Literature DB >> 32939985

Nanochannel-Based Poration Drives Benign and Effective Nonviral Gene Delivery to Peripheral Nerve Tissue.

Jordan T Moore1, Christopher G Wier2, Luke R Lemmerman1, Lilibeth Ortega-Pineda1, Daniel J Dodd3, William R Lawrence3, Silvia Duarte-Sanmiguel1,4, Kavya Dathathreya1, Ludmila Diaz-Starokozheva5, Hallie N Harris6, Chandan K Sen7, Ian L Valerio8, Natalia Higuita-Castro1,5, William David Arnold6, Stephen J Kolb6,9, Daniel Gallego-Perez1,5.   

Abstract

While gene and cell therapies have emerged as promising treatment strategies for various neurological conditions, heavy reliance on viral vectors can hamper widespread clinical implementation. Here, the use of tissue nanotransfection as a platform nanotechnology to drive nonviral gene delivery to nerve tissue via nanochannels, in an effective, controlled, and benign manner is explored. TNT facilitates plasmid DNA delivery to the sciatic nerve of mice in a voltage-dependent manner. Compared to standard bulk electroporation (BEP), impairment in toe-spread and pinprick response is not caused by TNT, and has limited to no impact on electrophysiological parameters. BEP, however, induces significant nerve damage and increases macrophage immunoreactivity. TNT is subsequently used to deliver vasculogenic cell therapies to crushed nerves via delivery of reprogramming factor genes Etv2, Foxc2, and Fli1 (EFF). The results indicate the TNT-based delivery of EFF in a sciatic nerve crush model leads to increased vascularity, reduced macrophage infiltration, and improved recovery in electrophysiological parameters compared to crushed nerves that are TNT-treated with sham/empty plasmids. Altogether, the results indicate that TNT can be a powerful platform nanotechnology for localized nonviral gene delivery to nerve tissue, in vivo, and the deployment of reprogramming-based cell therapies for nerve repair/regeneration.
© 2020 Wiley-VCH GmbH.

Entities:  

Keywords:  nonviral gene delivery; peripheral nerve; tissue nanotransfection

Year:  2020        PMID: 32939985      PMCID: PMC7704786          DOI: 10.1002/adbi.202000157

Source DB:  PubMed          Journal:  Adv Biosyst        ISSN: 2366-7478


  69 in total

1.  An oligovascular niche: cerebral endothelial cells promote the survival and proliferation of oligodendrocyte precursor cells.

Authors:  Ken Arai; Eng H Lo
Journal:  J Neurosci       Date:  2009-04-08       Impact factor: 6.167

2.  The role of cultured Schwann cell grafts in the repair of gaps within the peripheral nervous system of primates.

Authors:  A D Levi; V K Sonntag; C Dickman; J Mather; R H Li; S C Cordoba; B Bichard; M Berens
Journal:  Exp Neurol       Date:  1997-01       Impact factor: 5.330

Review 3.  The complex and evolving story of T cell activation to AAV vector-encoded transgene products.

Authors:  Lauren E Mays; James M Wilson
Journal:  Mol Ther       Date:  2010-11-30       Impact factor: 11.454

4.  Dual angiogenic and neurotrophic effects of bone marrow-derived endothelial progenitor cells on diabetic neuropathy.

Authors:  Jin-Ok Jeong; Mee-Ohk Kim; Hyongbum Kim; Min-Young Lee; Sung-Whan Kim; Masaaki Ii; Jung-uek Lee; Jiyoon Lee; Yong Jin Choi; Hyun-Jai Cho; Namho Lee; Marcy Silver; Andrea Wecker; Dong-Wook Kim; Young-sup Yoon
Journal:  Circulation       Date:  2009-01-26       Impact factor: 29.690

Review 5.  Steps toward safe cell therapy using induced pluripotent stem cells.

Authors:  Hideyuki Okano; Masaya Nakamura; Kenji Yoshida; Yohei Okada; Osahiko Tsuji; Satoshi Nori; Eiji Ikeda; Shinya Yamanaka; Kyoko Miura
Journal:  Circ Res       Date:  2013-02-01       Impact factor: 17.367

6.  The functional characteristics of Schwann cells cultured from human peripheral nerve after transplantation into a gap within the rat sciatic nerve.

Authors:  A D Levi; V Guénard; P Aebischer; R P Bunge
Journal:  J Neurosci       Date:  1994-03       Impact factor: 6.167

7.  Macrophage-Induced Blood Vessels Guide Schwann Cell-Mediated Regeneration of Peripheral Nerves.

Authors:  Anne-Laure Cattin; Jemima J Burden; Lucie Van Emmenis; Francesca E Mackenzie; Julian J A Hoving; Noelia Garcia Calavia; Yanping Guo; Maeve McLaughlin; Laura H Rosenberg; Victor Quereda; Denisa Jamecna; Ilaria Napoli; Simona Parrinello; Tariq Enver; Christiana Ruhrberg; Alison C Lloyd
Journal:  Cell       Date:  2015-08-13       Impact factor: 41.582

Review 8.  Pathophysiological Changes of Physical Barriers of Peripheral Nerves After Injury.

Authors:  Qianyan Liu; Xinghui Wang; Sheng Yi
Journal:  Front Neurosci       Date:  2018-08-23       Impact factor: 4.677

Review 9.  Nerve growth factor and diabetic neuropathy.

Authors:  Gary Pittenger; Aaron Vinik
Journal:  Exp Diabesity Res       Date:  2003 Oct-Dec

Review 10.  Barriers of the peripheral nerve.

Authors:  Sirkku Peltonen; Maria Alanne; Juha Peltonen
Journal:  Tissue Barriers       Date:  2013-05-30
View more
  6 in total

Review 1.  Nanotechnology-Driven Cell-Based Therapies in Regenerative Medicine.

Authors:  D Alzate-Correa; W R Lawrence; A Salazar-Puerta; N Higuita-Castro; D Gallego-Perez
Journal:  AAPS J       Date:  2022-03-15       Impact factor: 3.603

2.  Designer Extracellular Vesicles Modulate Pro-Neuronal Cell Responses and Improve Intracranial Retention.

Authors:  Lilibeth Ortega-Pineda; Alec Sunyecz; Ana I Salazar-Puerta; Maria Angelica Rincon-Benavides; Diego Alzate-Correa; Amrita Lakshmi Anaparthi; Elizabeth Guilfoyle; Louisa Mezache; Heather L Struckman; Silvia Duarte-Sanmiguel; Binbin Deng; David W McComb; Daniel J Dodd; William R Lawrence; Jordan Moore; Jingjing Zhang; Eduardo Reátegui; Rengasayee Veeraraghavan; M Tyler Nelson; Daniel Gallego-Perez; Natalia Higuita-Castro
Journal:  Adv Healthc Mater       Date:  2022-01-21       Impact factor: 11.092

Review 3.  Fabrication and use of silicon hollow-needle arrays to achieve tissue nanotransfection in mouse tissue in vivo.

Authors:  Yi Xuan; Subhadip Ghatak; Andrew Clark; Zhigang Li; Savita Khanna; Dongmin Pak; Mangilal Agarwal; Sashwati Roy; Peter Duda; Chandan K Sen
Journal:  Nat Protoc       Date:  2021-11-26       Impact factor: 17.021

4.  Myogenic tissue nanotransfection improves muscle torque recovery following volumetric muscle loss.

Authors:  Andrew Clark; Subhadip Ghatak; Poornachander Reddy Guda; Mohamed S El Masry; Yi Xuan; Amy Y Sato; Teresita Bellido; Chandan K Sen
Journal:  NPJ Regen Med       Date:  2022-10-20

5.  A Murine Tail Lymphedema Model.

Authors:  Aladdin H Hassanein; Mithun Sinha; Colby R Neumann; Ganesh Mohan; Imran Khan; Chandan K Sen
Journal:  J Vis Exp       Date:  2021-02-10       Impact factor: 1.355

6.  Nanotransfection-based vasculogenic cell reprogramming drives functional recovery in a mouse model of ischemic stroke.

Authors:  Luke R Lemmerman; Maria H H Balch; Jordan T Moore; Diego Alzate-Correa; Maria A Rincon-Benavides; Ana Salazar-Puerta; Surya Gnyawali; Hallie N Harris; William Lawrence; Lilibeth Ortega-Pineda; Lauren Wilch; Ian B Risser; Aidan J Maxwell; Silvia Duarte-Sanmiguel; Daniel Dodd; Gina P Guio-Vega; Dana M McTigue; W David Arnold; Shahid M Nimjee; Chandan K Sen; Savita Khanna; Cameron Rink; Natalia Higuita-Castro; Daniel Gallego-Perez
Journal:  Sci Adv       Date:  2021-03-19       Impact factor: 14.136
  6 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.