publication . Article . Review . Other literature type . 2018

Designs of Biomaterials and Microenvironments for Neuroengineering.

Yang, Yanru; Zhang, Yuhua; Chai, Renjie; Gu, Zhongze;
Open Access
  • Published: 09 Dec 2018 Journal: Neural Plasticity, volume 2,018, pages 1-10 (issn: 2090-5904, eissn: 1687-5443, Copyright policy)
  • Publisher: Hindawi Limited
Abstract
<jats:p>Recent clinical research on neuroengineering is primarily focused on biocompatible materials, which can be used to provide electroactive and topological cues, regulate the microenvironment, and perform other functions. Novel biomaterials for neuroengineering have been received much attention in the field of research, including graphene, photonic crystals, and organ-on-a-chip. Graphene, which has the advantage of high mechanical strength and chemical stability with the unique electrochemical performance for electrical signal detection and transmission, has significant potential as a conductive scaffolding in the field of medicine. Photonic crystal materia...
Subjects
free text keywords: Review Article, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Article Subject
Related Organizations
92 references, page 1 of 7

Schmidt, C. E., Leach, J. B.. Neural tissue engineering: strategies for repair and regeneration. Annual Review of Biomedical Engineering . 2003; 5 (1): 293-347 [OpenAIRE] [] [DOI]

Millet, L. J., Gillette, M. U.. Over a century of neuron culture: from the hanging drop to microfluidic devices. Yale Journal of Biology and Medicine . 2012; 85 (4): 501-521 [OpenAIRE] [PubMed]

Dalamagkas, K., Tsintou, M., Seifalian, A.. Advances in peripheral nervous system regenerative therapeutic strategies: a biomaterials approach. Materials Science and Engineering: C . 2016; 65: 425-432 [OpenAIRE] [PubMed] [] [DOI]

Xu, X. Y., Li, X. T., Peng, S. W.. The behaviour of neural stem cells on polyhydroxyalkanoate nanofiber scaffolds. Biomaterials . 2010; 31 (14): 3967-3975 [OpenAIRE] [PubMed] [] [DOI]

Gu, Y., Zhu, J., Xue, C.. Chitosan/silk fibroin-based, Schwann cell-derived extracellular matrix-modified scaffolds for bridging rat sciatic nerve gaps. Biomaterials . 2014; 35 (7): 2253-2263 [OpenAIRE] [PubMed] [] [DOI]

Yang, F., Murugan, R., Ramakrishna, S., Wang, X., Ma, Y. X., Wang, S.. Fabrication of nano-structured porous PLLA scaffold intended for nerve tissue engineering. Biomaterials . 2004; 25 (10): 1891-1900 [OpenAIRE] [PubMed] [] [DOI]

Xiao, Z., Tang, F., Tang, J.. One-year clinical study of NeuroRegen scaffold implantation following scar resection in complete chronic spinal cord injury patients. Science China Life Sciences . 2016; 59 (7): 647-655 [OpenAIRE] [PubMed] [] [DOI]

Kim, W. R., Jang, M. J., Joo, S., Sun, W., Nam, Y.. Surface-printed microdot array chips for the quantification of axonal collateral branching of a single neuron in vitro. Lab on a Chip . 2014; 14 (4): 799-805 [PubMed] [] [DOI]

Cogan, S. F.. Neural stimulation and recording electrodes. Annual Review of Biomedical Engineering . 2008; 10 (1): 275-309 [OpenAIRE] [] [DOI]

Kotwal, A., Schmidt, C. E.. Electrical stimulation alters protein adsorption and nerve cell interactions with electrically conducting biomaterials. Biomaterials . 2001; 22 (10): 1055-1064 [OpenAIRE] [PubMed] [] [DOI]

Ghasemi-Mobarakeh, L., Prabhakaran, M. P., Morshed, M., Nasr-Esfahani, M. H., Ramakrishna, S.. Electrical stimulation of nerve cells using conductive nanofibrous scaffolds for nerve tissue engineering. Tissue Engineering Part A . 2009; 15 (11): 3605-3619 [OpenAIRE] [PubMed] [] [DOI]

Thunberg, J., Kalogeropoulos, T., Kuzmenko, V.. In situ synthesis of conductive polypyrrole on electrospun cellulose nanofibers: scaffold for neural tissue engineering. Cellulose . 2015; 22 (3): 1459-1467 [OpenAIRE] [] [DOI]

Aregueta-Robles, U. A., Woolley, A. J., Poole-Warren, L. A., Lovell, N. H., Green, R. A.. Organic electrode coatings for next-generation neural interfaces. Frontiers in Neuroengineering . 2014; 7: 15-15 [OpenAIRE] [PubMed] [] [DOI]

Baniasadi, H., Ahmad Ramazani, S. A., Mashayekhan, S.. Fabrication and characterization of conductive chitosan/gelatin-based scaffolds for nerve tissue engineering. International Journal of Biological Macromolecules . 2015; 74: 360-366 [OpenAIRE] [PubMed] [] [DOI]

Geim, A. K.. Graphene: status and prospects. Science . 2009; 324 (5934): 1530-1534 [OpenAIRE] [PubMed] [] [DOI]

92 references, page 1 of 7
Abstract
<jats:p>Recent clinical research on neuroengineering is primarily focused on biocompatible materials, which can be used to provide electroactive and topological cues, regulate the microenvironment, and perform other functions. Novel biomaterials for neuroengineering have been received much attention in the field of research, including graphene, photonic crystals, and organ-on-a-chip. Graphene, which has the advantage of high mechanical strength and chemical stability with the unique electrochemical performance for electrical signal detection and transmission, has significant potential as a conductive scaffolding in the field of medicine. Photonic crystal materia...
Subjects
free text keywords: Review Article, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Article Subject
Related Organizations
92 references, page 1 of 7

Schmidt, C. E., Leach, J. B.. Neural tissue engineering: strategies for repair and regeneration. Annual Review of Biomedical Engineering . 2003; 5 (1): 293-347 [OpenAIRE] [] [DOI]

Millet, L. J., Gillette, M. U.. Over a century of neuron culture: from the hanging drop to microfluidic devices. Yale Journal of Biology and Medicine . 2012; 85 (4): 501-521 [OpenAIRE] [PubMed]

Dalamagkas, K., Tsintou, M., Seifalian, A.. Advances in peripheral nervous system regenerative therapeutic strategies: a biomaterials approach. Materials Science and Engineering: C . 2016; 65: 425-432 [OpenAIRE] [PubMed] [] [DOI]

Xu, X. Y., Li, X. T., Peng, S. W.. The behaviour of neural stem cells on polyhydroxyalkanoate nanofiber scaffolds. Biomaterials . 2010; 31 (14): 3967-3975 [OpenAIRE] [PubMed] [] [DOI]

Gu, Y., Zhu, J., Xue, C.. Chitosan/silk fibroin-based, Schwann cell-derived extracellular matrix-modified scaffolds for bridging rat sciatic nerve gaps. Biomaterials . 2014; 35 (7): 2253-2263 [OpenAIRE] [PubMed] [] [DOI]

Yang, F., Murugan, R., Ramakrishna, S., Wang, X., Ma, Y. X., Wang, S.. Fabrication of nano-structured porous PLLA scaffold intended for nerve tissue engineering. Biomaterials . 2004; 25 (10): 1891-1900 [OpenAIRE] [PubMed] [] [DOI]

Xiao, Z., Tang, F., Tang, J.. One-year clinical study of NeuroRegen scaffold implantation following scar resection in complete chronic spinal cord injury patients. Science China Life Sciences . 2016; 59 (7): 647-655 [OpenAIRE] [PubMed] [] [DOI]

Kim, W. R., Jang, M. J., Joo, S., Sun, W., Nam, Y.. Surface-printed microdot array chips for the quantification of axonal collateral branching of a single neuron in vitro. Lab on a Chip . 2014; 14 (4): 799-805 [PubMed] [] [DOI]

Cogan, S. F.. Neural stimulation and recording electrodes. Annual Review of Biomedical Engineering . 2008; 10 (1): 275-309 [OpenAIRE] [] [DOI]

Kotwal, A., Schmidt, C. E.. Electrical stimulation alters protein adsorption and nerve cell interactions with electrically conducting biomaterials. Biomaterials . 2001; 22 (10): 1055-1064 [OpenAIRE] [PubMed] [] [DOI]

Ghasemi-Mobarakeh, L., Prabhakaran, M. P., Morshed, M., Nasr-Esfahani, M. H., Ramakrishna, S.. Electrical stimulation of nerve cells using conductive nanofibrous scaffolds for nerve tissue engineering. Tissue Engineering Part A . 2009; 15 (11): 3605-3619 [OpenAIRE] [PubMed] [] [DOI]

Thunberg, J., Kalogeropoulos, T., Kuzmenko, V.. In situ synthesis of conductive polypyrrole on electrospun cellulose nanofibers: scaffold for neural tissue engineering. Cellulose . 2015; 22 (3): 1459-1467 [OpenAIRE] [] [DOI]

Aregueta-Robles, U. A., Woolley, A. J., Poole-Warren, L. A., Lovell, N. H., Green, R. A.. Organic electrode coatings for next-generation neural interfaces. Frontiers in Neuroengineering . 2014; 7: 15-15 [OpenAIRE] [PubMed] [] [DOI]

Baniasadi, H., Ahmad Ramazani, S. A., Mashayekhan, S.. Fabrication and characterization of conductive chitosan/gelatin-based scaffolds for nerve tissue engineering. International Journal of Biological Macromolecules . 2015; 74: 360-366 [OpenAIRE] [PubMed] [] [DOI]

Geim, A. K.. Graphene: status and prospects. Science . 2009; 324 (5934): 1530-1534 [OpenAIRE] [PubMed] [] [DOI]

92 references, page 1 of 7
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