCL model were 1. 15 and 2. 20 mm, respectively. Under the same load, the maximum compressive stresses of the healthy knee joint on the medial and lateral cartilage of the tibial plateau were 2. 5 and 1. 7 MPa, respectively; the maximum compressive stresses on the medial and lateral femoral articular cartilage were 2. 7 and 2. 1 MPa, respectively. In the medial meniscus complete resection model, the maximum compressive stresses on the medial and lateral cartilage of the tibial plateau articular cartilage were 9. 0 and 7.0 MPa, respectively, which were normal increase of 260.0% and 311.7%, respectively, compared with the healthy model; and the maximum compressive stresses on the medial and lateral femoral condylar cartilage were 8. 5 and 7. 8 MPa, respectively, which were 214. 8% and 271. 4% higher than the normal models, respectively. When the medial meniscus was replaced with the PCL scaffold, the maximum compressive stresses on the medial and lateral cartilage of the tibial plateau articular cartilage were 2. 7 and 1. 8 MPa, respectively, which were 8. 0% and 5. 9% higher than those of the healthy knee joint model, respectively. The maximum compressive stresses on the medial and lateral femoral condyle cartilage were 3. 0 and 2. 2 Mpa, respectively, which were 11. 1% and 4. 8% higher than the normal model. Concluson: The three-dimensional finite element model of knee joint of PCL material has good biomechanical ability, which can reduce the stress of articular cartilage of femoral condyle and tibial plateau after meniscectomy and achieve the purpose of protecting the articular cartilage.

Appilcation of polycaprolactone/collagen nanofibrous membranes in constituting tissue engineering retinal pigment epithelium / 中华实验眼科杂志

Objective@#To explore the potential of polycaprolactone (PCL)/gelatin nanofibrous composite membrane in constituting tissue engineering retinal pigment epithelium (RPE).@*Methods@#The embryonic stem cells (ESCs) were differentiated into RPE (ESC-RPE) cells by spontaneous differentiation methods.Flow cytometry was used to detect the expression of specific RPE markers in ESC-RPE cells.The nanofiber membrane of PCL and PCL/gelatin nanofibrous composite membrane were prepared by electrospinning.The topography and contact angle of the two membranes were detected.The viability of ESC-RPE cells treated by the extracts of the two kinds of membranes was detected by cell counting kit-8 (CCK-8)method.After the ESC-RPE cells were cultured on the PCL/gelatin nanofibrous composite membrane, immunostaining was used to detect the expression of specific RPE markers of tissue engineering RPE.@*Results@#ESC-RPE cells were negative for pluripotent marker OCT4, but positive for microphthalmia-associated transcription factor (MITF), RPE65 and Bestrophin.Both the nanofiber membrane of PCL and PCL/gelatin nanofibrous composite membrane were porous and the contact angle were (97.2±3.1)° and (13.6±2.4)°, respectively.The extracts of the two kinds of membranes showed no significant effect on the growth of ESC-RPE cells.The tissue engineering RPE based on PCL/gelatin nanofibrous composite membrane positively expressed MITF and ZO-1.@*Conclusions@#PCL/gelatin nanofibrous composite membrane shows good hydrophilicity and biocompatibility.Besides, the membrane is favor for the growth of ESC-RPE cells and holds the potential to constitute tissue engineering RPE.

Selection of the appropriate pore size, surface modification technique for 3D printed tracheal graft and evaluation of its property / 中华胸心血管外科杂志

Objective To prepare 3D printed porous tracheal graft fabricated by PCL and to select the appropriate pore size and surface modification techniques,in order to explore its effect on cell behavior.Methods The PCL porous tracheal graft was prepared by 3D printing technology and biomechanical properties of the graft were measured by means of longitudinal tension,radial compression and three-point bending test.The porous grafts were surface-modified through hydrolysis,amination and nanocrystallization treatment and then characterized by energy dispersive spectroscopy(EDS).The effect of different pore sizes and surface modifications on the cell proliferation behavior was evaluated by CCK-8 and scanning electron microscopy (SEM).Results The 3 D printed porous tracheal graft had similar morphology with the native tracheas(P ＞ 0.05) and better biomechanical properties(P ＜0.05).It was more suitable for cell adhesion and proliferation when the pore size is 200 μm (P ＜ 0.05).Compared to hydrolysis and amination,nanocrystallization treatment successfully improved the cytotropism of the 3D printed tracheal graft(P ＜ 0.05).Conclusion 3 D printed porous tracheal graft shows favorable biomechanical properties.The appropriate pore size of the 3D printed porous tracheal graft is 200 μm and the appropriate surface modification techniques is nanocrystallization.

Repair of Nasal Septal Perforation Using Polycaprolactone Plate and Temporalis Fascia Graft