Polycaprolactone Nanofibers Containing Vascular Endothelial Growth Factor-Encapsulated Gelatin Particles Enhance Mesenchymal Stem Cell Differentiation and Angiogenesis of Endothelial Cells

Jiang, Yongchao; Wang, Xiaofeng; Xu, Yiyang; Qiao, Yuhui; Guo, Xin; Wang, Dongfang; Li, Qian; Turng, Lih‐Sheng

doi:10.1021/acs.biomac.8b00870

Cited by 52 publications

(43 citation statements)

References 40 publications

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“…The basic advantages of using gelatin particles are their slow degradation and controlled release properties in a biological environment because of introducing cross-linking treatment during fabrication. An example would be the work of Jiang and co-workers who prepared PCL fibrous scaffolds containing vascular endothelial growth factor (VEGF)-incorporated gelatin particles which were able to exhibit both diffusion and degradation mediated release for a long period of time (Figure 6b), differentiate mesenchymal stem cells from endothelial cells, sustain the durability of the tubular composition, and form new blood vessels among endothelial cells [136]. The integration of various sustained release characteristics within nanofiber scaffolds protects the encapsulated GFs from biological degradation, generates cellular signal transduction as well as repairs and regenerates damage.…”

Section: Applications Of Nanofibers In Therapeutics Deliverymentioning

confidence: 99%

Electrospinning Nanofibers for Therapeutics Delivery

et al. 2019

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The limitations of conventional therapeutic drugs necessitate the importance of developing novel therapeutics to treat diverse diseases. Conventional drugs have poor blood circulation time and are not stable or compatible with the biological system. Nanomaterials, with their exceptional structural properties, have gained significance as promising materials for the development of novel therapeutics. Nanofibers with unique physiochemical and biological properties have gained significant attention in the field of health care and biomedical research. The choice of a wide variety of materials for nanofiber fabrication, along with the release of therapeutic payload in sustained and controlled release patterns, make nanofibers an ideal material for drug delivery research. Electrospinning is the conventional method for fabricating nanofibers with different morphologies and is often used for the mass production of nanofibers. This review highlights the recent advancements in the use of nanofibers for the delivery of therapeutic drugs, nucleic acids and growth factors. A detailed mechanism for fabricating different types of nanofiber produced from electrospinning, and factors influencing nanofiber generation, are discussed. The insights from this review can provide a thorough understanding of the precise selection of materials used for fabricating nanofibers for specific therapeutic applications and also the importance of nanofibers for drug delivery applications.

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Section: Applications Of Nanofibers In Therapeutics Deliverymentioning

confidence: 99%

Electrospinning Nanofibers for Therapeutics Delivery

et al. 2019

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“…Encapsulation of pro-angiogenic growth factors into electrospun nanofibers is an effective and direct strategy to promote angiogenesis in different physiological and pathological conditions. To date, a large number of experimental studies have successfully encapsulated pro-angiogenic growth factors (mainly VEGF) into nanofibrous mats by means of different techniques, such as coaxial electrospinning, to achieve sustained release profiles [ 128 , 129 , 130 , 131 ]. For example, in order to accelerate endothelialization along the lumen of graft, composite grafts were fabricated by co-electrospinning of chitosan hydrogel/polyethylene glycol (PEG)-b-poly(L-lactide-co-ε-caprolactone) (PLCL) loaded with VEGF as the inner layer and platelet-derived growth factor (PDGF)-loaded emulsion/PLCL nanofibers as the outer layer.…”

Section: Electrospun Nanofibers Meet Angiogenesismentioning

confidence: 99%

Electrospun Nanofibers for Improved Angiogenesis: Promises for Tissue Engineering Applications

et al. 2020

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Angiogenesis (or the development of new blood vessels) is a key event in tissue engineering and regenerative medicine; thus, a number of biomaterials have been developed and combined with stem cells and/or bioactive molecules to produce three-dimensional (3D) pro-angiogenic constructs. Among the various biomaterials, electrospun nanofibrous scaffolds offer great opportunities for pro-angiogenic approaches in tissue repair and regeneration. Nanofibers made of natural and synthetic polymers are often used to incorporate bioactive components (e.g., bioactive glasses (BGs)) and load biomolecules (e.g., vascular endothelial growth factor (VEGF)) that exert pro-angiogenic activity. Furthermore, seeding of specific types of stem cells (e.g., endothelial progenitor cells) onto nanofibrous scaffolds is considered as a valuable alternative for inducing angiogenesis. The effectiveness of these strategies has been extensively examined both in vitro and in vivo and the outcomes have shown promise in the reconstruction of hard and soft tissues (mainly bone and skin, respectively). However, the translational of electrospun scaffolds with pro-angiogenic molecules or cells is only at its beginning, requiring more research to prove their usefulness in the repair and regeneration of other highly-vascularized vital tissues and organs. This review will cover the latest progress in designing and developing pro-angiogenic electrospun nanofibers and evaluate their usefulness in a tissue engineering and regenerative medicine setting.

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“…To improve hemocompatibility and endothelialization on the surface of cardiovascular implants, significant efforts have been made through surface modifications in three ways-physical, chemical, and biological modifications. [58] Mg alloys Biodegradability, [59] low density, appropriate mechanical properties, vascular implants [60] Co-Cr alloys Nontoxicity, elasticity, corrosion resistance, tissue engineering [37] NiTi alloys Biocompatibility, shape memory and superelasticity, [61] medical devices and implants [62] Naturally derived materials Collagen Biocompatibility, [63] cell adhesion, [ 64,65] cell encapsulation [66] Gelatin Cytocompatibility, cell growth, [ 67,68] cell differentiation and angiogenesis, [69] Chitosan Hemocompatibility, [70] biocompatibility, [71] cell encapsulation [72] Silk fibroin Biocompatibility, compliance, [73] adequate mechanical strength, tissue engineering [ 74,75] Decellularized tissues Biocompatibility, cell proliferation, [76] tissue engineering [77] Synthetic nonbiodegradable materials PTFE Biostability, appropriate mechanical properties, surface modification, [78] clinical reference [79] PU Biocompatibility, elasticity, [75] biostability, tissue engineering [67] PET Adequate mechanical properties, corrosion resistance, Non-toxicity, tissue engineering [80] Synthetic biodegradable materials PCL Biodegradability, biocompatibility, plasticity, [81] vascular devices [82] PLA Biocompatibility, appropriate mechanical properties, [83] tissue engineering [84] PLLA Biostability, adequate mechanical properties, [83] tissue engineering [84] PLGA Biocompatibility, appropriate degradation rate, vascular scaffolds [ 85,…”

Section: Surface Modificationmentioning

confidence: 99%

Surface Engineering of Cardiovascular Devices for Improved Hemocompatibility and Rapid Endothelialization

Zhao

Feng

2020

Adv Healthcare Materials

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Cardiovascular devices have been widely applied in the clinical treatment of cardiovascular diseases. However, poor hemocompatibility and slow endothelialization on their surface still exist. Numerous surface engineering strategies have mainly sought to modify the device surface through physical, chemical, and biological approaches to improve surface hemocompatibility and endothelialization. The alteration of physical characteristics and pattern topographies brings some hopeful outcomes and plays a notable role in this respect. The chemical and biological approaches can provide potential signs of success in the endothelialization of vascular device surfaces. They usually involve therapeutic drugs, specific peptides, adhesive proteins, antibodies, growth factors and nitric oxide (NO) donors. The gene engineering can enhance the proliferation, growth, and migration of vascular cells, thus boosting the endothelialization. In this review, the surface engineering strategies are highlighted and summarized to improve hemocompatibility and rapid endothelialization on the cardiovascular devices. The potential outlook is also briefly discussed to help guide endothelialization strategies and inspire further innovations. It is hoped that this review can assist with the surface engineering of cardiovascular devices and promote future advancements in this emerging research field.

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Polycaprolactone Nanofibers Containing Vascular Endothelial Growth Factor-Encapsulated Gelatin Particles Enhance Mesenchymal Stem Cell Differentiation and Angiogenesis of Endothelial Cells

Cited by 52 publications

References 40 publications

Electrospinning Nanofibers for Therapeutics Delivery

Electrospinning Nanofibers for Therapeutics Delivery

Electrospun Nanofibers for Improved Angiogenesis: Promises for Tissue Engineering Applications

Surface Engineering of Cardiovascular Devices for Improved Hemocompatibility and Rapid Endothelialization

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