The long-term goal of the application is to understand how the central nervous system (CNS) generates sympathetic tone under basal conditions and formulates complex and highly differentiated cardiovascular response patterns characteristic of such behavioral and pathophysiological states as the defense reaction and neurogenic hypertension.
The specific aims of the application are as follows: 1) To define the connections between four groups of cat medullary neurons believed to comprise the basic circuitry responsible for a major component of basal sympathetic nerve discharge (SND) -- the 2- to 6-Hz rhythm. These are sympathoexcitatory (SE) and sympathoinhibitory (SI) neurons of the lateral tegmental field, SE neurons of the rostral ventrolateral medullary reticular formation (RVLM), and SI neurons of the raphe. 2) To test the hypothesis that the axons of bulbospinal neurons innervating the thoracolumbar intermediolateral nucleus (IML) emit collaterals at cervical levels that engage descending propriospinal systems with sympathetic function. Thus, we envision multisynaptic as well as monosynaptic routes to the IML from the brain stem. 3) To determine whether anatomically established reciprocal pathways between the RVLM, dorsolateral pontine complex and the hypothalamus are involved in modulating activity in the basic medullary circuitry responsibly for the 2- to 6-Hz rhythm in SND. If so, the question whether these loops provide positive and/or negative feedback control of RVLM-SE neurons will be investigated. 4) To test the hypothesis that the basal discharges of any given postganglionic sympathetic nerve in the anesthetized cat are derived from multiple central sources rather than from a single anatomically circumscribed generator. As a corollary, the possibility will be examined that the multiple generators of SND are located at both brain stem and diencephalic levels. 5) To test the hypothesis that the brain stem reticular network governing SND is comprised of distinct modules of synaptically interrelated neurons and that each module has a specific output address (e.g., a particular sympathetic nerve). It is further hypothesized that the selective coupling of modules with different output addresses provides the basis for the differential changes in regional blood flow accompanying such behavioral states as the defense reaction. Thus, we envision the sympathetic network in the reticular formation as a polymorphic or highly plastic system capable of formulating a number of discrete output patterns. The electrophysiological techniques used to study these problems in cats include: antidromic mapping of the axonal projections of single central neurons, autocorrelation, microiontophoresis and microstimulation, post-R wave analysis, power density spectral analysis, spike train analysis, unit spike-triggered averaging of SND and central field potentials, and unit- greater than unit crosscorrelation.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Method to Extend Research in Time (MERIT) Award (R37)
Project #
5R37HL013187-26
Application #
2214719
Study Section
Special Emphasis Panel (NSS)
Project Start
1978-12-01
Project End
1997-11-30
Budget Start
1994-12-01
Budget End
1995-11-30
Support Year
26
Fiscal Year
1995
Total Cost
Indirect Cost
Name
Michigan State University
Department
Pharmacology
Type
Schools of Medicine
DUNS #
193247145
City
East Lansing
State
MI
Country
United States
Zip Code
48824
Gebber, Gerard L; Das, Mahasweta; Barman, Susan M (2004) An unusual form of phase walk in a system of coupled oscillators. J Biol Rhythms 19:542-50
Fadel, Paul J; Orer, Hakan S; Barman, Susan M et al. (2004) Fractal properties of human muscle sympathetic nerve activity. Am J Physiol Heart Circ Physiol 286:H1076-87
Das, Mahasweta; Gebber, Gerard L; Barman, Susan M et al. (2003) Fractal properties of sympathetic nerve discharge. J Neurophysiol 89:833-40
Orer, Hakan S; Das, Mahasweta; Barman, Susan M et al. (2003) Fractal activity generated independently by medullary sympathetic premotor and preganglionic sympathetic neurons. J Neurophysiol 90:47-54
Zhou, Shi-Yi; Gebber, Gerard L; Zhong, Sheng et al. (2002) Pathways involved in synchronization of sympathetic nerve discharge to lung inflation. Brain Res 931:107-16
Gebber, G L (2001) A defence-like reaction: an emergent property of a system of coupled non-linear oscillators. Clin Exp Pharmacol Physiol 28:125-9
Larsen, P D; Zhong, S; Gebber, G L et al. (2001) Sympathetic nerve and cardiovascular responses to chemical activation of the midbrain defense region. Am J Physiol Regul Integr Comp Physiol 280:R1704-12
Lewis, C D; Gebber, G L; Larsen, P D et al. (2001) Long-term correlations in the spike trains of medullary sympathetic neurons. J Neurophysiol 85:1614-22
Larsen, P D; Lewis, C D; Gebber, G L et al. (2000) Partial spectral analysis of cardiac-related sympathetic nerve discharge. J Neurophysiol 84:1168-79
Larsen, P D; Zhong, S; Gebber, G L et al. (2000) Differential pattern of spinal sympathetic outflow in response to stimulation of the caudal medullary raphe. Am J Physiol Regul Integr Comp Physiol 279:R210-21

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