HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via ISI Web of Science (2) Citing Articles via Google Scholar Google Scholar Articles by Moffitt, J. A. Articles by Johnson, A. K. Search for Related Content PubMed PubMed Citation Articles by Moffitt, J. A. Articles by Johnson, A. K.

NEUROHUMORAL CONTROL OF CIRCULATION AND HYPERTENSION

Short-term fluoxetine treatment enhances baroreflex control of sympathetic nervous system activity after hindlimb unloading

¹The Cardiovascular Center, and Departments of ²Psychology, ³Pharmacology, and ⁴Exercise Science, University of Iowa, Iowa City, Iowa 52242

Submitted 18 April 2002 ; accepted in final form 20 November 2003

	ABSTRACT

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
Data in humans indicate that individuals with orthostatic hypotension that are refractory to other traditional forms of therapy are responsive to selective serotonin reuptake inhibitor (SSRI) treatment. We tested the hypothesis that SSRI administration would help correct the attenuated baroreflex control of sympathetic nervous system activity in the hindlimb-unloaded (HU) rat model of cardiovascular deconditioning. An initial study was conducted to determine the time course of effects of fluoxetine (Flu) administration on baroreflex control of lumbar sympathetic nerve activity (LSNA) in conscious, chronically instrumented rats. Animals received either vehicle (Veh, sterile water) or 10 mg/kg Flu for 1, 4, or 16 days of treatment. Data indicate that while 1-day and 16-day Flu administration did not affect baroreflex function, baroreflex control of LSNA was enhanced after 4-day (short term) Flu administration. HU rats were then treated with Flu for 4 days and compared with HU rats receiving Veh and to casted control rats maintained in the normal posture that received either Veh or short-term Flu treatment. Similar to pilot data, short-term Flu treatment enhanced baroreflex control of LSNA in both HU rats and control rats. These data taken together indicate that baroreflex control of sympathetic nervous system activity is a possible mechanism responsible for the successful treatment of orthostatic intolerance with Flu.

serotonin; microgravity; spaceflight

Baroreflex-mediated changes in sympathetic nervous system activity are of primary importance in controlling both heart rate (HR) and peripheral resistance (3, 28). Adequate control of these factors is vital to preventing both cardiac arrhythmias and orthostatic hypotension (3, 28). Recent findings indicate that short-term treatment with an SSRI reduces basal sympathetic tone in healthy humans (32). It is unknown if the positive cardiovascular effects of SSRI treatment require chronic administration. Data indicate that short-term treatment with selective norepinephrine (NE) reuptake inhibitors may elicit transient reductions in basal sympathetic cardiac tone that do not persist with longer-term (21 day) treatment in humans (2). In contrast, treatment with nefazodone, a combined serotonin and NE reuptake inhibitor, resulted in a dose-dependent reduction in sympathetic cardiac tone that is maintained with chronic treatment (1). Therefore the time course for cardiovascular autonomic effects in response to SSRI administration is unclear.

The hindlimb-unloaded (HU) rat model of cardiovascular deconditioning has been used as a ground-based animal model to study mechanisms responsible for the orthostatic intolerance commonly experienced after bed rest and spaceflight. The physiological effects of hindlimb unloading in rodents are well-documented and similar to those experienced by humans after cardiovascular deconditioning. These effects include an initial central shift in fluids, diuresis, natriuresis, and reduced plasma volume and blood volume (31, 35). In addition, on removal from hindlimb unloading, rats exhibit typical signs of deconditioning: resting tachycardia, reduced exercise capacity, and effects consistent with orthostatic intolerance (18, 25, 36). Studies have also demonstrated that HU rats have attenuated baroreflex control of sympathetic nervous system activity that is most likely due to a change within the central nervous system (12, 20-22). Thus the HU rat model of cardiovascular deconditioning provides an excellent model for the study of dysautonomia and reflex syncope syndromes.

In the current studies, we wanted to determine if the SSRI fluoxetine (Flu) would ameliorate baroreflex dysfunction in the HU rat model of cardiovascular deconditioning. Due to the unknown time course of autonomic effects associated with SSRI treatment, we first conducted an initial study to determine if significant effects on the sympathetic nervous system could be elicited in rats. We then determined whether these effects required acute or chronic SSRI administration. We hypothesized that chronic Flu administration would enhance sympathetic baroreceptor reflexes and this effect would help correct the attenuated baroreflex control of sympathetic nervous system activity after HU in rats.

	METHODS

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
Animals

Male Sprague-Dawley rats (n = 33) obtained from Harlan (Indianapolis, IN) were used for all experimental procedures. Animals were housed individually in environmentally controlled conditions and maintained on a 12:12-h light-dark cycle and given food and water ad libitum. All experiments were conducted in accordance with the National Institutes of Health Guide for the Care and Use of Laboratory Animals and were approved by the Institutional Animal Care and Use Committee of the University of Iowa.

Time Course of Flu

Four groups of rats were used to evaluate the time course of the effects of Flu administration on baroreflex control of HR and sympathetic nervous system activity in a pilot study. Rats received injections of sterile water [vehicle (Veh); 1 ml/kg ip; n = 3] for a period of 16 days or received chronic injections of the SSRI Flu for 16 days (Flu-D16; 10 mg/kg ip; n = 3), a short-term course of treatment for 4 days (Flu-D4; 10 mg/kg ip; n = 3), or an acute treatment of Flu 1 day before baroreflex testing (Flu-D1; 10 mg/kg ip; n = 3). This dose of Flu has been well documented as an appropriate dose to produce maximal selective inhibition of 5-HT reuptake in vivo both acutely and chronically (13). Animals were weighed and given injections at approximately the same time each day (1600-1700). The drug fluoxetine hydrochloride (Flu) was obtained from Sigma (St. Louis, MO). Although the sample size for each group in this study was small, we repeated the primary finding (4-day enhancement) in the subsequent study that focused on the effects of SSRI administration after hindlimb unloading.

SSRI Treatment and Hindlimb Unloading

Male Sprague-Dawley rats (n = 21) obtained from Harlan were randomly assigned to HU or casted control (CC, see below) groups. Both groups were then subdivided into CC and HU groups that received either Veh or Flu treatment. Thus this study contained four experimental groups: casted control-vehicle (CC-Veh; n = 5), hindlimb unloaded-vehicle (HU-Veh; n = 6), casted control-fluoxetine (CC-Flu; n = 5), and hindlimb unloaded-fluoxetine (HU-Flu; n = 5). Rats in the Flu-treated groups received Flu injections (10 mg/kg ip) on the last 4 days of the CC or HU protocol. This time period was chosen based on pilot data from the time-course experiments that demonstrated that baroreflex function was enhanced in response to this treatment regimen. The remaining groups of CC and HU rats received injections of sterile water (1 ml/kg) on the last 4 days of the protocol. HU rats were acclimated to the unloading procedure by temporarily suspending the hindlimbs 2 h/day for 2 consecutive days before the HU procedure. The hindlimbs of HU rats were then elevated with a harness attached to the proximal two-thirds of the tail by modification of a technique previously described (14). Briefly, two hooks were attached to the tail with moleskin adhesive material. A curved rigid support made of lightweight plastic (X-lite splint, AOA/Kirschner Medical) was placed beneath the tail to allow adequate blood flow. The hooks were connected by a wire to a swivel apparatus at the top of the cage, and the hindlimbs were elevated so there was no contact with supportive surfaces. Rats were maintained in a suspension angle of approximately 30-35°. A small thoracic cast made from plaster of Paris was applied to reduce lordosis and help prevent the rats from reaching the tail apparatus. CC rats had the thoracic cast applied (n = 10) but were maintained in a normal cage environment. Animals remained in the HU or CC conditions for a total of 14 days. This time period was chosen because 1) Spacelab Life Sciences missions have been of similar duration, 2) humans subjected to bed rest exhibit stable changes within this time period (9), and 3) this duration of hindlimb unloading provides stable changes in muscle weight and strength in rats (7, 14, 19, 23). Body weights were recorded before and after the control or hindlimb unloading period. During the unloading protocol, the rats were closely monitored several times daily for adequate food and water intake, grooming behavior, and urination and defecation. All rats were housed individually in a temperature-controlled (69-72°F) atmosphere with a 12:12-h light-dark cycle and given rat chow (Purina 5008 rodent chow) and water ad libitum. On the 13th day of the protocol, animals were removed from unloading or normal cage activity conditions to undergo surgical procedures. HU or CC animals were returned to the suspension apparatus or to their cage, respectively, as soon as they had adequately recovered from anesthesia (<1 h). Recovery from anesthesia was determined when the animal was alert and responsive.

Surgical Procedures

Surgical procedures for the placement of femoral catheters and lumbar sympathetic recording electrodes were conducted under halothane anesthesia, using aseptic surgical technique. Polyethylene (PE 10 fused to PE 50) catheters were inserted into the aorta and abdominal vena cava via the left femoral artery and vein for measurement of arterial pressure and administration of vasoactive drugs, respectively.

With the use of a midline abdominal incision, a branch of the lumbar sympathetic chain was dissected free. A bipolar Teflon-insulated silver wire electrode (Medwire, 0.005-in. diameter, 36 gauge) threaded through Silastic tubing (0.25-in. ID) was placed around the isolated nerve. The nerve-electrode complex was covered with a polyvinylsiloxane gel (Coltene President, Mahwah, NJ), which was allowed to harden before closure. A ground wire was sewn to the abdominal wall, and incision sites were sutured closed. Both the catheters and the lumbar sympathetic recording electrodes were tunneled subcutaneously and exteriorized at the dorsal cervical region. Catheters were filled with 10 U/ml of heparinized saline and capped with an airtight plug until the experiment. Animals were given subcutaneous fluids and butorphanol (Stadol, 3 mg/kg) for postoperative analgesia. After immediate recovery from anesthesia, animals were returned to their cages for 24 h.

Experimental Procedures

Unrestrained animals were placed in an experimental cage that was in a Faraday cage to help reduce electrical noise. The arterial catheter was connected to a pressure transducer for recording of arterial pressure. Mean arterial pressure (MAP) was derived electronically using a low-pass filter. HR was determined by measuring the number of heart beats triggered from the arterial pressure pulse. Lumbar sympathetic nerve activity (LSNA) was amplified 2,000 times using a Grass preamplifier (P511) and filtered using a high-pass frequency level of 100 Hz and a low-pass frequency level of 3 kHz. Action potentials were monitored using a Tektronix oscilloscope and a custom-made audio monitor (Bioengineering, Univ. of Iowa). Nerve activity was rectified and integrated using an RMS converter with a time constant of 28 ms. The rectified, integrated signal was then electronically averaged, and this mean signal was used as the relative measure of LSNA. Background noise was determined at the end of the experiment when sympathetic nerve activity was eliminated by an intravenous bolus dose of the ganglionic-blocking agent chlorisondamine (5 mg/kg). This level of background noise was then subtracted from the recorded LSNA before data manipulations. Data signals were gathered and analyzed with a PowerLab (ADInstruments) data-acquisition system.

Baroreflex Assessment Protocol

Baseline hemodynamic parameters were recorded for 20-40 min before experimental manipulations to ensure stabilization of MAP, HR, and LSNA. After the collection of baseline parameters, arterial baroreflex curves were generated by producing ramp changes in arterial pressure over approximately 2-3 min. Initially, MAP was increased to 170-180 mmHg by infusion of the ₁-adrenergic receptor agonist phenylephrine (PE) at increasing rates (2-25 µg·kg^-1·min^-1). MAP, HR, and LSNA were allowed to return within 10% of baseline values before proceeding with the experimental protocol. Arterial pressure was then decreased to 50-60 mmHg by infusion of the vasodilator sodium nitroprusside (NTP) at sequentially increasing rates (10-100 µg·kg^-1·min^-1). The rate of change of arterial pressure was held constant by observing the recorded pressure change and varying the rate of infusion to produce a smooth ramp change in pressure. Care was taken to keep the rate of change of arterial pressure similar in all animals at approximately 1-2 mmHg/s. Volumes infused did not exceed 100 µl. Baroreceptors were always activated first (PE infusion) before unloading (NTP infusion), to minimize any potential effects of reflexly released humoral agents, such as vasopressin or ANG II, on baroreflex function.

Data Analysis

Lumbar sympathetic nerve responses were expressed as a percentage of baseline or control LSNA before experimental interventions. Baseline or control LSNA was considered to be 100%. This analysis allows for direct evaluation of the animal's ability to reflexly increase or decrease LSNA relative to its basal level.

For baroreflex analysis, HR and LSNA were determined at differing levels of MAP during PE and NTP infusions. Data relating changes in HR or LSNA to MAP were fit to a sigmoid logistic function (15) using a standard software package (Sigma Plot, Jandel Scientific, San Rafael, CA). The equation used for this mathematical model is

Parameters (P₁-P₄), which are used to describe basic baroreflex function, were generated from data fit to the logistic function. These parameters were 1) the maximum LSNA or HR during decreases in arterial pressure (P1), 2) the coefficient used to calculate the gain as a function of pressure (P2), 3) the inflection point or MAP at the midpoint of the curve (P3), and 4) the minimum LSNA or HR at an increased arterial pressure (P4). In addition, the gain (G) of the reflex at each level of arterial pressure was calculated for the entire baroreflex curve using the following equation

For each individual animal's fit curve, the four parameters (P₁-P₄) and gain were derived. These parameters and the gain of the baroreflex curve were averaged within a group. In evaluating the time course of Flu treatment, the average parameters were statistically compared between groups using one-way ANOVA. Statistical comparison of baroreflex parameters after Flu or Veh treatment in CC and HU rats was performed using two-way ANOVA. Body weight before and after the CC or hindlimb unloading procedures was evaluated using two-way ANOVA for repeated measures. The mean parameters were used to generate an average baroreflex curve for each group.

	RESULTS

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
Time Course of Flu Pilot Study

Data from the pilot study examining the time course of effects after Flu treatment are presented in Table 1. While there were no significant differences in resting hemodynamic parameters among the four treatment groups, body weight was significantly lower in animals receiving a 16-day treatment regimen of Flu.

Baroreflex Parameters

There were no changes in baroreflex control of HR among any of the three treatment groups compared with the Vehtreated rats as evidenced by no significant differences in any of the parameters describing the baroreflex curves (Table 1).

While acute (Flu-D1) and chronic (Flu-D16) Flu treatment did not alter baroreflex control of LSNA, short-term treatment of Flu (Flu-D4) elicited a significant enhancement in baroreflex control of LSNA as evidenced by a significantly greater maximal baroreflex parameter compared with the Veh group (Table 1). Although maximal gain was not significantly enhanced in this group, a definite trend is evident (P < 0.07).

Flu Treatment in HU Rats

Baseline parameters. Baseline hemodynamic parameters as well as body weights and soleus muscle weights among the four groups are shown in Table 2. Although there were no significant differences in resting MAP among the groups, resting HR was significantly elevated in both groups of HU rats. Both HU-Flu and HU-Veh groups demonstrated a significant reduction in soleus muscle weight and soleus-to-body weight ratio compared with rats in the CC-Veh and CC-Flu groups. Both CC groups experienced a significant increase in body weight throughout the 14-day protocol.

Baroreflex control of HR. Baroreflex control of HR after short-term treatment with Flu in HU rats is illustrated in Fig. 1. Neither hindlimb unloading nor short-term Flu altered the HR response to changes in MAP. This is further evidenced by no significant differences among any of the baroreflex parameters for HR in the four groups shown in Table 3.

View larger version (18K): [in this window] [in a new window]   Fig. 1. Mean baroreflex curves describing reflex control of heart rate (HR) after either vehicle (Veh) or short-term fluoxetine (Flu) treatment in casted control (CC) and hindlimb-unloaded (HU) rats. There was no significant effect on baroreflex control of HR by either hindlimb unloading or Flu treatment.

Baroreflex control of LSNA. Baroreflex-mediated changes in LSNA after short-term treatment with Flu in HU rats are illustrated in Fig. 2. HU-Veh rats demonstrated attenuation of baroreflex mediated increases in LSNA in response to a decrease in MAP compared with CC-Veh rats. In addition, the maximal parameter for baroreflex control of LSNA and the maximal gain was significantly lower in HU-Veh rats compared with that of CC-Veh rats (Table 3). There was a main group effect for a significantly lower minimal parameter for HU rats compared with CC rats in their respective drug treatment group. This effect was present for maximal gain as well (Table 3). Confirming results from the pilot study (Table 1), short-term Flu treatment (i.e., 4 days) in CC-Flu rats resulted in a significant enhancement in maximal LSNA baroreflex responses compared with CC-Veh rats (Fig. 2, Table 3). Data further indicate that this short-term Flu treatment resulted in a normalization of the attenuation in baroreflex control of LSNA in HU rats (Fig. 2). This is evidenced by there being no significant difference between the baroreflex parameters for LSNA in HU-Flu rats compared with CC-Veh rats as shown in Fig. 2 and Table 3.

View larger version (16K): [in this window] [in a new window]   Fig. 2. Mean baroreflex curves describing reflex control of lumbar sympathetic nervous system activity (LSNA) after either vehicle (Veh) or short-term fluoxetine (Flu) administration in casted control (CC) and hindlimb unloaded (HU) rats. Data indicate that fluoxetine treatment enhanced baroreflex control of LSNA in control rats (CC-Veh vs. CC-Flu) as well as normalized the attenuation in baroreflex control of LSNA in HU rats.

	DISCUSSION

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
The results of the present study indicate that short-term treatment with the SSRI Flu in rats results in an enhancement in baroreflex control of sympathetic nervous system activity, and this effect serves to correct the experimentally induced attenuation in baroreflex function in the HU rat model of cardiovascular deconditioning.

Data on the effects of the time course of Flu treatment on sympathetic baroreceptor responses indicate that while acute (1 day) and chronic (16 day) Flu treatment did not affect baroreflex control of LSNA, an intermediate short-term treatment (4 days) resulted in a significant enhancement in baroreflex control of LSNA (Table 1). This effect was verified in a separate group of animals by demonstrating that 4 days of Flu treatment resulted in a similar enhancement in baroreflex control of LSNA in CC-Flu rats compared with CC-Veh animals (Fig. 2 and Table 3).

Considering that it is necessary to administer Flu chronically to alleviate the psychological symptoms associated with depression, we originally hypothesized that only chronic (i.e., 16 day) treatment with Flu would result in an enhancement in baroreflex control of sympathetic nervous system activity. However, data indicate that only a 4-day treatment with Flu produced a significant enhancement in baroreflex function (Fig. 2, Tables 1 and 3). Although these results are interesting and somewhat surprising, there are several possibilities that might explain these effects. First, it is possible that while behavioral effects require chronic SSRI treatment, cardiovascular effects can be elicited in response to a short-term treatment regimen. Studies investigating the cardiovascular benefits of SSRI treatment in humans have primarily evaluated these responses after chronic treatment (5, 11, 27, 29, 30). However, recently Shores et al. (32) cited a reduction in plasma NE appearance rates after short-term treatment with the SSRI sertraline in healthy subjects. The effects after chronic treatment were not evaluated in this (32) study.

It is also possible that the enhancement in sympathetic baroreflex function is due to the specific adaptations in neurotransmission that occur at the short-term time point of administration. Data indicate that short-term SSRI treatment results in a marked reduction of the firing activity of dorsal raphe serotonergic neurons that is partially recovered by 7 days of treatment and completely recovered by 14 days (6). This is in contrast to the finding that prolonged and not short-term SSRI administration results in a marked decrease in locus ceruleus NE neuronal activity (34). This imbalance in raphe 5-HT neuronal activity vs. locus ceruleus NE neuronal activity has been cited as a possible reason why anxiety and panic disorder symptoms are often exaggerated after short-term SSRI treatment and then diminish altogether after chronic treatment (34). Considering these data, it is tempting to speculate that perhaps short-term SSRI treatment results in an overactivation of sympathetic reflexes due to this imbalance in 5-HT/NE neuronal firing. This would explain both the augmentation in anxiety and panic symptoms and the transient enhancement in baroreflex control of LSNA after short-term SSRI treatment. Nonetheless, it is interesting why enhancement in sympathetic baroreflex responses does not persist after chronic treatment.

A third possibility for this effect is that the plasticity and adaptive ability of the arterial baroreflex prevents such an enhancement in baroreflex control of sympathetic nervous system activity to persist in an animal with normal baroreflex function. This would prevent any deleterious cardiovascular effects such as hypertension from developing. However, clinical data indicate that overdosage of SSRIs often produces hypertension (26).

Because group sizes were small in our pilot study in which we studied the time course of SSRI treatment effects on baroreflex function, we felt that it was important to systematically replicate the 4-day data demonstrating the enhancement in baroreflex control of LSNA. We did this in conjunction with the hindlimb unloading study. The results indicate that the baroreflex control of LSNA is enhanced at 4 days in both CC and HU rats receiving Flu compared with their respective Veh treatment groups. Although the effect of 4 days of Flu treatment in the HU-Flu group (vs. their respective control or HU-Veh) was similar to the Flu-D4 group (vs. their respective control or Veh), it would not be appropriate to combine the data from the two studies since control animals in the hindlimb unloading study received a thoracic cast, while those in the time course (pilot) study did not. Nevertheless, the systematic replication of the findings of the two studies increases the degree of confidence in the reliability of the finding that 4 days of treatment with Flu enhances baroreflex control of LSNA. In addition, the fact that this effect helped normalize attenuated baroreflex control of LSNA after HU adds additional support for this conclusion.

Baroreflex data in untreated HU and CC rats are very similar to previous reports (12, 20) and have been essentially replicated in the present study. Comparable to the previous results, HU rats exhibited no significant alterations in baroreflex control of HR (Fig. 1; Table 3) but had a significant attenuation in baroreflex-mediated increases in LSNA compared with control rats (Fig. 2, Table 3). This attenuation in LSNA reflex responses was essentially offset through short-term Flu treatment as there were no significant differences in baroreflex control of LSNA in HU-Flu compared with CC-Veh rats (Fig. 2, Table 3). Because CC-Flu rats also demonstrated a significant enhancement in baroreflex control of LSNA similar to data shown in Fig. 2 and Table 3, there was no significant statistical interaction between the factors of drug treatment and deconditioning status. This may argue against any underlying functional change in the serotonergic system accompanying cardiovascular deconditioning as a mechanism accounting for the attenuation in baroreflex control of LSNA. However, to more conclusively eliminate a role of the serotonergic system controlling baroreflex function in HU rats, further investigation is necessary.

Data in humans indicate that individuals with orthostatic hypotension that are refractory to other traditional forms of therapy are often responsive to SSRI treatment (11, 29). The HU rat model of cardiovascular deconditioning is an animal model commonly used to study mechanisms responsible for the orthostatic intolerance commonly experienced after bed rest and spaceflight. Considering that baroreflex-mediated changes in sympathetic nervous system activity are of primary importance when compensating for changes in arterial blood pressure during an orthostatic challenge (3, 28), we wanted to determine if SSRI treatment may enhance baroreflex function and thus improve orthostatic intolerance. Results indicate that short-term Flu administration resulted in a significant enhancement in baroreflex control of LSNA as well as a correction in attenuated baroreflex function in HU rats (Fig. 2, Tables 1 and 3). Thus enhancement in baroreflex control of sympathetic nervous system activity is a possible mechanism responsible for the successful treatment of orthostatic intolerance in humans after SSRI administration.

The specific mechanism by which Flu treatment works to restore attenuated baroreflex function is not clear. It is possible that the attenuation in baroreflex gain after hindlimb unloading in rats is due to autonomic imbalance and short-term SSRI treatment helps reduce sympathetic tone and thus restore autonomic balance and improve baroreflex function. This possibility is supported by several observations. First, previous data indicate that there is a high degree of correlation between a reduction in autonomic balance as measured through a decrease in HR variability and the attenuation of baroreflex gain (17). Second, hindlimb unloading in rats is associated with a resting tachycardia and reduction in the sympathetic baroreflex gain as documented in the current and previous studies (12, 20, 22). Data from the current study indicate that Flu normalized the attenuated sympathetic baroreflex gain (Fig. 2) and partially normalized the resting tachycardia associated with hindlimb unloading (Table 2). Previous studies indicate that SSRI treatment may restore autonomic imbalance after long-term treatment in posttraumatic stress disorder patients (5). Plasma NE appearance rates are reduced after short-term Flu treatment in healthy humans (32). These findings taken together suggest an SSRI-mediated restoration in autonomic balance may be a mechanism responsible for normalization of attenuated sympathetic baroreflex function after hindlimb unloading.

Individuals with a history of psychological depression are at a much greater risk for developing cardiovascular disease than patients with no prior history of depressive disorders (24). Major depression essentially doubles the risk that patients with newly diagnosed coronary artery disease will experience an adverse cardiovascular event within a year after the diagnosis (4). Increased sympathetic nervous system activity has often been cited as a mechanism in the link between psychological depression and cardiovascular disease (24). Recent data indicate that in rats exposed to the chronic mild stress rodent model of depression there was augmented cardiac sympathetic tone (10). Data from the current study suggest that SSRI administration reduces the basal sympathetic tone to stabilize or normalize baroreflex control of sympathetic nerve activity. Data in humans indicate that this could be a possibility since Flu administration in depressed patients with heart disease resulted in a significant decrease in resting HR (27). In addition SSRI treatment in posttraumatic stress disorder patients normalizes the reduction in HR variability, indicating a possible reduction in an elevated basal sympathetic tone (5).

	GRANTS

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
This research was supported by National Heart, Lung, and Blood Institute Grants HL-07121, HL-14388, and HL-57472 and Office of Naval Research Grant N00014-97-1-0145.

	FOOTNOTES

 

Address for reprint requests and other correspondence: A. K. Johnson, Dept. of Psychology, Univ. of Iowa, 11 Seashore Hall E., Iowa City, IA 52242-1407 (E-mail: alan-johnson{at}uiowa.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.

	REFERENCES

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 

1. Agelink MW, Majewski T, Wurthmann C, Postert T, Linka T, Rotterdam S, and Klieser E. Autonomic neurocardiac function in patients with major depression and effects of antidepressive treatment with nefazodone. J Affect Disord 62: 187-198, 2001.
2. Agelink MW, Ullrich H, Baumann B, Strum S, and Majewski T. Effects of reboxetine, a selective norepinephrine reuptake inhibitor, on sympathetic and parasympathetic outflow to the heart: preliminary data. Psychopharmacology 163: 151-156, 2002.
3. Blomqvist CG and Stone HL. Cardiovascular adjustments to gravitational stress. In: Handbook of Physiology. The Cardiovascular System. Peripheral Circulation and Organ Blood Flow. Bethesda, MD: Am. Physiol. Soc., 1983, sect. 2, vol. III, pt. 2, chapt. 28, p. 1025-1063.
4. Carney RM, Rich MW, Freedland KE, Saini J, teVelde A, Simeone C, and Clark K. Major depressive disorder predicts cardiac events in patients with coronary artery disease. Psychosom Med 50: 627-633, 1988.
5. Cohen H, Kotler M, Matar M, and Kaplan Z. Normalization of heart rate variability in post-traumatic stress disorder patients following fluoxetine treatment: preliminary results. Isr Med Assoc J 2: 296-301, 2000.
6. De Montigny C, Chaput Y, and Blier P. Modification of serotonergic neuron properties by long-term treatment with serotonin reuptake blockers. J Clin Psychiatry 51: 4-8, 1990.
7. Delp MD, Brown M, Laughlin MH, and Hasser EM. Rat aortic vasoreactivity is altered by old age and hindlimb unloading. J Appl Physiol 78: 2079-2086, 1995.
8. Gambarana C, Scheggi S, Tagliamonte A, Tolu P, and De Montis MG. Animal models for the study of antidepressant activity. Brain Res Protoc 7: 11-20, 2001.
9. Gharib C, Maillet A, Gauquelin G, Allevard AM, Guell A, Cartier R, and Arbeille P. Results of a 4-week head-down tilt with and without LBNP countermeasure. I. Volume regulating hormones. Aviat Space Environ Med 63: 3-8, 1992.
10. Grippo AJ, Moffitt JA, and Johnson AK. Cardiovascular alterations and autonomic imbalance in an experimental model of depression. Am J Physiol Regul Integr Comp Physiol 282: R1333-R1341, 2002.
11. Grubb BP, Samoil D, Kosinski D, Wolfe D, Lorton M, and Madu E. Fluoxetine hydrochloride for the treatment of severe refractory orthostatic hypotension. Am J Med 97: 366-368, 1994.
12. Hasser EM and Moffitt JA. Regulation of sympathetic nervous system function after cardiovascular deconditioning. In: NeuroCardiovascular Regulation: From Molecules to Man, edited by Chapleau MW and Abboud F. New York: New York Academy of Sciences, 2001, p. 454-468.
13. Hwang EC, Magnussen I, and Van Woert MH. Effects of chronic fluoxetine administration on serotonin metabolism. Res Commun Chem Pathol Pharmacol 29: 79-98, 1980.
14. Jaspers SR and Tischler ME. Atrophy and growth failure of rat hindlimb muscles in tail-cast suspension. J Appl Physiol 57: 1472-1479, 1984.
15. Kent BB, Drane JW, Blumenstein B, and Manning JW. A mathematical model to assess changes in the baroreceptor reflex. Cardiology 57: 295-310, 1972.
16. Kuhn MD, Wolf WA, and Lovenberg W. Review of the role of central serotonergic neuronal system in blood pressure regulation. Hypertension 2: 243-255, 1980.
17. Lucini D, Guzzetti S, Casiraghi S, and Pagani M. Correlation between baroreflex gain and 24-h indices of heart rate variability. J Hypertens 20: 1625-1631, 2002.
18. Martel E, Champeroux P, Lacolley P, Richard S, Safar M, and Cuche JL. Central hypervolemia in the conscious rat: a model of cardiovascular deconditioning. J Appl Physiol 80: 1390-1396, 1996.
19. McDonald KS, Delp MD, and Fitts RH. Effect of hindlimb unweighting on tissue blood flow in the rat. J Appl Physiol 72: 2210-2218, 1992.
20. Moffitt JA, Foley CM, Schadt JC, Laughlin MH, and Hasser EM. Attenuated baroreflex control of sympathetic nerve activity after cardiovascular deconditioning in rats. Am J Physiol Regul Integr Comp Physiol 274: R1397-R1405, 1998.
21. Moffitt JA, Heesch CM, and Hasser EM. Increased GABA(A) inhibition of the RVLM after hindlimb unloading in rats. Am J Physiol Regul Integr Comp Physiol 283: R604-R614, 2002.
22. Moffitt JA, Schadt JC, and Hasser EM. Altered central nervous processing of baroreceptor input following hindlimb unloading in rats. Am J Physiol Heart Circ Physiol 277: H2272-H2279, 1999.
23. Musacchia XJ, Deavers DR, Meininger GA, and Davis TP. A model for hypokinesia: effects on muscle atrophy in the rat. J Appl Physiol 48: 479-486, 1980.
24. Musselman DL, Evans DL, and Nemeroff CB. The relationship of depression to cardiovascular disease: epidemiology, biology, and treatment. Arch Gen Psychiatry 55: 580-592, 1998.
25. Overton JM, Woodman CR, and Tipton CM. Effect of hindlimb suspension on O_{2 max} and regional blood flow responses to exercise. J Appl Physiol 66: 653-659, 1989.
26. Rickels K and Schweizer E. Clinical overview of the serotonin reuptake inhibitors. J Clin Psychiatry 51: 9-12, 1990.
27. Roose SP, Glassman AH, Attia E, Woodring S, Giardina EG, and Bigger JT. Cardiovascular effects of fluoxetine in depressed patients with heart disease. Am J Psychiatry 155: 660-665, 1998.
28. Rowell LB. Human Cardiovascular Control. New York: Oxford Univ. Press, 1993, p. 36-254.
29. Samoil D and Grubb BP. Neurally mediated syncope and serotonin reuptake inhibitors. Clin Auton Res 5: 251-255, 1995.
30. Sauer WH, Berlin JA, and Kimmel SE. Selective serotonin reuptake inhibitors and myocardial infarction. Circulation 104: 1894-1898, 2001.
31. Shellock FG, Swan HJ, and Rubin SA. Early central venous pressure changes in the rat during two different levels of head-down suspension. Aviat Space Environ Med 56: 791-795, 1985.
32. Shores MM, Pascualy M, Lewis NL, Flatness D, and Veith RC. Short-term sertraline treatment suppresses sympathetic nervous system activity in healthy human subjects. Psychoneuroendocrinology 26: 433-439, 2001.
33. Stahl SM. Mechanism of action of serotonin selective reuptake inhibitors. Serotonin receptors and pathways mediate therapeutic effects and side effects. J Affect Disord 51: 215-235, 1988.
34. Szabo ST, de Montigny C, and Blier P. Progressive attenuation of the firing activity of locus coeruleus noradrenergic neurons by sustained administration of selective serotonin reuptake inhibitors. Int J Neuropsychopharmacol 3: 1-11, 2000.
35. Taylor HL, Henschel A, Brozek J, and Keys A. Effects of bed rest on cardiovascular function and work performance. J Appl Physiol 2: 223-239, 1949.
36. Woodman CR, Sebastian LA, and Tipton CM. Influence of simulated microgravity on cardiac output and blood flow distribution during exercise. J Appl Physiol 79: 1762-1768, 1995.

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via ISI Web of Science (2) Citing Articles via Google Scholar Google Scholar Articles by Moffitt, J. A. Articles by Johnson, A. K. Search for Related Content PubMed PubMed Citation Articles by Moffitt, J. A. Articles by Johnson, A. K.