Abstract

The objectives of the studies outlined are to establish the role of specific endogenous opioid peptides in the pathophysiology of hemorrhagic shock and to facilitate the development of improved therapeutic approaches to shock and trauma. Preliminary studies from this laboratory have demonstrated that endogenous opioids, including the dynorphin/kappa-receptor system, may be involved in the regulation of cardiovascular function during shock. We propose to use newly available technology to elucidate the mechanism by which specific opioid systems mediate cardiovascular dysfunction during hemorrhagic shock. In the proposed studies, the role of specific opioid peptides (particularly dynorphin) and opioid receptors will be examined with regard to the pathophysiology of acute hemorrhagic shock in the rat. Plasma concentrations of opioid peptides and catecholamines will be determined before and after the induction of shock. Changes in brain opiate receptor binding sites and brain opiate immunoreactivity will be measured in specific regions associated with cardiovascular regulation from control and injured animals in order to examine the effects of shock on regional peptide concentrations and opioid receptor distribution. """"""""Micropunch"""""""" techniques will also be employed to examine opioid immunoreactivity and receptor changes in important central cardiovascular nuclei which may mediate the compensatory or decompensatory response to shock. Post-shock changes in plasma opioid concentration, central nervous system opiate immunoreactivity and receptor distribution will be related to alterations in mean arterial pressure, cardiac output/stroke volume and regional blood flow to specific peripheral vascular beds. To further determine whether dynorphin and/or the kappa- opiate receptor contribute to the sequelae of shock, we will evaluate whether centrally administered kappa-opioid receptor agonists exacerbate the physiological response to shock. Finally, the therapeutic efficacy of two novel opioid antagonists nalmefine and WIN44,441-3 (which have increased activity at kappa sites) will be evaluated and compared to that of naloxone in hemorrhagic shock. Taken together, these proposed studies will enhance our understanding of the pathophysiological mechanisms that underlie hypotension and low-flow states that accompany shock and trauma and may result in the development of new and more effective therapeutic approaches to the treatment of hemorrhagic shock.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
2R01GM034690-02A1
Application #
3286109
Study Section
Surgery, Anesthesiology and Trauma Study Section (SAT)
Project Start
1984-09-01
Project End
1989-11-30
Budget Start
1986-12-01
Budget End
1987-11-30
Support Year
2
Fiscal Year
1987
Total Cost
Indirect Cost

  Institution

Name
University of California San Francisco
Department
Type
Schools of Medicine
DUNS #
073133571
City
San Francisco
State
CA
Country
United States
Zip Code
94143

  Publications

Tomasevic, Gregor; Laurer, Helmut L; Mattiasson, Gustav et al. (2012) Delayed neuromotor recovery and increased memory acquisition dysfunction following experimental brain trauma in mice lacking the DNA repair gene XPA. J Neurosurg 116:1368-78
Tomasevic, Gregor; Raghupathi, Ramesh; Scherbel, Uwe et al. (2010) Deletion of the p53 tumor suppressor gene improves neuromotor function but does not attenuate regional neuronal cell loss following experimental brain trauma in mice. J Neurosci Res 88:3414-23
Conte, Valeria; Raghupathi, Ramesh; Watson, Deborah J et al. (2008) TrkB gene transfer does not alter hippocampal neuronal loss and cognitive deficits following traumatic brain injury in mice. Restor Neurol Neurosci 26:45-56
Schutz, Christian; Stover, John F; Thompson, Hilaire J et al. (2006) Acute, transient hemorrhagic hypotension does not aggravate structural damage or neurologic motor deficits but delays the long-term cognitive recovery following mild to moderate traumatic brain injury. Crit Care Med 34:492-501
Lifshitz, Jonathan; Janmey, Paul A; McIntosh, Tracy K (2006) Photon correlation spectroscopy of brain mitochondrial populations: application to traumatic brain injury. Exp Neurol 197:318-29
Thompson, Hilaire J; Hoover, Rachel C; Tkacs, Nancy C et al. (2005) Development of posttraumatic hyperthermia after traumatic brain injury in rats is associated with increased periventricular inflammation. J Cereb Blood Flow Metab 25:163-76
Zhang, Chen; Saatman, Kathryn E; Royo, Nicolas C et al. (2005) Delayed transplantation of human neurons following brain injury in rats: a long-term graft survival and behavior study. J Neurotrauma 22:1456-74
Lenzlinger, P M; Shimizu, S; Marklund, N et al. (2005) Delayed inhibition of Nogo-A does not alter injury-induced axonal sprouting but enhances recovery of cognitive function following experimental traumatic brain injury in rats. Neuroscience 134:1047-56
Boockvar, John A; Schouten, Joost; Royo, Nicolas et al. (2005) Experimental traumatic brain injury modulates the survival, migration, and terminal phenotype of transplanted epidermal growth factor receptor-activated neural stem cells. Neurosurgery 56:163-71; discussion 171
Conte, Valeria; Uryu, Kunihiro; Fujimoto, Scott et al. (2004) Vitamin E reduces amyloidosis and improves cognitive function in Tg2576 mice following repetitive concussive brain injury. J Neurochem 90:758-64

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