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Bone Marrow Stromal Cells Associated with Poly L-Lactic-Co-Glycolic Acid (PLGA) Nanofiber Scaffold Improve Transected Sciatic Nerve Regeneration

Volume 15, Issue 3 – Issue Serial Number 58, Summer 2017, Page 149-156   ( PDF (380 K) ) Document Type: Research Paper DOI: 10.15171/ijb.1576 Authors Gholamreza Kaka1; Jamshid Arum1; Seyed Homayoon Sadraie1, 2; Asgar Emamgholi1; Alireza Mohammadi 1 ۱Neuroscience…

Volume 15, Issue 3 – Issue Serial Number 58, Summer 2017, Page 149-156   ( PDF (380 K) )
Document Type: Research Paper
DOI: 10.15171/ijb.1576

Authors
Gholamreza Kaka1; Jamshid Arum1; Seyed Homayoon Sadraie1, 2; Asgar Emamgholi1; Alireza Mohammadi 1
۱Neuroscience Research Center, Baqiyatallah University of Medical Sciences, Tehran, Iran
۲Department of Anatomy, School of Medicine, Baqiyatallah University of Medical Sciences, Tehran, Iran

Abstract
Background:Although peripheral nerves show capacity for regeneration after injury to a certain extent, the extent of regeneration is not remarkable. Previous studies have suggested that through the production of growth factors or extracellular matrix components, mesenchymal stem cells may enhance nerve regeneration.
Objectives:In the present study, the therapeutic potency of the Bone Marrow Stromal Cells (BMSCs) associated with Poly L-lactic-co-glycolic acid (PLGA) nanofiber Scaffoldson rat sciatic nerve repair was evaluated.
Material and Methods:Thirtyadult male Wistar rats (220-250 g) were divided randomly into six groups, including control 1 (transected sciatic nerve), control 2 (transected sciatic nerve and stitched), Sham, PLGA, BMSCs, and PLGA+BMSCs. Functional recovery was evaluated at the end of 2nd, 4th, 6th, and 8th weeks after surgery using sciatic functional index (SFI) and hot water test. After killing all rats at the end of 8th week, their sciatic nerves were removed, fixed, and processed for the histological  examination and analysis by the Motic software.
Results:A significant recovery of the sciatic nerve function was observed in the PLGA+BMSCs transplanted group at the  ۸th week after surgery as demonstrated by SFI and hot water findings. Histological examinations also showed a significant improvement in the PLGA+BMSCs group compared to the control 1, 2, Sham, PLGA and BMSCs groups.
Conclusion:BMSCs associated with PLGA nanofiber scaffold might be useful for improving the functional peripheral nerve repair having some clinical outcome.

Keywords: Poly L-lactic-co-glycolic acid (PLGA); Repair; Scaffold; Sciatic nerve
Main Subjects:Tissue Engineering

Full Text

۱٫ Background

Peripheral nerve damage is among the most prevalent human disabilities. The rate of peripheral nerve injuries in the developed countries was assessed to be between 13 and 23 per 100,000 population per year (1, 2). Although these injuries are not life-threatening but impose a high financial burden on the patients and the health care systems (3).

Nerve damages are divided into neuraproxy, axonotmesis, and neurotmesis (4, 5). A relatively common type of traumatic injury affecting the peripheral nervous system is neurotmesis. Cell therapy, as a nerve repair strategy creates a favorable environment in the peripheral nervous system (6, 7). Since application of the embryonic stem/germ cells is likely to be limited due to the ethical, genetics, as well as other considerations, many investigators have focused their works on the adult stem cells as the potential source for the regenerative medicine (8, 9). Among the adult stem cell reservoirs, bone marrow has long been used as a source for deriving mesenchymal stem cells, but, notably changes such as reduction in the available cell number with an increasein the patient’s age, longer doubling times, and lower differentiation potential have also been reported as the limiting factors in (10, 11). Polymers could be used as the scaffolds for helping differentiated cell adhesion and maintenance of their function without preventing proliferating cells’ organization and growth  as well as aiding the task of the extracellular matrix. As the cells’ and tissues’ transporters, scafolds can be constructed by both natural and artificial polymers (12). These scaffolds must be biodegradable, nonpoisonous, mechanically similar to the tissue that will be substituted, and capable of binding to the other molecules (13). In this regard, natural polymers have been studied for biomaterials application. Poly L-lactic-co-glycolic acid (PLGA) is known as a biodegradable and biocompatible polymer. In addition, PLGA nanofibers could be used as the scaffold alongside bone marrow cells in the tissue engineering (14). In a study on the feasibility of PLGA (10:90) polymer, it was shown that PLGA could be considered as a potential candidate for the repair or regeneration in theCNS (11). These polymers have recently received much attentions in the tissue engineering (15).

Stem cells are cells with a high potential for differentiation as characterized by their capability for unlimited self-renewal, tissue-specific precursors, and differentiation (16). Bone marrow stromal cells (BMSCs) could differentiate into hepatocytes, skeletal muscle, cardiomyocytes, and blood cells. The potency of the BMSCs to induce neurogenesis  might constitute  a potential for  assisting   the  functional  recovery of  the  damaged CNS. Remarkably, recent in vitro studies have shown that BMSCs can differentiate into the neural cells depending on the growth  conditions. BMSCs might  represent a potential  alternative  for substituting the  embryonic  stem  cells. BMSCs are cells of choice for application in cell the therapy by replacing the defunct neurons. These cells are capable ofproducing various types of growth factors and cytokines (17). BMSCs are among the cells which can appropriately grow and proliferate on the scaffolds (15). 

۲٫ Objective

The present study has aimed to evaluate the effects of BMSCs on PLGA nanofiber scaffolds for repairing of the transected sciatic nerve in the rat.

۳٫ Materials and Methods

۳٫۱٫ Fabrication of the PLGA Scaffolds by Electrospinning

The PLGA nanofibrous (Sigma, USA) scaffolds were fabricated by electrospinning process (Fanavaran, Iran). Dimethylformamide (Merck, Germany) and chloroform (Ghatranshimi, Iran) (1:3) were used to dissolve PLGA. For electrospinning, the solution was fed into a 5 mL plastic syringe with a needle diameter of 0.4 mm. A high voltage (20 kV) was attached to the tip of the needle to generate the electric field when a fluid jet was ejected at the speed of 1 mL.h-1 A positively charged jet was formed from the Taylor cone and was sprayed to the grounded aluminum foil target (12).

 ۳٫۲٫ Scanning Electron Microscope (SEM)

The nanofibers were observed with Scanning Electron Microscopy (SEM; HITACHI S-4800, Japan) after gold coating. XRD patterns of all samples were obtained at room temperature with a BRUKER D8 diffractometer (Cu Kα radiation, λ = ۱٫۵۴۰۶ A° ) with the scanning rate of 5°.min-1. One hundred different fibers were selected randomly in SEM images and the diameter mean was presented.

 ۳٫۳٫  Isolation and Culture of BMSCs

Bone marrow was extracted from the femurs of 3 Wistar rats. Briefly, the rat femurs were aseptically removed under deep anesthesia using ketamine and xylazine (Alfasan, Holland) intraperitonealy. The femurs were transected and bone marrow aspirated by a syringe containing 1mL of culture medium α-MEM (Gibco, UK). The content of the syringe was cultured in α-MEM medium containing 1% penicillin/streptomycin (Gibco, UK) in addition to 10% Fetal Bovine Serum (FBS) (Gibco, UK) and incubated at 37 °C and 5% CO2. After 24 hours,  the BMSCs cell culture medium was removed and the cells were rinsed with the sterile phosphate-buffered saline (PBS). Subsequently PBS was replaced by addition of fresh medium. Once the cells were attached and grown to 70-80% of the confluency, the cells were passaged using 0.25% Trypsin (Sigma, USA) and 0.04% Ethylenediaminetetraacetic acid (EDTA) (Sigma, USA) (18, 19).

 ۳٫۴٫ BMSCs Culturing on the PLGA Nanofiber Scaffold

PLGAnanofibrous scaffolds were sterilized with 70% ethanol for 30 min and UV ray for 24h and seeded with the rat third passage of BMSCs in the α-MEM medium. The constructs were cultured for 2 weeks with the medium being replaced once every 3 days. The cell adhesion efficiency was expressed as the number of cells attached to the scaffold as the percentage of seeded cells. At the end of the culture, the BMSCs on PLGA were fixed and stained with Hematoxylin and Eosin  H&E.

۳٫۵٫  Animals and Surgical Procedure

All experiments including animals and surgical procedures were approved by the Ethics Committee of Baqiyatallah University of Medical Sciences. In this research, right sciatic nerve transected in midpoint of thigh in 30 adult male rats and were divided randomly into six groups:  ۱) Control 1 without any intervention; 2) Control 2 immediately after transected sciatic nerve stitched; 3) Sham-treated with culture medium on the injured nerve; 4) PLGA treated with a thin PLGA nanofiber around the injured nerve; 5) BMSCs treated with transplantation of 100000 BMSCs around the injured nerve, and 6) PLGA+BMSCs treated with a thin PLGA nanofiber contain attached BMSCs around the injured nerve.

 ۳٫۶٫ Sciatic Functional Index (SFI) Assessment

Functional recovery was assessed by SFI at the end of 2nd, 4th, 6th, and the 8th weeks after surgery. In order to determine the SFI index, the hind limbs were stained with ink to be printed footprints on a white paper. The lengths of the third toe to its heel (PL), the second toe to the fourth toe (IT), and the first to the fifth toe (TS) were measured on the contralateral normal side (N), and the experimental side (E) in each rat. SFI was computed using the following modified formula:

SFI= |-38.5 (EPL-NPL/NPL) + 109.5 (ETS-NTS/NTS) + 13.3 (EIT-NIT/NIT)-8.8|

In this study, SFI equal to -100 indicates a significant impairment, whereas, an SFI oscillating around 0 is considered to reflect normal function (20).

 ۳٫۷٫ Assessment of Sciatic Nerve Sensory Functional Index; Hot Water

At the end of above  defined times, the hot water behavioral test was done; a method for evaluation the sensory function of the sciatic nerve. After the water temperature reached to 50 °C, the injured leg was entered to the warm water bath as long as the animals were sensing and dragging their leg out of the water. The amount of time required for the animal to  retract its limb from the water was considered as the “reaction time”. We repeated this test 3 times with 10 minutes intervals for each animal separately (21).

 ۳٫۸٫ Histological Analysis

At the end of the 8th week after surgery, all right rat’s sciatic nerves were removed, fixed. and processed for the histological evaluation. Sciatic nerves were transversely sectioned at 5µm thickness, stained with hematoxylin-eosin (H&E) (Merck, Germany), and hematoxylin-Van Gieson stain (Merck, Germany). The number of nerve fibers waere counted from at least 5 randomly selected areas (magnification:1000×) in different categories based on the diameter (D) (including D> 6 µm, D= 4-6 µm, and D< 4 µm) using the Motic software.In addition, the surface area occupied by blood vessels (per unit area=100000 μm2) were also measured.

۳٫۹٫ Statistical Analysis

All data were expressed as mean±SEM and were analyzed using one-way analysis of variance (ANOVA) followed by Post Hoc Tukey with the SPSS 22.0 software package. p< 0.05 was considered as an indication of a significant difference. All data showed in mean ± SEM.

۴٫ Results

۴٫۱٫ SEM Evaluation

PLGA porous electrospun nanofibers were formed with various thicknesses, folds, layers, and different directions. In SEM imaging, the diameter of these fibers was estimated between 100 and 270 nm.

۴٫۲٫ BMSCs Proliferation on the PLGA Nanofibers

Our previous study showed that the cultured BMSCs, as the mesenchymal stem cells, have high purity, and are available in sufficient amount (13,14). Light microscope and SEM evaluation of BMSCs seeded on the PLGA nanofibers showed that nanofibers retain their  structure, the rate of degradation was negligible, as well as appropriate interaction with cells. The cells proliferated and closely attached to each other. SEM imaging showed no major differences between the cell morphology in nanofibers groups (Fig. 1). The BMSCs grown on these scaffolds had a more flattened morphology with multiple poses and seeded cells attached to the nanofiber surface and penetrated into the pores of PLGA nanofiber scaffold.

۴٫۳٫ SFI Results

The mean of SFI indexes after surgery in all groups were significantly decreased and tended to -100. After 2nd, 4th, and 6th weeks of surgery, SFI mean was increased in all groups. Our results showed that the mean SFI in PLGA, BMSCs, and PLGA+BMSCs groups was significantly increased compared to controls and Sham groups (Fig. 2).

۴٫۴٫ Sciatic Nerve Sensory Evaluation; the Hot Water

At the 8th week after surgery, the reaction time in the hot water test was significantly decreased in PLGA, BMSCs groups, and substantially in the PLGA+BMSCs group compared to the controls and Sham groups (Fig. 3).

۴٫۵٫ Histomorphometric Analysis

Based on nerve diameter, the histomorphometric results showed that at the 8th week after surgery, the number of nerve fibers in the different categories was significantly increased in the PLGA+BMSCs group compared to the control 1, 2, and Sham groups, respectively (p<0.05) (Fig. 4, 5).

The amount of collagen fibers in the epineurium and perineurium was decreased in the PLGA+BMSCs group compared to the control 1, 2, and Sham groups, as well (p<0.05) (Fig. 6).

Also our results showed that area engaged in the blood vessels in the PLGA+BMSCs group was significantly increased compared to the other groups, as well (Fig. 7).

۵٫ Discussion

Construction of a biodegradable scaffold for cell culture and application in tissue repair is one of the most important parameters in the tissue engineering. PLGA, as a synthetic, non-toxic, and biodegradable material has a high tensile strength is being used in the manufacturing biological scaffolds (22). In this study, the electron microscopic images of the PLGA nanofibers showed that these fibers with diameters ranging from 100 to 270 nm provide high porosity and suitable bonding capabilities for cultivation and cell growth such as BMSCs in vitro. This finding is somewhat in alignment with the results of Xu et al. (2007) as they could culture smooth muscle and endothelial cells on the nanofiber scaffold PLLA-CL (poly L-lactide-co-epsilon-caprolactone) (23). Formerly, Kazeminejad and his colleagues have shown the possibility of human bone marrow mesenchymal stem cells’ proliferation and differentiation into hepatocytes on nanofibrous scaffold formed by Poly (Ԑ-caprolactone; PCL), collagen, and polyethersulfone (PES) (24). In the present study, the results of SFI at the 8th weeks after surgery has shown that the mean of SFI was significantly improved in the PLGA+BMSCs group compared to the control group. This finding is agreement with the results of Liu et al. (2011) and Zarbakhsh et al. (2012).  Liu and coworkers have reported the significantly higher SFI in the group that had a biodegradable nerve conduit and stem cells derived from adipose tissue at the 8 weeks after surgery (25). In addition, Zarbakhsh and colleagues have reported that bone marrow mesenchymal stem cells have the ability to improve SFI following to a nerve injury (26). It seems SFI improvement in the transected sciatic nerve treated with the PLGA+BMSCs group is due to neurotrophins secretion from transplanted bone marrow mesenchymal stem cells (27) and increased PLGA nanofibers porosity, flexibility, and surface area. Hot water test results showed a significant sensory function improvement in the PLGA+BMSCs group compared to the control group. Gärtner et al. (2012) have demonstrated that chitosan membranes and human mesenchymal stem cells from Wharton jelly of the umbilical cord improve pain-reflexes; an observation in agreement with our results (28).  It seems that in our study, functional improvement of the sciatic nerve in therapeutic groups is due to secretion of neurotrophic factors such as Brain Derived Neurotrophic Factor (BDNF), Neurotrophin-3 (NT-3), Neurotrophin-4  (NT-4), Glial cell line-derived neurotrophic factor  (GDNF), and platelet-derived growth factor (PDGF). It is well known that neurotrophins are a family of proteins that play a critical role, particularly in the cell growth and differentiation, as well as sensory neurons restoration; therefore, affecting pain reflexes (27). Histomorphometric results of this research showed that at 8th weeks after surgery, the number of nerve fibers has increased in the PLGA+BMSCs group compared to the control group. Liu and colleagues have reported that transplantation of the adipose-derived stem cells significantly increases the number of nerve fibers compared to DMEM group (25). It has been reported that VEGF directly improves axonal regeneration via stimulation of angiogenesis (29). It seems that improvement of transected sciatic nerve fibers could be due to angiogenesis. Our histological results have demonstrated that formation of collagen fibers in the epineurium has gradually decreased in the control group 1 to PLGA+BMSCs group, respectively.

Several possible mechanisms have suggested for explaining the effect of mesenchymal stem cells on peripheral nerve repair. Overall, mesenchymal stem cells affect the improvement of nerve regeneration by induction of cell transplantation, production of growth factors, extracellular matrix synthesis, release of anti-inflammatory, anti-apoptotic molecules as well as immune system modulators to create a favorable environment for the nerve repair (27).

In addition, previous studies have reported that the PLGA stimulates angiogenesis by endothelial sprouting and creating a suitable environment for the nerve growth and axons repair (30, 31) which are in agreement with the results of the present study. Altogether, these findings suggest that BMSCs along with the PLGA membrane could improve histomorphometric recovery of the transected sciatic nerves in the rat model.

۶٫ Conclusion

Our results have suggested that transplantation of BMSCs seeded on the PLGA nanofiber scaffolds improve transected sciatic nerve regeneration.

Acknowledgements

We  appreciate the financial supports of the Neuroscience Research Center of the Baqiyatallah University of Medical Sciences.

References

Asplund M, Nilsson M, Jacobsson A, Von Holst H. Incidence of traumatic peripheral nerve injuries and amputations in Sweden between 1998 and 2006. Neuroepidemiology. 2009;32(3):217-28. DOI: 10.1159/000197900

Evans GR. Peripheral nerve injury: a review and approach to tissue engineered constructs. Anat Rec. 2001;263(4):396-404. DOI: 10.1002/ar.1120

Rosberg H-E, Carlsson KS, Cederlund RI, Ramel E, Dahlin LB. Costs and outcome for serious hand and arm injuries during the first year after trauma-a prospective study. BMC Public Health. 2013;13(1):1. DOI:10.1186/1471-2458-13-501

Lukovic D, Moreno Manzano V, Stojkovic M, Bhattacharya SS, Erceg S. Concise review: human pluripotent stem cells in the treatment of spinal cord injury. Stem Cell. 2012;30(9):1787-92. DOI: 10.1002/stem.1159

Bahari Z, Manaheji H, Dargahi L, Daniali S, Norozian M, Meftahi G, et al. Time Profile of nNOS Expression in the Spinal Dorsal Horn after L5 Spinal Root Transection in Rats. Neurophysiology. 2015;47(4):287-94. DOI: 10.1007/s11062-015-9535-9

Bahari Z, Manaheji H, Hosseinmardi N, Meftahi GH, Sadeghi M, Danialy S, et al. Induction of spinal long-term synaptic potentiation is sensitive to inhibition of neuronal nos in l5 spinal nerve-transected rats. EXCLI J. 2014;13:751.

Peng J, Wang Y, Zhang L, Zhao B, Zhao Z, Chen J, et al. Human umbilical cord Wharton’s jelly-derived mesenchymal stem cells differentiate into a Schwann-cell phenotype and promote neurite outgrowth in vitro. Brain Res Bull. 2011;84(3):235-43. DOI: 10.1016/j.brainresbull.2010.12.013

Mohammadi A, Attari F, Babapour V, Hassani SN, Masoudi N, Shahverdi A, et al. Generation of Rat Embryonic Germ Cells via Inhibition of TGFss and MEK Pathways. Cell J. 2015;17(2):288-95. DOI: 10.22074/cellj.2016.3732

Ogawa S-i, Tokumoto Y, Miyake J, Nagamune T. Induction of oligodendrocyte differentiation from adult human fibroblast-derived induced pluripotent stem cells. In Vitro Cell Dev Biol Anim. 2011 Aug;47(7):464-9. DOI: 10.1007/s11626-011-9435-2.

Cheng M, Deng J, Yang F, Gong Y, Zhao N, Zhang X. Study on physical properties and nerve cell affinity of composite films from chitosan and gelatin solutions. Biomaterials. 2003;24(17):2871-80. DOI: 10.1016/S0142-9612(03)00117-0

Deuse T, Stubbendorff M, Tang-Quan K, Phillips N, Kay MA, Eiermann T, et al. Immunogenicity and immunomodulatory properties of umbilical cord lining mesenchymal stem cells. Cell Transplant. 2011;20(5):655-67. DOI: 10.3727/096368910X536473

Bini T, Gao S, Wang S, Ramakrishna S. Poly (l-lactide-co-glycolide) biodegradable microfibers and electrospun nanofibers for nerve tissue engineering: an in vitro study. J Mater Sci. 2006;41(19):6453-9.

Zolfagari D, KaKa G, Sadri M, Sadraie S, Emamgoli A, Asghari Jafarabadi M, et al. Study of the Coculture of Bone Marrow Stromal Cells (BMSCs) with PLGA Nanofibers Coated with Gelatin and Poliy-L-lysine. ZUMS J. 2014;22(92):1-13.

Zolfagari D, Kaka G, Sadraee SSH, Herfehdoost G. Characterization of Bone Marrow Stromal Cell Growth on Substrate PLGA nanofibers. J Mazandaran Univ Med Sci. 2014;24(117):65-73.

Emamgholi A, Rahimi M, Kaka G, Sadraie SH, Najafi S. Presentation of a novel model of chitosan-polyethylene oxide-nanohydroxyapatite nanofibers together with bone marrow stromal cells to repair and improve minor bone defects. Iran J Basic Med Sci. 2015;18(9):887.

Joshi C, Enver T. Molecular complexities of stem cells. Curr Opin Hematol. 2003;10(3):220-8.

Kaka GR, Tiraihi T, Delshad A, Arabkheradmand J, Kazemi H. In vitro differentiation of bone marrow stromal cells into oligodendrocyte-like cells using triiodothyronine as inducer. Int J Neurosci. 2012;122(5):237-47. DOI:10.3109/00207454.2011.642037

Yeu IS, Lee HJ, Yi JS, Yang JH, Lee IW, Lee HK. The survival and migration pattern of the bone marrow stromal cells after intracerebral transplantation in rats. J Korean Neurosurg Soc. 2004;36:400-4.

Pannunzio ME, Jou I-m, Long A, Wind TC, Beck G, Balian G. A new method of selecting Schwann cells from adult mouse sciatic nerve. J Neurosci Metod. 2005;149(1):74-81. DOI: 10.1016/j.neulet.2014.02.065

Yu H, Liu J, Ma J, Xiang L. Local delivery of controlled released nerve growth factor promotes sciatic nerve regeneration after crush injury. Neurosci Lett. 2014;566:177-81. DOI: 10.1016/j.neulet.2013.04.054

Ma J, Liu J, Yu H, Wang Q, Chen Y, Xiang L. Curcumin promotes nerve regeneration and functional recovery in rat model of nerve crush injury. Neurosci Lett. 2013;547:26-31. DOI: 10.1007/s11626-010-9381-4

Wang G, Hu X, Lin W, Dong C, Wu H. Electrospun PLGA-silk fibroin–collagen nanofibrous scaffolds for nerve tissue engineering. In Vitro Cell Dev Biol Anim. 2011;47(3):234-40. DOI: 10.1007/s11626-010-9381-4

Xu C, Inai R, Kotaki M, Ramakrishna S. Electrospun nanofiber fabrication as synthetic extracellular matrix and its potential for vascular tissue engineering. Tissue Engin. 2004;10(7-8):1160-8. DOI: 10.1089/ten.2004.10.1160

Kazemnejad S, Allameh A, Soleimani M, Gharehbaghian A, Amirizadeh N, Kaviani S, et al. Development of a novel three-dimensional biocompatible nanofibrous scaffold for the expansion and hepatogenic differentiation of human bone marrow mesenchymal stem cells. Iran J Biotech. 2007;5(4):201-11.

Liu G, Cheng Y, Guo S, Feng Y, Li Q, Jia H, et al. Transplantation of adipose-derived stem cells for peripheral nerve repair. Int J Mol Med. 2011;28(4):565-72. DOI: 10.3892/ijmm.2011.725

Zarbakhsh S, Bakhtiyari M, Faghihi A, Joghataei MT, Mehdizadeh M, Khoei S, et al. The effects of schwann and bone marrow stromal stem cells on sciatic nerve injury in rat: a comparison of functional recovery. Cell J. 2012;14(1):39-46.

Guo Z-y, Sun X, Xu X-l, Zhao Q, Peng J, Wang Y. Human umbilical cord mesenchymal stem cells promote peripheral nerve repair via paracrine mechanisms. Neural Regen Res. 2015;10(4):651. DOI:10.4103/1673-5374.155442

Gärtner A, Pereira T, Simões MJ, Armada-da-Silva PA, França ML, Sousa R, et al. Use of hybrid chitosan membranes and human mesenchymal stem cells from the Wharton jelly of umbilical cord for promoting nerve regeneration in an axonotmesis rat model. Neural Regen Res. 2012;7(29):2247. DOI: 10.3969/j.issn.1673-5374.2012.29.002

Raisi A, Azizi S, Delirezh N, Heshmatian B, Amini K. Use of chitosan conduit for bridging small-gap peripheral nerve defect in sciatic nerve transection model of rat. Iran J Vet Surg. 2012;5(1):89-100.

Biagini G, Pugnaloni A, Damadei A, Bertani A, Belligolli A, Bicchiega V, et al. Morphological study of the capsular organization around tissue expanders coated with N-carboxybutyl chitosan. Biomaterials. 1991;12(3):287-91. DOI:10.1016/0142-9612(91)90036-A

VandeVord PJ, Matthew HW, DeSilva SP, Mayton L, Wu B, Wooley PH. Evaluation of the biocompatibility of a chitosan scaffold in mice. J Biomed Mater Res. 2002;59(3):585-90.

 

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