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Departments of Medicine (Cardiology) and Cellular and Molecular Physiology, General Clinical Research Center, Pennsylvania State University College of Medicine, The Milton S. Hershey Medical Center, Hershey, Pennsylvania 17033
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Aging attenuates the increase in muscle
sympathetic nerve activity (MSNA) and elicits hypotension during
otolith organ engagement in humans. The purpose of the present study
was to determine the neural and cardiovascular responses to otolithic
engagement during orthostatic stress in older adults. We hypothesized
that age-related impairments in the vestibulosympathetic reflex would
persist during orthostatic challenge in older subjects and might
compromise arterial blood pressure regulation. MSNA, arterial blood
pressure, and heart rate responses to head-down rotation (HDR)
performed with and without lower body negative pressure (LBNP) in prone
subjects were measured. Ten young (27 ± 1 yr) and 11 older
subjects (64 ± 1 yr) were studied prospectively. HDR performed
alone elicited an attenuated increase in MSNA in older subjects
(
106 ± 28 vs. 20 ± 7% for young and older subjects).
HDR performed during simultaneous orthostatic stress increased total
MSNA further in young (53 ± 15%; P < 0.05)
but not older subjects (
5 ± 4%). Older subjects demonstrated consistent significant hypotension during HDR performed both alone (6 ± 2 mmHg) and during LBNP (7 ± 2 mmHg). These data provide experimental support for the concept that
age-related impairments in the vestibulosympathetic reflex persist
during orthostatic challenge in older adults. Furthermore, these
findings are consistent with the concept that age-related alterations
in vestibular function might contribute to altered orthostatic blood pressure regulation with age in humans.
vestibular; blood pressure regulation; orthostasis; baroreflex; autonomic nervous system
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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ASSUMPTION OF THE UPRIGHT posture initiates reflex-mediated increases in vasoconstrictor muscle sympathetic nerve activity (MSNA) (3). Failure to increase MSNA and vascular resistance in the face of gravitationally induced peripheral venous pooling and translocation of central blood volume produces hypotension and compromises vital organ perfusion (2, 24). Accordingly, reflexive modulators of MSNA activated during orthostatic stress are of physiological and clinical significance.
An extensive body of experimental literature has accumulated examining baroreflex-mediated increases in MSNA during orthostatic stress in humans under varying and diverse physiological conditions (3, 4, 22, 25, 27, 32). In patients with autonomic failure, who demonstrate a diminished ability to increase peripheral vascular resistance during baroreceptor unloading, orthostatic stress can produce persistent hypotension (30). These data indicate the critical role of the baroreflex in the adaptation to the upright posture in humans. Additionally, the vestibular system is activated during changes in posture. Vestibular activation reflexively alters sympathetic nerve activity and subsequently vascular resistance (8, 17, 20, 28, 36). These increases also appear critical in the adaptation to the upright posture (5, 9). Collectively, these experimental findings indicate that both baroreflex- and vestibular-mediated increases in MSNA and vascular resistance contribute critically to orthostatic blood pressure control.
In humans, the incidence of orthostatic hypotension increases with advancing age (26). Furthermore, orthostatic hypotension is associated with an increased rate of mortality (13). Thus, mechanisms underlying orthostatic blood pressure regulation are clinically important, particularly in older individuals. One mechanism that may contribute to the age-associated increase in the incidence of orthostatic hypotension is the vestibulosympathetic reflex. Consistent with these suggestions, the vestibulosympathetic reflex is impaired with age (21). Age-associated impairment in the vestibulosympathetic reflex likely results from functional and anatomic changes that occur within both central and peripheral aspects of the vestibular system with age (6, 12, 23, 31). However, it is not currently known whether the age-related impairments in the vestibulosympathetic reflex are detrimental to orthostatic blood pressure control in older adults. Thus, we tested the hypothesis that the ability of the vestibulosympathetic reflex to increase MSNA is impaired resulting in impaired blood pressure regulation during orthostatic stress with age in humans. The results of this study are consistent with the concept that the age-related impairment of the vestibulosympathetic reflex persists during orthostatic challenge in humans.
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METHODS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Subjects
We prospectively studied 21 (10 young and 11 older) healthy volunteers who were normotensive, nonobese, nonsmokers, and not taking any medications known to affect autonomic/cardiovascular function. All subjects were sedentary to recreationally active. On the basis of their age, subjects were classified as either "young" (18-35 yr) or "older" (55-70 yr). Both men and women were studied because sex does not influence the vestibulosympathetic reflex in either young or older subjects (17, 21). Written informed consent was obtained from all subjects after verbal explanation of the experimental protocols. The experiments were approved by the Institutional Review Board at the Pennsylvania State University College of Medicine and meet the American Physiological Society's "Guiding Principals For Ethical Principles For Research Involving Human Subjects" (1).Experimental Design
Protocol 1. The purpose of this experimental protocol was to determine both the neural and cardiovascular responses to head-down rotation (HDR) (i.e., otolith organ engagement) in young and older adults. Subjects performed HDR in the prone position as previously described (28). Briefly, subjects were positioned prone on an examination table with their head extending over the end of the table, such that the head could be rotated downward without interference from the end of the table. During the baseline period, the subject's head was supported in the chin-up neck-extended position. After a 3-min baseline period, the chin support was removed and the subject's head was passively lowered to the point of maximal rotation. After a 1-min period of HDR, the subject's head was returned to the baseline chin-up position for a period of recovery.
Protocol 2.
The purpose of this experimental protocol was to determine the ability
of the vestibulosympathetic reflex to increase MSNA during orthostatic
stress (i.e., baroreceptor unloading). HDR was performed in young and
older subjects during baroreceptor unloading elicited by lower body
negative pressure (LBNP). This protocol was performed in the prone
position with the subjects enclosed in a LBNP chamber up to the level
of the iliac crest. The subject's head was extended over the edge of
the examination table such that the head could be rotated downward
without interference from the end of the table, as in protocol
1. The protocol began with the subject's head in the baseline
chin-up supported position. After a 3-min baseline period, LBNP at 30
mmHg was applied for a 4-min period. During minute 3 of
LBNP, HDR was performed, as in protocol 1, for 1 min. After
this period, the head was returned to the baseline chin-up position and
LBNP continued (minute 4). After this 4-min period, LBNP was
terminated. The subject's head remained in the baseline chin-up
position for a recovery period.
Measurements
Multifiber recordings of MSNA were obtained from the peroneal nerve. A tungsten microelectrode was inserted through the skin and adjusted until a site with clear spontaneously occurring sympathetic bursts was identified. A reference electrode was positioned subcutaneously 2-3 cm away from the site of the recording electrode. Previously described criteria were applied to ensure that an adequate MSNA recording site was obtained (34). Raw nerve signals were amplified (20,000-90,000 times) and filtered (700-2,000 Hz). These filtered signals were then rectified and integrated (time constant 0.1 s) to obtain mean voltage neurograms. Sympathetic recordings indicative of electrode site shifts and/or electromyogram artifact during the experimental protocols were excluded.Continuous measurements of arterial blood pressure and heart rate were made using a Finapres photoplethysmograph (Ohmeda, Louisville, CO). Mean voltage neurograms, heart rate, and arterial blood pressure tracings were collected (MacLab 8e, ADInstruments, Milford, MA) on computer for quality control purposes and later off-line analyses.
Data Analysis
Sympathetic bursts were identified from the mean voltage neurograms. MSNA is reported as both burst frequency and as total MSNA (amplitude of individual bursts) as measured by a computer program (Peaks, ADInstruments).One between- and one within-factor repeated-measures analysis of variance were used to compare the effect of HDR on both neural and cardiovascular parameters in young and older subjects. Paired t-tests were performed to determine if responses to HDR differed between protocols 1 and 2 in each age group. Significance was set at P < 0.05 for all statistical tests. All values are presented as means ± SE.
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RESULTS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Subject characteristics are presented in Table
1. Except for differences in age and
resting MSNA, young and older subjects did not differ in respect to
height, weight, and baseline arterial blood pressure and heart rate.
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Protocol 1 (HDR Alone)
Responses to HDR in young and older subjects are presented in Fig. 1. In young subjects, HDR increased MSNA (8 ± 1 bursts/min and 106 ± 29% for burst frequency
and total MSNA; P < 0.001) but did not alter mean
arterial pressure (MAP) or heart rate. Older subjects demonstrated a
significant but attenuated (P < 0.05 vs. young)
increase in MSNA during HDR (4 ± 1 bursts/min and 20 ± 7% for burst frequency and total MSNA). Unlike young subjects
(1 ± 1 mmHg), HDR decreased MAP in older subjects
(6 ± 2 mmHg; P < 0.01). Heart rate was not
altered by HDR.
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Study 2 (HDR During LBNP)
Responses to HDR during orthostatic stress in young and older subjects are presented in Fig. 2. Young subjects demonstrated a significant increase in MSNA during LBNP (12 ± 1 bursts/min and 162 ± 31% for burst frequency
and total MSNA). HDR performed during minute 3 of LBNP
increased MSNA further (9 ± 2 bursts/min and 53 ± 15% for change from levels during LBNP; P < 0.01).
When the head was returned to the baseline chin-up position during minute 4 of LBNP, MSNA returned to pre-HDR levels. MAP was
well maintained throughout LBNP and during HDR. Heart rate increased during LBNP (6 ± 1 beats/min; P < 0.001) and
was further increased when HDR was performed during minute 3 of LBNP (4 ± 1 beats/min; P < 0.05). All
variables returned to baseline levels during recovery.
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In older subjects, LBNP increased MSNA (13 ± 2 bursts/min and
162 ± 71% for burst frequency and total MSNA;
P < 0.01) to a similar degree as in young subjects.
However, in contrast to a further increase in MSNA when HDR was
performed during minute 3 of LBNP in young subjects, older
subjects did not demonstrate a further increase in total MSNA from
baseline (4 ± 1 bursts/min and 5 ± 4%;
P < 0.05 for burst frequency). Additionally, HDR performed during LBNP decreased MAP (7 ± 2 mmHg;
P < 0.001). This decrease in MAP during HDR in
minute 3 of LBNP (7 ± 2 mmHg) was similar in
magnitude to the decrease in MAP during HDR performed without LBNP in
protocol 1 (6 ± 2 mmHg). Heart rate increased during LBNP but was not altered by HDR performed during LBNP.
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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The present finding of an attenuated increase in MSNA during otolithic engagement in older adults confirms our previous demonstration that aging attenuates the vestibulosympathetic reflex (21). The primary new finding from the present study is that age-associated impairment of the vestibulosympathetic reflex persists during orthostatic challenge in older adults and results in the inability to maintain arterial blood pressure. Collectively, these experimental findings are consistent with the concept that age-related impairment in the vestibulosympathetic reflex may compromise the ability of the vestibular system to participate in orthostatic blood pressure regulation in older humans. As such, it is possible that these age-related alterations in the vestibulosympathetic reflex contribute mechanistically to altered orthostatic blood pressure regulation with age in humans.
The mechanisms underlying this age-associated impairment in the vestibulosympathetic reflex remain unclear but likely involve age-related changes in both central (i.e., reductions in hair cell number) and peripheral aspects (i.e., reductions in afferent projections) of the vestibular system (6, 12, 23, 31). Changes in the vestibular system of these types would likely produce generalized deficits in vestibular function. Consistent with this suggestion, the vestibulosympathetic reflex and both the vestibuloocular and vestibulospinal reflexes are impaired with age (7, 16, 29). Thus, it is likely that functional and morphological changes within the vestibular system contribute to the age-associated impairment in the vestibulosympathetic reflex. Additionally, increases in MSNA during HDR appear to be proportional to the level of head rotation (8). Thus, the attenuated increase in MSNA during HDR in older subjects could have resulted from a smaller degree of head rotation during HDR possibly resulting from reduced neck flexibility with age. However, it is unlikely that the stimulus to the otolith organs differed between the experimental groups because we previously reported identical levels of maximal head rotation in prone young and older subjects during HDR (21). We also did not observe any noticeable differences between the two age groups.
In addition to an attenuated increase in MSNA during HDR, we also demonstrated that HDR performed during orthostatic challenge (i.e., LBNP) does not increase MSNA further in older adults. These data indicate that the vestibular systems' ability to participate in orthostatic blood pressure regulation may be impaired with age. Thus, it is possible that impairment of the vestibulosympathetic reflex with age contributes to the increased incidence of orthostatic hypotension with age. This appears especially true because baroreceptor unloading in the older subjects elicited marked increases in MSNA.
In addition to the attenuated increase in MSNA during otolith organ
engagement, HDR produced hypotension in older adults. The magnitude of
the decline in arterial blood pressure during otolithic engagement
appears similar irrespective of the preceding state of
sympathoexcitation (6 ± 2 and 7 ± 2 mmHg for HDR performed alone and HDR during LBNP). These data indicate that engagement of the vestibulosympathetic reflex by HDR in older adults
elicits hypotension that notably persists in the face of orthostatic
challenge. These data are in contrast to data in young subjects that
demonstrate significant increases in MSNA and preserved arterial blood
pressure in response to otolithic engagement even during experimentally
induced increases in baseline levels of MSNA and arterial blood
pressure (18, 19). Our demonstration that otolithic
engagement elicits hypotension in older adults is not the first example
of vestibular activation producing hypotension in humans
(21). Additionally, in several previous animal studies, vestibular activation has been demonstrated to produce hypotension (10, 33) as well as vestibular lesion-producing
hypotension during whole body tilt in cats (5). However,
our data (present study and Ref. 21) are the first to show
this pattern in older humans.
Currently, the mechanism(s) underlying the reductions in arterial blood pressure during otolithic engagement in older adults are not known. Because increases in MSNA during HDR increase calf and forearm vascular resistance in young subjects (15), it is possible that deficits in the transduction of increases in MSNA into increases in vascular resistance during HDR contributed to the hypotension in older adults. Consistent with this suggestion, Davy and colleagues (4) demonstrated that the transduction of increased MSNA into vascular resistance changes is impaired with age during LBNP applied to elicit similar reductions in central venous pressure to avoid group differences in baroreceptor unloading (11, 14). Thus, it is possible that the reductions in sympathetic vascular transduction noted during LBNP with age contribute to, but cannot fully explain, the reductions in arterial blood pressure. Thus, it is likely that vasodilation occurs in some other (i.e., nonmuscle) vascular bed. Presently, we are not able to determine where vasodilation occurs but rather can only speculate that it plays an obligatory role in producing hypotension during otolithic engagement in older adults.
Vestibular activation produces discretely patterned effects on vascular tone in animals (i.e., both vasoconstriction and vasodilation) (10). Lesion of the vestibular nerve produces persistent hypotension in the cat during whole body upright tilting (5). These data establish that an intact neural vestibular pathway appears critical for maintenance of arterial blood pressure during upright tilting. This association between increasing afferent vestibular outflow and maintenance of arterial blood pressure during orthostasis is likely mediated by removing the vestibular-mediated stimuli to increase vasoconstrictor nerve traffic and subsequently its influence on vascular tone. Additionally, these data provide the experimental basis to suggest that conditions associated with impaired vestibular function may produce hypotension or alter blood pressure control during orthostasis by attenuating increases in vasoconstrictor neural outflow (i.e., MSNA) or augmenting peripheral vasodilation through an unknown mechanism. In this context, attenuation of the vestibulosympathetic reflex with age likely represents a model of impaired vestibular function and is consistent with the persistent hypotension that occurs during HDR in older humans. Additionally, during postural change when the otolith organs are engaged, alterations in vestibular function could contribute to altered orthostatic blood pressure control.
We do not believe that the higher levels of MSNA in the older subjects
at baseline or during LBNP contributed to an inability to increase MSNA
during HDR in the two protocols. The ability to increase MSNA in
response to orthostatic stress (LBNP) appears to be well preserved with
age in humans (present study and Ref. 21) as does the
ability of a cold pressor test to increase MSNA (21, 35).
To specifically test this issue during LBNP, two subjects performed
LBNP at 40 mmHg for 4 min with the addition of apnea for 30 s at
the start of the third minute of LBNP. Unlike HDR, apnea during LBNP
increased MSNA from 25 to 39 bursts/30 s (Total MSNA 200%) and from
27 to 34 bursts/30 s (Total MSNA 52%) for the two subjects,
respectively. This finding clearly indicates that MSNA responsiveness
to HDR was not limited by high activity during LBNP in the older
subjects (i.e., no ceiling effect).
It could be argued that MSNA responses to otolith engagement are delayed in older subjects and thus prevented us from observing increases in MSNA with HDR during LBNP. Zakir et al. (37) demonstrated a transient reduction in renal SNA following stimulation of otolithic afferent nerves. This finding suggests a time-dependent effect of sympathetic responses to vestibular activation. However, the study by Hume and Ray (8) showed the MSNA response to otolith engagement by HDR was maximally activated within 1 min and persisted for 30 min during the maneuver. From this study, we do not believe that using 1 min of HDR in the older subjects prevented us from observing a sympathetic response during LBNP.
In summary, the age-related impairment in the vestibulosympathetic reflex persists during orthostatic challenge in humans. Unlike responses in young adults, HDR performed during sympathoexcitation (i.e., LBNP) does not further increase MSNA in older adults but does provoke hypotension that is of similar magnitude to that demonstrated during HDR performed alone. These consistent and persistent reductions in arterial blood pressure during otolithic activation in older adults provide experimental evidence consistent with the concept that orthostatic blood pressure regulation during otolithic engagement is impaired with age and as such may contribute to altered orthostatic blood pressure regulation with age in humans.
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ACKNOWLEDGEMENTS |
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Grants from the National Heart, Lung, and Blood Institute (HL-58303), National Aeronautics and Space Administration (NAG 9-1034), National Space Biomedical Research Institute (NCC 9-58-168), and an Established Investigator Grant from the American Heart Association awarded to Dr. Ray supported this project. Dr. Monahan was supported by a National Research Service Award (HL-67624). Additional support was provided by a National Institutes of Health sponsored General Clinical Research Center with a National Center for Research Resources Grant M01 RR10732.
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FOOTNOTES |
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Address for reprint requests and other correspondence: C. A. Ray, Penn State College of Medicine, The Milton S. Hershey Medical Center, Division of Cardiology H047, 500 Univ. Drive, Hershey, PA 17033-2390 (E-mail: caray{at}psu.edu).
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
August 1, 2002;10.1152/ajpregu.00298.2002
Received 28 May 2002; accepted in final form 25 July 2002.
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REFERENCES |
|---|
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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1.
American Physiological Society.
Guiding principles for research involving animals and human beings.
Am J Physiol Regul Integr Comp Physiol
283:
R281-R283,
2002
2.
Blomqvist, CG,
and
Stone HL.
Cardiovascular adjustments to gravitational stress.
In: Handbook of Physiology Section 2: The Cardiovascular System, edited by Abboud FM.. Baltimore, MD: Williams & Wilkins, 1983, p. 1025-1063.
3.
Burke, D,
Sundlof G,
and
Wallin G.
Postural effects on muscle nerve sympathetic activity in man.
J Physiol
272:
399-414,
1977
4.
Davy, KP,
Tanaka H,
and
Seals DR.
Augmented cardiopulmonary and integrated sympathetic baroreflexes but attenuated peripheral vasoconstriction with age.
Hypertension
32:
298-304,
1998
5.
Doba, N,
and
Reis DJ.
Role of the cerebellum and the vestibular apparatus in regulation of orthostatic reflexes in the cat.
Circ Res
40:
9-18,
1974[Medline].
6.
Engstrom, H,
Ades HW,
Engstrom B,
Gilchrist D,
and
Bourne G.
Structural changes in the vestibular epithelia in elderly monkeys and humans.
Adv Otorhinolaryngol
22:
93-110,
1977[Medline].
7.
Hirvonen, TP,
Aalto H,
Pyykko I,
Juhola M,
and
Jantti P.
Changes in vestibulo-ocular reflex of elderly people.
Acta Otolaryngol Suppl (Stockh)
529:
108-110,
1997.
8.
Hume, KM,
and
Ray CA.
Sympathetic responses to head-down rotations in humans.
J Appl Physiol
86:
1971-1976,
1999
9.
Jian, BJ,
Cotter LA,
Emanuel BA,
Cass SP,
and
Yates BJ.
Effects of bilateral vestibular lesions on orthostatic tolerance in awake cats.
J Appl Physiol
86:
1552-1560,
1999
10.
Kerman, IA,
Emanuel BA,
and
Yates BJ.
Vestibular stimulation leads to distinct hemodynamic patterning.
Am J Physiol Regul Integr Comp Physiol
279:
R118-R125,
2000
11.
Lanne, T,
and
Olsen H.
Decreased capacitance response with age in lower limbs of humans: a potential error in the study of cardiovascular reflexes in aging.
Acta Physiol Scand
161:
503-507,
1997[ISI][Medline].
12.
Lopez, I,
Honrubia V,
and
Baloh RW.
Aging and the human vestibular nucleus.
J Vestib Res
7:
77-85,
1997[ISI][Medline].
13.
Masaki, KH,
Schatz IJ,
Burchfiel CM,
Sharp DS,
Chiu D,
Foley D,
and
Curb JD.
Orthostatic hypotension predicts mortality in elderly men: the Honolulu Heart Program.
Circulation
98:
2290-2295,
1998
14.
Monahan, KD,
Dinenno FA,
Seals DR,
and
Halliwill JR.
Smaller age-associated reductions in leg venous compliance in endurance exercise-trained men.
Am J Physiol Heart Circ Physiol
281:
H1267-H1273,
2001
15.
Monahan, KD,
and
Ray CA.
Limb neurovascular control during altered otolithic input in humans.
J Physiol
538:
303-308,
2002
16.
Mulch, G,
and
Petermann W.
Influence of age on results of vestibular function tests. Review of literature and presentation of caloric test results.
Ann Otol Rhinol Laryngol Suppl
88:
1-17,
1979[Medline].
17.
Ray, CA.
Effect of gender on vestibular sympathoexcitation.
Am J Physiol Regul Integr Comp Physiol
279:
R1330-R1333,
2000
18.
Ray, CA.
Interaction of the vestibular system and baroreflexes on sympathetic nerve activity in humans.
Am J Physiol Heart Circ Physiol
279:
H2399-H2404,
2000
19.
Ray, CA.
Interaction between vestibulosympathetic and skeletal muscle reflexes on sympathetic activity in humans.
J Appl Physiol
90:
242-247,
2001
20.
Ray, CA,
and
Hume KM.
Neck afferents and muscle sympathetic activity in humans: implications for the vestibulosympathetic reflex.
J Appl Physiol
84:
450-453,
1998
21.
Ray, CA,
and
Monahan KD.
Aging attenuates the vestibulosympathetic reflex in humans.
Circulation
105:
956-961,
2002
22.
Rea, RF,
and
Wallin BG.
Sympathetic nerve activity in arm and leg muscles during lower body negative pressure in humans.
J Appl Physiol
66:
2778-2781,
1989
23.
Rosenhall, U,
and
Rubin W.
Degenerative changes in the human vestibular sensory epithelia.
Acta Otolaryngol (Stockh)
79:
67-80,
1975.
24.
Rowell, LB.
Human Cardiovascular Control. New York: Oxford Univ. Press, 1993.
25.
Rowell, LB,
and
Seals DR.
Sympathetic activity during graded central hypovolemia in hypoxemic humans.
Am J Physiol Heart Circ Physiol
259:
H1197-H1206,
1990
26.
Rutan, GH,
Hermanson B,
Bild DE,
Kittner SJ,
LaBaw F,
and
Tell GS.
Orthostatic hypotension in older adults. The Cardiovascular Health Study. CHS Collaborative Research Group.
Hypertension
19:
508-519,
1992
27.
Shoemaker, JK,
Hogeman CS,
Leuenberger UA,
Herr MD,
Gray K,
Silber DH,
and
Sinoway LI.
Sympathetic discharge and vascular resistance after bed rest.
J Appl Physiol
84:
612-617,
1998
28.
Shortt, TL,
and
Ray CA.
Sympathetic and vascular responses to head-down neck flexion in humans.
Am J Physiol Heart Circ Physiol
272:
H1780-H1784,
1997
29.
Sloane, PD,
Baloh RW,
and
Honrubia V.
The vestibular system in the elderly: clinical implications.
Am J Otol
10:
422-429,
1989.
30.
Smit, AA,
Halliwill JR,
Low PA,
and
Wieling W.
Pathophysiological basis of orthostatic hypotension in autonomic failure.
J Physiol
519:
1-10,
1999
31.
Sturrock, RR.
Age related changes in neuron number in the mouse lateral vestibular nucleus.
J Anat
166:
227-232,
1989[ISI][Medline].
32.
Sundlof, G,
and
Wallin BG.
Effect of lower body negative pressure on human muscle nerve sympathetic activity.
J Physiol
278:
525-532,
1978
33.
Uchino, Y,
Kudo N,
Tsuda K,
and
Iwamura Y.
Vestibular inhibition of sympathetic nerve activities.
Brain Res
22:
195-206,
1970[ISI][Medline].
34.
Vallbo, AB,
Hagbarth KE,
Torebjork HE,
and
Wallin BG.
Somatosensory, proprioceptive, and sympathetic activity in human peripheral nerves.
Physiol Rev
59:
919-957,
1979
35.
Victor, RG,
Leimbach WN, Jr,
Seals DR,
Wallin BG,
and
Mark AL.
Effects of the cold pressor test on muscle sympathetic nerve activity in humans.
Hypertension
9:
429-436,
1987
36.
Yates, BJ.
Vestibular influences on the sympathetic nervous system.
Brain Res Brain Res Rev
17:
51-59,
1992[Medline].
37.
Zakir, M,
Ono S,
Meng H,
and
Uchino Y.
Saccular and utricular influences on sympathetic nerve activities in cats.
Exp Brain Res
134:
402-406,
2000[ISI][Medline].
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P < 0.05 compared with young.
