Gold nanoparticle-filled biodegradable photopolymer scaffolds induced muscle remodeling: in vitro and in vivo findings.

Therapeutic stem cell transplantation bears the promise of new directions in organ and tissue replacement, but a number of its difficulties and perils are also well known. Our goal was to develop a method of transplantation by which the transplanted cells remain confined to the transplantation site and induce favorable processes. With the help of mask-projection excimer laser stereolithography, 3D hybrid nanoscaffolds were fabricated from biodegradable, photocurable PPF:DEF resin with incorporated gold nanoparticles (Au NPs). The scaffolds were tested in vitro and in vivo in order to find out about their biocompatibility and fitness for our purposes. In vitro, macrophages and mouse autologous adipose stem cells (ASCs) were seeded over the hybrid scaffolds and non-hybrid (with Au NPs) scaffolds for 4days. The hybrid nanocomposite greater stem cell dispension and stem cell adhesion than PPF scaffolds without Au NPs, but such a difference was not seen in the case of macrophages. In vivo, stem cells, scaffoldings and scaffoldings covered in stem cells were transplanted under the back skin of mice. After 14days, blood samples were taken and the affected skin area was excised. Cytokine and chemokine profiling did not indicate elevated immunomediators in the sera of experimental animals. Interestingly, the autologous-stem-cell-seeded hybrid nanocomposite scaffold induced muscle tissue regeneration after experimental wound generation in vivo. We could not observe such stem cell-induced tissue regeneration when no scaffolding was used. We conclude that PPF:DEF resin nanoscaffolds with incorporated gold nanoparticles offer a safe and efficient alternative for the enhancement of local tissue remodeling. The results also support the idea that adipose derived stem cells are an optimal cell type for the purposes of regenerative musculoskeletal tissue engineering.

[1]  Alberto Diaspro,et al.  Rapid fabrication of rigid biodegradable scaffolds by excimer laser mask projection technique: a comparison between 248 and 308?nm , 2013 .

[2]  D. Saris,et al.  Autologous, allogeneic, induced pluripotent stem cell or a combination stem cell therapy? Where are we headed in cartilage repair and why: a concise review , 2015, Stem Cell Research & Therapy.

[3]  Han-Tsung Liao,et al.  Osteogenic potential: Comparison between bone marrow and adipose-derived mesenchymal stem cells. , 2014, World journal of stem cells.

[4]  A. Diaspro,et al.  Fabrication of hybrid nanocomposite scaffolds by incorporating ligand-free hydroxyapatite nanoparticles into biodegradable polymer scaffolds and release studies , 2015, Beilstein journal of nanotechnology.

[5]  I. Romano,et al.  3D scaffold fabrication by mask projection excimer laser stereolithography , 2014 .

[6]  A. Diaspro,et al.  Nanocomposite scaffold fabrication by incorporating gold nanoparticles into biodegradable polymer matrix: Synthesis, characterization, and photothermal effect. , 2015, Materials science & engineering. C, Materials for biological applications.

[7]  G. Pins,et al.  Biomimetic scaffolds for regeneration of volumetric muscle loss in skeletal muscle injuries. , 2015, Acta biomaterialia.

[8]  Rosa Akbarzadeh,et al.  Prospect of Stem Cells in Bone Tissue Engineering: A Review , 2016, Stem cells international.

[9]  L. Ceseracciu,et al.  Four-order stiffness variation of laser-fabricated photopolymer biodegradable scaffolds by laser parameter modulation. , 2015, Materials science & engineering. C, Materials for biological applications.

[10]  P. Kingham,et al.  Peripheral nerve regeneration: experimental strategies and future perspectives. , 2015, Advanced drug delivery reviews.

[11]  A. Schnerch,et al.  Characterization of human embryonic stem cells with features of neoplastic progression , 2009, Nature Biotechnology.

[12]  D. Cho,et al.  Bone regeneration using a microstereolithography-produced customized poly(propylene fumarate)/diethyl fumarate photopolymer 3D scaffold incorporating BMP-2 loaded PLGA microspheres. , 2011, Biomaterials.

[13]  G. Subramanian,et al.  Mechanoresponsive musculoskeletal tissue differentiation of adipose-derived stem cells , 2016, Biomedical engineering online.

[14]  K. Hörmann,et al.  Advances in skeletal muscle tissue engineering. , 2007, In vivo.

[15]  A. Rogers,et al.  Stem cells and cancer: evidence for bone marrow stem cells in epithelial cancers. , 2006, World journal of gastroenterology.

[16]  Dong-Woo Cho,et al.  Development of 3D PPF/DEF scaffolds using micro-stereolithography and surface modification , 2009, Journal of materials science. Materials in medicine.

[17]  Excimer laser-produced biodegradable photopolymer scaffolds do not induce immune rejection in vivo , 2015 .

[18]  J. Corcos,et al.  Bladder tissue engineering: a literature review. , 2015, Advanced drug delivery reviews.

[19]  J. Vacanti,et al.  Tissue engineering : Frontiers in biotechnology , 1993 .

[20]  G. Mancardi,et al.  Autologous hematopoietic stem cell transplantation in multiple sclerosis: 20 years of experience , 2016, Neurological Sciences.

[21]  L. Ceseracciu,et al.  Towards excimer-laser-based stereolithography: a rapid process to fabricate rigid biodegradable photopolymer scaffolds , 2012, Journal of The Royal Society Interface.

[22]  Valeria Chiono,et al.  Trends in the design of nerve guidance channels in peripheral nerve tissue engineering , 2015, Progress in Neurobiology.