1 / 35

Use of Electrical Stimulation to Improve Nerve Regeneration

Use of Electrical Stimulation to Improve Nerve Regeneration. Jan Nguyen, Claudia Wei, Jeff Coursen Hieu Nguyen Group April 2010. Hieu Data Blitz (04.29.2010). Overview: PPy conduit from TDA Fill with hydrogel Embed DRGs EF stimulation. Final semester project. DRG body.

Download Presentation

Use of Electrical Stimulation to Improve Nerve Regeneration

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Use of Electrical Stimulation to Improve Nerve Regeneration Jan Nguyen, Claudia Wei, Jeff Coursen Hieu Nguyen Group April 2010

  2. Hieu Data Blitz (04.29.2010) Overview: PPy conduit from TDA Fill with hydrogel Embed DRGs EF stimulation

  3. Final semester project DRG body

  4. Final semester project Jan DRG body Hydrogel

  5. Final semester project Claudia PPy conduit Jan DRG body Hydrogel

  6. Final semester project Claudia PPy conduit Jan DRG body Hydrogel Electric field Jeff

  7. Hydrogels • Why hydrogels? • Structural rigidity provides contact guidance for cell adhesion & growth • Prevents conduit from collapsing

  8. Hydrogels • Provides 3D scaffold • Representation of body • Allows for testing multiple layers of cells or organs • Medium that serves as drug delivery device • Applications: • Allows DRGs to adhere to surface & not float in media • Test how effective hydrogels are since goal is to have in body

  9. Tested Hydrogels (A): Pure Collagen Matrigel Collagen gel with HEPES Collagen gel with 10x DMEM Collagen / HA hydrogel [1] [2] [3] [4] [5]

  10. Data PC12 cells in collagen hydrogel

  11. Tested Hydrogels (B): • 1. Curt’s hydrogel • Pros: • optimized in Schmidt’s lab to have effect on neurite extension • Can be put in final product  human body • Cons: • our success rate with this hydrogel < matrigel • Hydrogel’s current f(x) is to evaluate cell’s response to EF  type doesn’t matter • 2. Matrigel • Pros: • Know works in vitro b/c our success rate > other hydrogels • Preparing matrigel is not necessary • Cons: • Can’t put into final product  human body

  12. Hydrogels in Conduits • A. Silicone • Used as model with PC 12 cells • B. PLGA from TDA • Used as model with PC 12 cells • C. Ppy from TDA • Used in final project with explanted DRGs PC12 cells with NGF Hydrogel Silicone conduit

  13. Analysis • Cryotome sectioning for imaging • cut thin slices to image cells inside opaque PPy • A. Cryostat Sectioning • i.   fix • ii.  freeze in Isopentane • iii. embed in OTC freezing medium • iv. section at -20C • v. sectioned at 40um and at 160um http://www.chadie.de/cryotomee.jpg http://www.bio.miami.edu/~cmallery/255/255hist/mcb5.43.microtome.jpg

  14. http://images.google.com/imgres?imgurl=http://www.abcam.com/ps/CMS/Images/immuno_staining2.jpg&imgrefurl=http://www.abcam.com/index.htmlhttp://images.google.com/imgres?imgurl=http://www.abcam.com/ps/CMS/Images/immuno_staining2.jpg&imgrefurl=http://www.abcam.com/index.html http://images.google.com/imgres?imgurl=http://www.abcam.com/ps/CMS/Images/immuno_staining2.jpg&imgrefurl=http://www.abcam.com/index.html http://images.google.com/imgres?imgurl=http://www.abcam.com/ps/CMS/Images/immuno_staining2.jpg&imgrefurl=http://www.abcam.com/index.html Analysis • B. Immunostaining • i.  fix with 4% Paraformaldehyde • ii. Wash with PBS • iii. permeabilize with 0.02% TritonX • iv.  block with goat serum • v. stained with primary and secondary antibodies ://www.abcam.com/index.html

  15. Analysis • C. Imaging • Under fluorescent lighting DRG in Ppy conduit

  16. What is PPy? • Polypyrrole is a electrically conducting polymer • Uses • Antistatic Coating • Protective coating for photoelectrochemical cells • Battery • Biomedical Applications • Biosensor • Drug delivery device “Geetha, S. et al. "Biosensing and Drug Delivery by Polypyrrole." Analytica Chimica Acta (2006): 119-25. Web.

  17. Why PPy? • PPy was chosen for this study because it is • Electrically conductive • Easy to synthesize • Flexible • Shown to be biocompatible with mammalian cells • Shown to promote neurite growth • Drawbacks • NOT biodegradable • Fragile and brittle Huang, Yi-Cheng, and Yi-You Huang. "Biomaterials and Strategies for Nerve Regeneration." Artificial Organs 30.7 (2006): 514-22.

  18. Lab Made PPy J.M. Sansiñena, V. Olazábal, T.F. Otero, C.N. Polo da Fonseca, M-A. De Paoli, Chem. Commun., (1997) 2217 • Synthesized on stainless steel • Doped with PSS (oxidative doping) • 0.7 mV at 40 min • Detox methods: prestimulation vs soaking

  19. Detox of Lab Made PPy • Soak • Soak for 1 day in DI water

  20. Detox of Lab Made PPy • Prestimulation • 0.1 mV per cm (0.2 mV total) • 2hours Prestimulation= best method of detoxification

  21. TDA PPy

  22. Endogenous Electric Fields • Transepithelial potential • Break in epithelium allows low resistance pathway for ions • Resulting Electric field: 100-1000 mV cm-1 (Nuccitelli, R. 2003. Endogenous Electric Fields in Embryos During Development, Regeneration, and Wound Healing. Radiation Protection Dosimetry Vol. 106, pp. 375-383)

  23. Role of Endogenous Electric Fields • Development • Wound Healing • Nerve regeneration • Cell migration • Mechanisms? Song, Bing et al. Nerve regeneration and wound healing are stimulated and directed by endogenous electric field in vivo. Journal of Cell Sciences 117 (2004):4681-4690.

  24. Stimulation of PPy in vitro • Electrodes: alligator clips or gold-plated mini-clips • Stimulation: 200 mV for two hours • PPy resistance: 10-40 kΩ • Media (F12K) resistance: 1500 kΩ

  25. Stimulation of Conduits in vivo • Puck is surgically implanted near injury site • Magnetic coil induces current in puck • Electrodes sutured to conduit Confidential. Virginia Technologies Inc.

  26. Using Magnetic Fields Directly • Why? Less invasive • Extended nerve growth found in direction of induced current (Macias Y. Melissa, et al. Directed and Enhanced Nuerite Growth with Pulsed Magnetic Field Stimulation. Bioelectromagnetics 21 (2000):272-286.)

  27. Research Fall 2010 Research Fall 2010: Stimulate rat DRGs in PPy conduit with Hydrogel.

  28. Final semester project Claudia PPy conduit Jan DRG body Hydrogel Electric field Jeff

  29. Experimental setup 0 mV 200 mV level of media DRG PPy conduit 6 uL gel 8 uL gel 6 uL gel

  30. DRG in Matrigel - stimulated DRG extended neurites onto conduit PPy conduit

  31. DRG in Matrigel - control (not stimulated) DRG extended neurites into hydrogel PPy conduit

  32. Tally for neurite extension Columns = where the neurite extended to Rows = type of hydrogel, and EF stimulation of PPy or no stimulation (control)

  33. Quick summary • Matrigel performed better in neurite promotion and structural support (compared to Collagen gel) • Need more samples to draw conclusive data • Do not use cryosectioning in order to preserve gel structure

  34. Literature Cited  1. Song, Bing et al. Nerve regeneration and wound healing are stimulated and directed by endogenous electric field in vivo. Journal of Cell Sciences 117 (2004):4681-4690. 2.Hou, S. "The Repair of Brain Lesion by Implantation of Hyaluronic Acid HydrogelsModified with Laminin." Journal of Neuroscience Methods 148 (2005): 60-70. Web. 3. Kotwal, A., and CE Schmidt. "Electrical stimulation alters protein adsorption and nerve cell interactions with electrically conducting biomaterials." Biomaterials 22 (2001): 1055-064. Print. 4. Macias Y. Melissa, et al. Directed and Enhanced Nuerite Growth with Pulsed Magnetic Field Stimulation. Bioelectromagnetics21 (2000):272-286.) 5. Nuccitelli, R. Endogenous Electric Fields in Embryos During Development, Regeneration, and Wound Healing. Radiation Protection DosimetryVol. 106 (2003): 375-383. 6. Pearson, R. et al. "Spatial Confinement of NeuriteRegrowth from Dorsal Root Ganglia within Nonporous Microconduits." Phillips, J. et al.. "A Self-Organizing Collagen Guidance Conduit." Tissue Engineering 11 (2005). Web. 7. Vernitskaya, T. "Polypyrrole: a Conducting Polymer; Its Synthesis, Properties and Applications." Russian Chemical Reviews 66.5 (1997): 443-57. Web.

  35. Acknowledgements We would like to thank: • Dr. Schmidt- for granting us the opportunity to participate in research • Hyma- for informing us with proper lab safety techniques and procedures • Zin, Jae, Leo, and other grad students- for their wealth of knowledge & advice • Hieu- for taking us under your wings and providing not only bountiful knowledge, but guidance and support in our research endeavors

More Related