Registration for a live webinar on 'Precision medicine treatment for anticancer drug resistance' is now open.
See webinar detailsWe noted you are experiencing viewing problems
-
Check with your IT department that JWPlatform, JWPlayer and Amazon AWS & CloudFront are not being blocked by your network. The relevant domains are *.jwplatform.com, *.jwpsrv.com, *.jwpcdn.com, jwpltx.com, jwpsrv.a.ssl.fastly.net, *.amazonaws.com and *.cloudfront.net. The relevant ports are 80 and 443.
-
Check the following talk links to see which ones work correctly:
Auto Mode
HTTP Progressive Download Send us your results from the above test links at access@hstalks.com and we will contact you with further advice on troubleshooting your viewing problems. -
No luck yet? More tips for troubleshooting viewing issues
-
Contact HST Support access@hstalks.com
-
Please review our troubleshooting guide for tips and advice on resolving your viewing problems.
-
For additional help, please don't hesitate to contact HST support access@hstalks.com
We hope you have enjoyed this limited-length demo
This is a limited length demo talk; you may
login or
review methods of
obtaining more access.
- View the Talks
-
1. Traumatic brain injury: from the ball field to the battlefield
- Prof. Alan Faden
-
2. Avoiding missed diagnosis of mild traumatic brain injury
- Dr. John Bedolla
-
3. Basic mechanisms of spinal cord injury (SCI)
- Prof. Edward D. Hall
-
4. Neuroinflammation and spinal cord injury
- Prof. Phillip Popovich
-
6. Experimental approaches to developing and evaluating novel treatments for TBI and SCI
- Prof. W. Dalton Dietrich
-
7. The treatment of spinal cord injury: past, present and future
- Prof. James Fawcett
-
9. Promoting neuroplasticity for functional restoration after SCI
- Prof. Edelle Field-Fote
-
10. Physical rehabilitation after spinal cord injury: maximizing function
- Prof. Jennifer Hastings
-
11. Therapies for spinal cord injury: perspective from industry
- Dr. Andrew Blight
-
12. Spinal cord injury: some reflections on living with tetraplegia
- Prof. Jonathan Cole
-
13. Coping beyond adversity: living with a spinal cord injury
- Mr. Gary Allsop
-
14. Identifying the trauma footprint of acquired brain injury
- Dr. Christine Durham
-
15. Acquiring better insight into what it's like to have acquired brain injury
- Dr. Christine Durham
-
16. Molecular imaging in epilepsy
- Prof. Matthias Koepp
-
18. Rehabilitation of military related neurotrauma
- Dr. Michael Yochelson
-
19. Spinal cord injury in natural disasters
- Prof. Colleen O'Connell
Printable Handouts
Navigable Slide Index
- Introduction
- Neurotrauma topics
- Brain and spinal cord injury research
- Bench to bedside/bedside to bench research
- Therapeutic opportunities
- TBI epidemiology
- Primary injury
- Brain after TBI (1)
- Brain after TBI (2)
- Secondary insults
- Types of secondary injury mechanisms
- Types of brain injury
- Types of preclinical animal models of TBI
- Weight drop model
- Impact acceleration model (Marmarou device)
- Controlled cortical impact (CCI)
- Fluid-percussion brain injury
- Blast injury model
- Induction of traumatic brain injury
- TBI pathology
- Lack of treatments
- Therapeutic hypothermia
- History of hypothermia
- Treatment with induced hypothermia
- Whole-body hypothermia for neonates
- Does moderate hypothermia protect in TBI?
- Neuronal cell death/contusion
- Glutamate levels affected by hypothermia
- Post traumatic inflammation
- Temperature mechanisms in ischemia and trauma
- Fever in the neuro ICU
- Temperature changes following TBI
- Hyperthermia affects mortality/contusion volume
- Spectrum of brain trauma heterogeneous injury
- Therapeutic hypothermia
- Morris water maze
- Hypothermia therapy improves cognition after TBI
- Protein kinases involved in learning and memory
- Drugs tested to improve cognition
- Posttraumatic epilepsy
- Hippocampus staining from epileptic patient
- Mossy fiber sprouting
- Hypothermia reduces seizure susceptibility
- Hypothermia attenuates axonal sprouting
- Trials conducted using hypothermia after TBI
- Long/short term hypothermia after TBI
- Questions regarding therapeutic hypothermia
- Progesterone clinical trials
- Spinal cord injury
- MRI images in rodents, porcine and man
- Diffusion tensor imaging
- SCI epidemiology
- Pathophysiology of acute spinal cord injury
- CT scan of extreme SCI
- Acute SCI - secondary injury mechanisms
- Cellular events that occur after SCI
- Cytoprotection
- Neuroprotective agents
- NASCIS III studies
- Sygen (GM-1 Ganglioside) summary of findings
- Promising treatments targeting CNS injury
- Confirming experimental therapies
- The history of hypothermia for SCI
- Effects of SC cooling in experimental SC trauma
- Spinal cord modest hypothermia
- Is modest hypothermia protective in SCI
- Thoracic injury
- Clinical protocols for therapeutic hypothermia
- Hypothermia and human SCI
- Research protocol at UMMSM/JMH
- Application of modest hypothermia after SCI
- Cooling profile of SCI patient
- ASIA impairment scale
- Modest intravascular hypothermia after SCI
- Clinical trials to test the novel therapy
- Acute rapid cooling therapy for SCI
- Repairing the spinal cord after injury
- The complicated nature of SCI
- Regeneration obstacles and strategies
- Using helper cells to promote regeneration
- Cell therapy
- The potential use of Schwann cells
- Advantages of Schwann cells in SCI
- A Schwann cell bridge
- Schwann cells transplanted into an injured site
- Schwann cells bridge plus ensheathing glia
- Triple therapy - Schwann cell, Rolipram, cAMP
- Elevating cAMP promotes axonal growth
- Schwann cell therapy in clinical trials
- Proposed human Schwann cell clinical trial
- Trial parameters
- Technical milestones for human Schwann cell trial
- Stem cells as therapy in SCI - timeline
- Embryonic stem cell-derived oligodendrocyte
- FDA approves GRNOPC1 IND first patient treated
- Allodynia after neural stem cell transplantation
- Stem cell therapy triggers tumor formation
- Promoting regeneration
- Growth promoting factors
- Regenerating axons face two major barriers
- Inhibitory CNS environment
- Innovative technologies
- Automated microscope for phenotypic screening
- High content screening in primary neurons
- Chemical library
- Automated analysis of neurons and processes
- The microscope looks at many types of fields
- Large scale screens
- KLFs and axon regeneration
- Most of the KLFs affect axon growth
- KLF4 KO leads to increased axon regeneration
- Various clinical research programs
- Conditioning approaches
- Cardiovascular and robotic training
- Manual rehabilitation approaches
- Combination therapy
- Summary
- The Miami Project faculty
- Thank you
Topics Covered
- Brain and spinal cord trauma
- Epidemiology of the clinical condition
- Animal modeling approaches
- Pathophysiological mechanisms of CNS injury
- Clinically relevant outcome measures
- Neuropathology
- Behavioral outcomes
- Clinical trials
- Novel treatments
Talk Citation
Dietrich, W.D. (2011, November 23). Experimental approaches to developing and evaluating novel treatments for TBI and SCI [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 30, 2024, from https://doi.org/10.69645/VCQD1874.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. W. Dalton Dietrich has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
Experimental approaches to developing and evaluating novel treatments for TBI and SCI
Published on November 23, 2011
52 min
A selection of talks on Neuroscience
Hide