Modulating effects of the menstrual cycle on cardiorespiratory responses to exercise under acute hypobaric hypoxia

The purpose of this study was to examine the hypothesis that the menstrual cycle-induced modulation of the cardiorespiratory response to exercise might be altered by acute exposure to altitude. During both the luteal and follicular phases, 9 moderately trained female subjects with normal menstrual cycles performed incremental exercise to maximal effort on a cycle ergometer at sea level (SL) and under hypobaric hypoxia (HH) at the equivalent of 3,000 m altitude. Both at rest and during exercise, minute ventilation (.VE) and oxygen uptake (.VO(2)) did not differ between the luteal and follicular phases (either at SL or HH). However, the ratio of .VE to .VO(2) (.VE /.VO(2)), both at rest and during peak exercise, was greater in the luteal phase than in the follicular phase under HH conditions. Furthermore, the partial pressure of end-tidal carbon dioxide (PETCO(2)) during exercise was lower in the luteal phase than in the follicular phase in HH. These results suggest that the menstrual cycle-induced modulation of the ventilatory response to exercise may be altered under acute hypobaric-hypoxic conditions.     

Effects of human menstrual cycle on thermoregulatory vasodilation during exercise

Summary To investigate the effects of the menstrual cycle and of exercise intensity on the relationship between finger blood flow (FBF) and esophageal temperature (T_es), we studied four women, aged 20–32 years. Subjects exercised at 40% and 70% in the semi-supine posture at an ambient temperature of 20 C. Resting T_es was higher during the luteal phase than the follicular phase (P<0.01). There were no significant differences between the two phases in FBF, oxygen consumption, carbon dioxide production, heart rate or minute ventilation at rest and during exercise, respectively. Each regression line of the FBF-T_es relationship consists of two distinct segments of FBF change to T_es (slope 1 and 2). FBF increased at a threshold T_es for vasodilation ([T_{es 0}]) and the rate of FBF rise became greater at another T_es above this threshold ([T_{es 0}']). For both levels of exercise, [T_{es 0}] and [T_{es 0}'] were shifted upward during the luteal phase, but the slopes of the FBF-T_es relationship were almost the same in the two phases of the menstrual cycle. Increasing exercise intensity induced a significant decrease in slope 1 of the FBF-T_es relationship during the follicular (P<0.01) and the luteal phases (P<0.02), respectively. These results show that the set-point temperature may be shifted towards a higher level during the luteal phase of the menstrual cycle during exercise and that, as in males, the thermoregulatory vasodilator response is attenuated by increasing exercise-induced vasoconstrictor tone in proportion to exercise intensity during both phases of the menstrual cycle when heat storage is insufficient in women.Supported in part by Grant-in-Aid for Scientific Research from the Ministry of Education, Science and Culture of Japan (grant no. 57770137)     

Plasma volume during heat stress and exercise in women

Summary Five women were studied during exercise and passive heating to determine whether PV dynamics were affected by the menstrual cycle. The exercise bout (80% peak) on a modified cycle ergometer and the passive heat stress were done in a hot environment (T_a=50°C, P_w=1.61kPa) during the follicular and luteal phase. Esophageal temperature (T_es) was measured continuously. Blood samples were drawn after each 0.2° C increase in T_es and was measured at that time. Initial PV was estimated at rest during the follicular phase. PV changes from rest were calculated at each T_es from Hb and Hct. During passive heating, PV decreased by a mean volume of 156 (±80) ml to 2.83 (±0.09)l in the follicular phase. During the luteal phase, there was a larger volume reduction (300±100 ml) during passive heating, and the final PV was lower than in the follicular phase and averaged 2.47±0.181. During exercise, PV decreased 463 (±90) ml to 2.50 (±0.11) l in the follicular and 381 (±70) ml to 2.50 (±0.23) l in the luteal phase. These data indicate that there is a menstrual cycle effect on PV dynamics during passive heating such that more fluid is shifted out of the vasculature during the luteal phase. During severe exercise there is a greater fluid loss during the follicular phase, yet the final PV is not different between phases.     

Vascular volume dynamics during ergometer exercise at different menstrual phases

Summary Five female Caucasians performed cycle ergometer exercise in a hot environment (32 C dry bulb, 30 C wet bulb) both early in the follicular phase and in the middle of the luteal phase of the menstrual cycle. During each menstrual phase, the exercise was performed once following hyper-hydration and once after 24-h fluid deprivation. More rapid increases in hemoglobin concentration and osmoconcentration, as well as decreases in plasma volume, were observed during exercise in the follicular phase, more notably following hypohydration. The data suggest that the phase of the menstrual cycle as well as the preexercise fluid status of the subject may be important determinants of vascular volume dynamics during exercise.Supported by National Institutes of Health Training Grant HL-07050     

Effects of the menstrual cycle phase on the blood lactate responses to exercise

The effects of menstrual cycle phase on the blood lactate response to exercise were examined in eumenorrheic women (n=9). Exercise tests were performed at the mid-follicular and mid-luteal points in the menstrual cycle (confirmed by basal body temperature records and hormone levels). Blood lactates were measured at rest and during the recovery from exercise. Resting lactates were not different between the exercise tests; however, recovery lactates were significantly (p < 0.05) lower in the luteal compared to the follicular phase. The mechanism for these differences is unclear, but may be related to an estrogen mediated increased lipid metabolism inducing a concurrent reduction in carbohydrate metabolism. The present findings question the use of blood lactate monitoring as a suitable technique to measure exercise intensity in eumenorrheic women.     

Comparison of thermoregulatory responses to exercise in dry heat among prepubertal boys, young adults and older males

The purpose of this investigation was to compare the thermoregulatory responses during exercise in a hot climate among three age categories. Eight prepubertal (PP), eight young adult (Y) and eight elderly (O) male subjects cycled at an intensity of 50 +/- 1% of their maximum oxygen uptake (V(O2peak)) for 85 min (three 20 min bouts with three 7 min rest periods) in hot and dry conditions (41 +/- 0.67 degrees C, 21 +/- 1% relative humidity). During the exercise-in-heat protocol, rectal temperature (T(re)) skin temperatures (T(sk)), heart rate (HR), V(O2), V(CO2) V(E), RER, sweat rate, and the number of heat activated sweat glands (HASG) were determined. Despite highest and lowest end-exposure T(re) in the Y and O groups, respectively, the rise in rectal temperature (accounting for differences in baseline T(re)) was similar in all age groups. Changes in body heat storage (DeltaS), both absolute and relative to body mass, were highest in the Y and O groups and lowest in the PP group. While end-session as well as changes in mean skin temperature were similar in all three age groups, HR (absolute and percentage of maximum) was significantly lower for the O compared with the PP and Y groups. Total body as well as per body surface sweating rate was significantly lower for the PP group, while body mass-related net metabolic heat production ((M -- W) kg(-1)) and heat gained from the environment were highest in the PP and lowest in the O group. Since mass-related evaporative cooling (E(sk) kg(-1)) and sweating efficiency (E(sk)/M(sw) kg(-1)) were highest in the PP and lowest in the O group, the mass-dependent heat stored in the body (DeltaS kg(-1)) was lowest in the PP (1.87 +/- 0.03 W kg(-1)) and highest in Y and O groups (2.19 +/- 0.08 and 1.97 +/- 0.11 W kg(-1), respectively). Furthermore, it was calculated that while the O group required only 4.1 +/- 0.5 W of heat energy to raise their body core temperature by 1 degrees C, and the Y group needed 6.9 +/- 0.9 W (1 degrees C)(-1), the PP group required as much as 12.3 +/- 0.7 W to heat up their body core temperature by 1 degrees C. These results suggest that in conditions similar to those imposed during this study, age and age-related characteristics affect the overall rate of heat gain as well as the mechanisms through which this heat is being dissipated. While prepubertal boys seem to be the most efficient thermoregulators, the elderly subjects appear to be the least efficient thermoregulators.     

Enhanced heat loss responses induced by short-term endurance training in exercising women

We investigated the effects of short-term endurance training and detraining on sweating and cutaneous vasodilatation during exercise in young women, taking into account changes in maximal oxygen uptake (VO2max) and the phase of the menstrual cycle. Eleven untrained women participated in endurance training; cycle exercise at approximately 60% VO2max for 60 min day(-1), 4-5 days week(-1) (30 degrees C, 45% relative humidity) for three complete menstrual cycles. The standard exercise test consisted of exercise at 50% VO2max for 30 min (25 degrees C, 45% relative humidity), and was conducted before training (Pre), during training sessions (T1, T2 and T3) and after cessation of training (D1 and D2). Values of VO2max increased significantly from 32.7 +/- 1.2 to 37.8 +/- 1.2 ml min(-1) kg(-1) at the end of the training. Local sweat rate in the chest and thigh, but not in the back and forearm, were significantly greater during T1 and T2 only in women who started training from the midfollicular phase. Cutaneous blood flow did not change with training. The threshold oesophageal temperatures for heat loss responses were significantly decreased during T1 versus Pre (averaged values for each body site: sweating, 37.49 +/- 0.08 versus 37.22 +/- 0.12 degrees C; and cutaneous vasodilatation, 37.40 +/- 0.07 versus 37.17 +/- 0.10 degrees C) and maintained through T3; the sensitivities of heat loss responses were not altered. These changes returned to the Pre level by D1. Our data indicate that physical training improves heat loss responses by decreasing the threshold temperatures and that these effects occur within a month of training and disappear within a month after cessation of training. The degree of increase in sweating with training differs among body sites and might be affected by the phase of the menstrual cycle.     

Influence of the menstrual cycle on proenkephalin peptide F responses to maximal cycle exercise

Proenkephalin peptide F [107–140] is an enkephalin-containing peptide found predominantly within the adrenal medulla and is co-packaged with epinephrine within adrenal medullary chromaffin granules. Peptide F has been shown to have the classic opioid analgesia effects along with immune cell interactions. This is only the second peptide F study in women, and in it we compare the responses of peptide F to a maximal cycle exercise test and recovery values over the follicular and luteal phases of the menstrual cycle. Eight untrained (directly documented in this study) women who were eumenorrheic performed a progressive maximal exercise test to volitional exhaustion on a cycle ergometer, once during the follicular phase, and once during the luteal phases of the menstrual cycle. Blood was obtained pre-exercise, immediately post-exercise and at 0, 15, and 30 min into recovery. Typical exercise changes in response to the cycle tests were observed with blood lactate increases that remained elevated 30 min into recovery. No significant exercise-induced elevations were observed for peptide F concentrations with exercise nor were any differences observed between the two menstrual phases. Thus, the effects of the menstrual cycle on peptide F concentrations appear to be minimal under the conditions of this investigation. With high concentrations of peptide F observed at rest (approx. 0.2–0.3 pmol ml⁻¹) pre-exercise arousal mechanisms may have obviated any exercise-induced response. In addition, inhibition via elevated epinephrine may have inhibited any post-exercise increases and finally adrenal medullary capacity for circulatory concentrations of peptide F may have been reached in such untrained women. Pre-exercise arousal mechanisms potentially related to analgesia may also be involved to prepare untrained women for the stress of maximal exercise.     

Influence of the menstrual cycle and oral contraceptives on thermoregulatory responses to exercise in young women

Summary Thermoregulatory responses to exercise in relation to the phase of the menstrual cycle were studied in ten women taking oral contraceptives (P) and in ten women not taking oral contraceptives (NP). Each subject was tested for maximal aerobic capacity ( ) and for 50% exercise in the follicular (F) and luteal (L) phases of the menstrual cycle. Since the oral contraceptives would have prevented ovulation a quasi-follicular phase (q-F) and a quasi-luteal phase (q-L) of the menstrual cycle were assumed for P subjects. Exercise was performed on a cycle ergometer at an ambient temperature of 24° C and relative air humidity of 50%. Rectal (T _re), mean skin ( ), mean body ( ) temperatures and heart rate (f _c) were measured. Sweat rate was estimated by the continuous measurement of relative humidity of air in a ventilated capsule placed on the chest, converted to absolute pressure (PH₂O_chest). Gain for sweating was calculated as a ratio of increase inPH₂O_chest to the appropriate increase inT _re for the whole period of sweating (G) and for unsteady-state (G_u) separately. The did not differ either between the groups of subjects or between the phases of the menstrual cycle. In P, rectal temperature threshold for sweating (T _{re, td}) was 37.85° C in q-L and 37.60° C in q-F (P < 0.01) and corresponded to a significant difference fromT _re at rest. TheT _re, andf _c increased similarly during exercise in q-F and q-L. No menstrual phase-related differences were observed either in the dynamics of sweating or in G. In NP,T _{re, td} was shorter in L than in F (37.70 vs 37.47° C,P<0.02) with a significantly greater value fromT _re at rest. The dynamics and G for sweating were also greater in L than in F. The G_u was 36.8 versus 16.6 kPa · ° C^–1 (P<0.01) while G was 6.4 versus 3.8 kPa · ° C^–1 (P<0.05), respectively. TheT _re, andf _c increased significantly more in phase F than in phase L. It was concluded that in these women performing moderate exercise, there was a greater temperature threshold and larger gains for sweating in phase L than in phase F. Intake of oral contraceptives reduced the differences in the gains for sweating making the thermoregulatory responses to exercise more uniform.     

Augmentation of exercise ventilation by medroxyprogesterone acetate

The influence of medroxyprogesterone acetate (MPA) on exercise performance was studied in a double-blind cross-over trial using six normal males to compare the exercise performance changes to those observed in a previous study of exercise responses of female subjects during the follicular and luteal phase of the menstrual cycle. A maximal progressive work exercise test on a cycle ergometer was performed after 2 weeks of placebo or MPA administration. Although five of six subjects spontaneously complained of increased exertional dyspnoea on MPA, no significant decreases were documented in maximal exercise time or in maximal oxygen consumption. A mean increase in exercise ventilation of 19% at low levels of exertion and 26% at high levels of exertion was documented, but no subject demonstrated evidence of ventilatory limitation. The increases in exercise ventilation observed in these male subjects after MPA administration were larger than those observed in the previous study comparing exercise ventilatory responses during follicular and luteal phases of the menstrual cycle. It seems possible that some other exercise-related modulator of the ventilatory response to exercise under the influence of progesterone is present in either male subjects receiving MPA or women with normal hormonal cycles.     

Tobacco withdrawal in women and menstrual cycle phase

Because negative mood is a characteristic of both tobacco withdrawal and menstrual discomfort, withdrawal may vary by menstrual cycle phase. Tobacco withdrawal, mood, and menstrual discomfort were assessed in premenopausal women who quit smoking during either the follicular (Days 1-14 postmenstrual onset; n = 41) or luteal (Day 15 or longer postmenstrual onset; n = 37) phase of the menstrual cycle and maintained biochemically verified smoking abstinence during the postquit week. Women quitting during the luteal phase reported significantly greater increases in tobacco withdrawal and self-reported depressive symptoms than women quitting during the follicular phase. These results indicate that selecting a quit-smoking day early in the follicular phase may attenuate withdrawal and negative affect in premenopausal female smokers.     

Control of sweating during the human menstrual cycle

Summary Thermoregulatory responses were studied in seven women during two separate experimental protocols in the follicular (F, days 4–7) phase and during the luteal (L, days 19–22) phase of the menstrual cycle. Continuous measurements of esophageal temperature (T _es), mean skin temperature ( ), oxygen uptake and forearm sweating ( ) were made during all experiments. Protocol I involved both passive heat exposure (3 h) and cycle exercise at ∼80% peak during which the environmental chamber was controlled atT _a=50.0° C, rh=14% (P _w=1.7 kPa). In protocol II subjects were tested during thirty-five minutes of exercise at ∼85% peak atT _a=35° C and rh=25% (P _w=1.4 kPa). The normal L increase in restingT _es (≈0.3° C) occurred in all seven subjects. was higher during L than F in all experiments conducted at 50° C. During exercise and passive heat exposure, theT _es threshold for sweating was higher in L, with no change in the thermosensitivity (slope) of toT _es between menstrual cycle phases. This rightward or upward shift inT _es threshold for initiation of sweating averaged 0.5° C for all experiments. The data indicate the luteal phase modulation in the control of sweating in healthy women is also apparent during severe exercise and/or heat stress.     

Changes in nociceptive flexion reflex threshold across the menstrual cycle in healthy women

OBJECTIVE: We assessed the influence of changes in steroid hormones across the menstrual cycle on the spinal nociceptive reflex. METHOD: We studied in 14 healthy women during the follicular and luteal phase the nociceptive flexion reflex (RIII reflex), an objective neurophysiological method that allows exploring possible abnormal functioning of the pain-control system. The basal body temperature (BBT) was used to evaluate the different phases of the ovarian cycle. The menstrual distress questionnaire (MDQ) was also applied for monitoring somatic and psychological symptoms during the cycle. RESULTS: During the luteal phase, the threshold of the RIII reflex (Tr) and the psychophysical threshold for pain (Tp) were both significantly reduced compared with the follicular phase. Moreover, the reflex threshold in the luteal phase was negatively correlated to the total MDQ score of the recording day. CONCLUSIONS: A higher sensitivity to pain stimuli was observed during the luteal phase of the menstrual cycle, which probably results from a reduction in the inhibitory descending control on spinal nociceptive flexion reflex. Complex neuromodulatory interactions of ovarian steroids with other systems of neurotransmission (especially serotonergic) may account for these observations.     

Intense exercise increases the post-exercise threshold for sweating

We demonstrated previously that esophageal temperature (T _es) remains elevated by ≈0.5°C for at least 65?min after intense exercise. Following exercise, average skin temperature (T _avg) and skin blood flow returned rapidly to pre-exercise values even though T _es remained elevated, indicating that the T _es threshold for vasodilation is elevated during this period. The present study evaluates the hypothesis that the threshold for sweating is also increased following intense exercise. Four males and three females were immersed in water (water temperature, T _w?=?42°C) until onset of sweating (Immersion 1), followed by recovery in air (air temperature, T _a?=?24°C). At a T _a of 24°C, 15?min of cycle ergometry (70% VO_2max) (Exercise) was then followed by 30?min of recovery. Subjects were then immersed again (T _w?=?42°C) until onset of sweating (Immersion 2). Baseline T _es and T _skavg were 37.0 (0.1)°C and 32.3 (0.3)°C, respectively. Because the T _skavg at the onset of sweating was different during Exercise [30.9 (0.3)°C] than during Immersion 1 and Immersion 2 [36.8 (0.2)°C and 36.4 (0.2)°C, respectively] a corrected core temperature, T _es (calculated), was calculated at a single designated skin temperature, T _{sk(designated)}, as follows: T _{es(calculated)}?=?T _es?+?[β/(1?β)][T _skavg?T _{sk(designated)}]. The T _{sk(designated)} was set at 36.5°C (mean of Immersion 1 and Immersion 2 conditions) and β represents the fractional contribution of T _skavg to the sweating response (β for sweating?=?0.1). While T _{es(calculated)} at the onset of sweating was significantly lower during exercise [36.7 (0.2)°C] than during Immersion 1 [37.1 (0.1)°C], the threshold of sweating during Immersion 2 [37.3 (0.1)°C] was greater than during both Exercise and Immersion 1 (P?相似文献   

Gustatory changes associated with the menstrual cycle.

We studied changes in the palatability and gustatory functions as they correlate with the menstrual cycle in 30 healthy females with regular menstrual cycles. The gustatory function was investigated by conducting electrogustometry and by the filter-paper disk method with taste solutions in the follicular and luteal phases of the same subjects. The responses to a questionnaire revealed that appetite was enhanced prior to menstruation in 14 cases (46.7%). The results of electrogustometry showed that the threshold in the domain of the chorda tympani nerve was 0.3 +/- 3.4 dB in the follicular phase and -0.9 +/- 2.8 dB in the luteal phase. Although the threshold in the luteal phase indicated a statistically significant decrease (p < 0.05), the difference was so small that the change could not be subjectively discriminated. The threshold in the domain of the glossopharyngeal nerve was 2.6 +/- 4.0 dB in the follicular phase and 1.7 +/- 3.9 dB in the luteal phase, with no significant difference between the two values. Gustatory thresholds as obtained by the filter-paper disk testing were not significantly different between the follicular and luteal phases. Thus, although the taste function may change through the menstrual cycle, changes in gustatory thresholds are minimal and remain within the normal range.     

A prospective study evidencing rhinomanometric and olfactometric outcomes in women taking oral contraceptives.

BACKGROUND: The aim of this prospective study was to evaluate the changes in olfactory sensitivity of oral contraceptive (pill) users. METHODS: Sixty women underwent rhinomanometric and olfactometric determinations during the follicular, periovular and luteal phases of the menstrual cycle, and at day 7, 14 and 21 of contraceptive intake. Thirty-one women used 30 microg ethinyl oestradiol plus 75 microg gestodene and 29 women used 20 microg ethinyl oestradiol plus 150 microg desogestrel. RESULTS: Rhinomanometry showed higher but not statistically significant values during the periovular phase than in the follicular and luteal phases. Olfactometry showed a higher sensitivity during the follicular and periovular phases than during the luteal phase of the menstrual cycle. The rhinomanometric surveys in pill users were statistically different from those of the luteal phase (P < 0.02) and the follicular and periovular phases (P < 0.001). The olfactometric thresholds during the period of contraceptive use were statistically different from those of the follicular phase for a few odorous substances, and from those of the periovular phase for each odorous substance, but similar to those of the luteal phase (P = NS). CONCLUSIONS: Unlike the rhinomanometric airflow and trans-nasal pressure, the olfactory threshold to odours seems to depend on the variations of the ovarian steroids during the menstrual cycle and on the iatrogenic effects of oral contraceptives.     

Lower olfactory threshold during the ovulatory phase of the menstrual cycle

We investigated whether olfactory detection threshold is correlated with phase of the menstrual cycle. Three hundred and thirty-two women 13-49 years old were tested once during either the follicular, ovulatory, luteal or menstrual phase, and 15 women 20-43 years old were tested at each of these phases across one complete cycle. In three non-cycling control groups subjects were each tested once; 83 post-menopausal women 47-86 years old, 60 pre-pubertal girls 5-12 years old, and 183 men 17-30 years old. Odor detection thresholds were determined using sniff bottles containing -log9.5 to -log6.0 concentrations of amyl acetate presented in ascending order. Thresholds differed significantly across the cycle and were lowest during the ovulatory and highest during the menstrual phase. Thresholds for all control groups were higher than for the cycling women during the ovulatory phase. The results confirm that olfactory threshold is related to phase of the menstrual cycle and thus possibly to hormonal state.     

Effects of physical training on heat loss responses of young women to passive heating in relation to menstrual cycle

To examine the effects of physical training on cutaneous vasodilation and sweating responses of young women in the follicular and luteal phase, 11 physically trained (T group) and 13 untrained (U group) women were passively heated by lower-leg immersion into hot water of 42°C (ambient temperature of 30°C and 45%RH) for 60 min in their mid-follicular and mid-luteal phases of the menstrual cycle. Female hormones increased significantly from the mid-follicular to the mid-luteal phase in T and U groups, but the degree of increase was significantly lower in T group. Mean body temperature thresholds for cutaneous vasodilation and sweating responses were significantly lower in T group than in U group, in both the menstrual phases, and the differences between the groups were greatest during the mid-luteal phase. The slope of the relationship between frequency of sweat expulsion (F_sw) and and between local sweating rate and F_sw was significantly greater in T group, although the slope of the relationship between cutaneous blood flow and did not differ between the groups, regardless of body site or menstrual phase. These results suggest that regular physical activity enhanced sweating and cutaneous vasodilation in young women. The enhancement of sweating was due to both central and peripheral mechanisms, and the enhancement of cutaneous vasodilation was possibly due to a central mechanism. Enhancement of heat loss responses via central mechanisms was greater during the mid-luteal phase than in the mid-follicular phase because the elevation of female reproductive hormone levels during the mid-luteal phase was relatively low in T group.     

Cardiovascular functioning during the menstrual cycle.

Variations in cardiovascular functioning during the 'normal' menstrual cycle have been little researched. Resting-blood pressures, resting-heart rate, rate-pressure product (RPP) and a derived index of fitness (Schneider Index) were monitored throughout natural, hormonally defined menstrual cycles. Volunteers were 26 women (20-48 years) who had regular (25-35 days) cycles. Their blood pressures and heart rate (at rest and according to Schneider's protocol) were measured at the same time daily (Monday-Friday) for 5 weeks. Daily, early morning-urine samples were assayed for sex hormones enabling accurate definition of cycle phase for each woman. Resting systolic-blood pressure was significantly higher in the ovulatory phase (P < 0.05) than in the follicular or luteal phases, but resting-diastolic pressures did not differ significantly between phases. Resting-heart rate was significantly higher in both ovulatory (P < 0.01) and luteal (P < 0.01) phases than in the menstrual and follicular phases. The Schneider Index was higher during the follicular phase than during the ovulatory (P < 0.005) or luteal (P < 0.01) phases, the RPP was higher during the ovulatory phase than during the bleeding (P < 0.05) and follicular (P < 0.005) phases. These findings provide a pattern of menstrual cycle-related variation in cardiovascular functioning that can be related to established actions of the ovarian steroids.     

The Effects of Menstrual Cycle Phase on Cardiovascular and Pulmonary Responses to Behavioral and Exercise Stress

The present study was designed to compare the differential cardiopulmonary and hemodynamic responses of Type A and B women to an exercise and a psychological stressor. In addition, the effects of menstrual cycle phase on the resting and response levels of a wide range of physiological variables were explored. Thirty-two women participated in a progressive exercise stress test and a threat of shock video game during both the luteal and follicular phases of the menstrual cycle. Half of these subjects expressed the coronary-prone behavior pattern referred to as Type A, as assessed by the Jenkins Activity Survey. The remaining women were relatively free of these behaviors (Type B). Heart rate, oxygen consumption, carbon dioxide production, minute ventilation, and end-tidal carbon dioxide were monitored and recorded on a breath-by-breath basis. Systolic and diastolic blood pressure measures were taken at 2-min intervals. Results indicated similar baseline, exercise, and behavioral stress responses among Type A and B women. The stress responses were also the same between the follicular and luteal phases for all measured physiological variables. However, resting levels of heart rate, metabolism, and ventilation were all elevated at rest during the luteal phase. A regression analysis based on the exercise heart rate and oxygen consumption data demonstrated that a majority of subjects exhibited heart rate responses in excess of that expected during the psychological stressor. These data are discussed with special reference to possible mechanisms of the pathophysiology of cardiovascular disease.