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Query: UMLS:C0085383 (
hypocapnia
)
1,697
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
1. In spontaneously breathing, anaesthetized rats, a study was made of the effects upon the graded cardiovascular responses to systemic hypoxia (inspiratory fractional O2 concentration, Fi, O2: 0.15, 0.12, 0.08, 0.06) of maintaining arterial CO2 pressure (Pa,CO2) at the air-breathing level by adding CO2 to the inspirate (eucapnic hypoxia), rather than allowing Pa,CO2 to fall (
hypocapnia
hypoxia). 2. At each Fi,O2, maintenance of eucapnia significantly reduced the increase in respiratory frequency, but significantly accentuated the increase in tidal and minute volume: as a result the fall in Pa,O2 at each Fi,O2 was significantly reduced. 3. Concomitantly, maintenance of eucapnia reduced the increase in heart rate (HR) and fall in arterial pressure (
ABP
), the effects being significant at Fi,O2 0.08 and/or 0.06. There was also a tendency for the increases in renal and femoral vascular conductances (RVC, FVC) to be reduced; at Fi,O2 0.06 mean increases from control were 2 +/- 10 vs. 16 +/- 7% (eucapnia vs.
hypocapnia
) for RVC, and 62 +/- 11 vs. 106 +/- 27% for FVC. 4. As maintenance of eucapnia reduced the fall in Pa,O2 at each Fi,O2, the above results were also considered as a function of Pa,O2. Then, maintenance of eucapnia had similar significant effects on the changes in respiration and HR as described above and reduced the mean increase in RVC (16 +/- 11 vs. 23 +/- 10%, at Pa,O2 31 mmHg, which was attained at Fi,O2 0.06 with eucapnia and 0.08 with
hypocapnia
). However, maintenance of eucapnia had no effect on the falls in
ABP
and accentuated the mean increase in FVC (74.9 +/- 13 vs. 57 +/- 10% at Pa,O2 31 mmHg). 5. These findings indicate that, in the rat, the
hypocapnia
that accompanies the hyperventilatory response to systemic hypoxia facilitates the tachycardia and may accentuate the renal vasodilation, but attenuate the hypoxia-induced vasodilatation in skeletal muscle. Possible mechanisms are discussed.
...
PMID:Influences on the cardiovascular response to graded levels of systemic hypoxia of the accompanying hypocapnia in the rat. 250 77
1. In cats anaesthetized with Saffan, which does not block afferent activation of the brain stem defence areas, we have analysed the cardiovascular changes induced by 3 min periods of graded systemic hypoxia (fraction of O2 in inspirate, Fi,O2, 0.15, 0.12, 0.08, 0.06). 2. At light levels of Saffan anaesthesia, hypoxia (particularly Fi, O2 0.08 and 0.06) or selective stimulation of carotid chemoreceptors evoked the pattern of tachycardia, decrease in renal and mesenteric vascular conductance (RVC, MVC), but increase in femoral vascular conductance (FVC) which is characteristic of the alerting-defence response. This supports our view that activation of the defence areas is an integral part of the response to systemic hypoxia. 3. Hypoxia also induced an increase in frequency of augmented breaths which was graded with the level of hypoxia: 0.6 min-1 at Fi, O2 0.21 to 1.1 min-1 at Fi, O2 0.06; in some cats each of these was accompanied by a transient fall in arterial pressure (
ABP
) and increase in FVC. It is proposed that these responses were all part of a reflex elicited by lung irritant receptors and facilitated by peripheral chemoreceptors. However, their low rate of occurrence and the liability of the vasodilatation suggests they do not make major contributions to the overall response. 4. The above short-lasting responses were superimposed upon gradual changes whose magnitudes were graded with the level of hypoxia: hyperventilation, slight tachycardia, but bradycardia at Fi, O2 0.6, small increases in
ABP
, FVC and MVC allowing femoral and mesenteric blood flow to increase, but decreases in RVC which maintained renal blood flow constant. 5. Vagotomy had no significant effect on these changes. Further, hyperinflation of the lungs with pressures of 10 mmHg evoked the Breuer-Hering reflex but had no noticeable cardiovascular effect. It is proposed that, in the cat, reflex tachycardia and vasodilatation elicited by lung stretch receptors play no significant part in the response to hypoxia. 6. By contrast, after pneumothorax, with ventilation and thereby arterial PCO2 (Pa, CO2) maintained constant, graded hypoxia produced graded bradycardia, decrease in MVC and RVC and no change in FVC. Taken together, these results suggest that in the spontaneously breathing cat, the response to hypoxia is dominated by the effects of
hypocapnia
secondary to hyperventilation, which by inhibiting peripheral and central chemoreceptor activity effectively counteracts the primary bradycardia and peripheral vasoconstriction elicited by hypoxic stimulation of peripheral chemoreceptors. 7. These proposals are compared with those drawn for other species.
...
PMID:Analysis of factors that contribute to cardiovascular changes induced in the cat by graded levels of systemic hypoxia. 260 Aug 40
The time constant of cerebral arterial bed (in brief time constant) is a product of brain arterial compliance (C(a)) and resistance (CVR). We tested the hypothesis that in normal subjects, changes in end-tidal CO(2) (EtCO(2)) affect the value of the time constant. C(a) and CVR were estimated using mathematical transformations of arterial pressure (
ABP
) and transcranial Doppler (TCD) cerebral blood flow velocity waveforms. Responses of the time constant to controlled changes in EtCO(2) were compared in 34 young volunteers. Hypercapnia shortened the time constant (0.22 s [0.17, 0.26] vs. 0.16 s [0.13, 0.20]; p = 0.000001), while
hypocapnia
lengthened the time constant (0.22 s [0.17, 0.26] vs. 0.23 s [0.19, 0.32]; p < 0.0032). The time constant was negatively correlated with changes in EtCO(2) (R(partial) = -0.68, p < 0.000001). This was associated with a decrease in CVR when EtCO(2) increased (R(partial) = -0.80, p < 0.000001) and C(a) remained independent of changes in EtCO(2). C(a) was negatively correlated with mean
ABP
(R(partial) = -0.68, p < 0.000001). In summary, the time constant shortens with increasing EtCO(2). Its potential role in cerebrovascular investigations needs further studies.
...
PMID:Time constant of the cerebral arterial bed in normal subjects. 2267 54
Objectives
: The critical closing pressure (CrCP) defines arterial blood pressure below which cerebral arteries collapse. It represents a clinically relevant parameter for the estimation of cerebrovascular tone. Although there are few methods to assess CrCP, there is no consensus which of them estimates this parameter most accurately. The aim of present retrospective, experimental study was to compare three methods of CrCP estimation: conventional Aaslid's formula and methods based on the cerebrovascular impedance: the established continuous flow forward (CFF) and a new pulsatile flow forward (PFF) model.
Methods
: The effects of the following physiological manoeuvres on the CrCP were studied in New Zealand white rabbits: lumbar infusion of Hartmann's solution to induce mild intracranial hypertension, sympathetic blockade to induce arterial hypotension, and modulation of respiratory tidal volume to induce
hypocapnia
or hypercapnia.
Results
: During intracranial hypertension, all CrCP estimates were significantly higher than at baseline, decreased with decreasing
ABP
and increased with gradual
hypocapnia
. During hypercapnia, all CrCP estimates were significantly decreased but only in the case of CrCP
A
the negative, non-physiological values were observed (16% of the cases). The Bland-Altman analysis revealed that a good agreement between each impedance method and Aaslid's method deteriorated significantly in the low range of the average numerical value of the estimates.
Discussion
: Our results confirm the limited usage of Aaslid's formula for the calculation of CrCP. Although both impedance methods seem to be equivalent, the fact that PFF model better describes cerebrovascular hemodynamic allows the recommendation of this model for the calculation of CrCP.
...
PMID:Critical closing pressure during experimental intracranial hypertension: comparison of three calculation methods. 3216 31
