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Query: UMLS:C0085383 (
hypocapnia
)
1,697
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We hypothesized that part of the newborn tolerance of asphyxia involves strong ion changes that minimize the cerebral acidosis and hasten its correction in recovery. After exposure of newborn puppies to 15 or 30 min experimental asphyxia (inhalation of gas with fractional concentration of CO2 and of O2 in inspired gas = 0.07-0.08 and 0.02-0.03, respectively), blood lactate increased to 13.2 and 23.4 mmol/l, respectively, brain tissue lactate increased to 14.4 and 19.7 mmol/kg, and cerebrospinal fluid (CSF) lactate increased to 7.6 and 14.4 mmol/l. We presume that the tissue lactate increase reflects increases in brain cell and extracellular fluid lactate concentration. The lactate increase, a change that will decrease the strong ion difference (SID), [HCO3-], and pH, was accompanied by increases in Na+ (plasma, CSF,
brain)
, K+ (plasma, CSF), and osmolality without change in Cl-. After 60-min recovery, plasma and brain lactate decreased significantly, but CSF lactate remained unchanged. [H+] recovery was more complete than that of the strong ions due to hyperventilation-induced
hypocapnia
. We conclude that during asphyxia-induced lactic acidosis, changes in strong ions occur that lessen the decrease in SID and minimize the acidosis in plasma and CSF. To the extent that the increase in brain tissue sodium reflects increases in intra-and extracellular fluid sodium concentration, the decrease in SID will be less in these compartments as well. In recovery, CSF ionic values change little; plasma and brain tissue lactate decrease with a similar time course, and the [H+] is rapidly returned toward normal by
hypocapnia
even while the SID is below normal.
...
PMID:Newborn puppy cerebral acid-base regulation in experimental asphyxia and recovery. 632 80
The perioperative complications associated with cerebral aneurysm surgery require a specific anaesthetic management. Four major perioperative accidents are discussed in this review. The anaesthetic and surgical management in case of rebleeding subsequent to the re-rupture of the aneurysm is mainly prophylactic. It includes haemodynamic stability assurance, maintenance of mean arterial pressure (MAP) between 80-90 mmHg during stimulation of the patient such as endotracheal intubation, application of the skull-pin head-holder, incision, and craniotomy. The aneurysmal transmural pressure should be adequately maintained by avoiding an aggressive decrease of intracranial pressure. Once the skull is open, the brain must be kept slack in order to decrease pressure under the retractors and avoid the risks of stretching and tearing of the adjacent vessels. If, despite these precautions, the aneurysm ruptures again. MAP should be decreased to 60 mmHg and the brain rendered more slack, in order to allow direct clipping of the aneurysm, or temporary clipping of the adjacent vessels. The optimal agents in this situation are isoflurane (which decreases CMRO2), intravenous anaesthetic agents (inspite their negative inotropic effect, they may potentially protect the
brain)
and sodium nitroprusside. Vasospasm occurs usually between the 3rd and the 7th day after subarachnoid haemorrhage. It may be seen peroperatively. The optimal treatment, as well as prophylaxis, is moderate controlled hypertension (MAP > 100 mmHg), associated with hypervolaemia and haemodilution, the so-called triple H therapy, with strict control of the filling pressures. Other beneficial therapies are calcium antagonists (nimodipine and nicardipine), the removal of the blood accumulated around the brain and in the cisternae, and possibly local administration of papaverine. Abrupt MAP increases are controlled in order to maintain adequate aneurysmal transmural pressure. Beta-blockers, local anaesthetics administered locally or intravenously, a carefully titrated level of anaesthesia, a maintained volaemia play a protective role. Cerebral oedema is sometimes already present at the opening of the skull or may arise later, due to a high pressure under the retractors, to the surgical manipulations of the brain or to brain ischaemia subsequent to temporary clipping. Its treatment is aggressive, with intravenous agents, mannitol, deep
hypocapnia
and/or lumbar drainage. Prophylaxis, according to the "brain homeostasis concept", is the preferred method to avoid these four peroperative accidents. It includes normal blood volume, normoglycaemia, moderate
hypocapnia
, normotension, soft manipulation of the brain and optimal brain relaxation.
...
PMID:[Peroperative risks in cerebral aneurysm surgery]. 875 91
Specific carotid body (CB)
hypocapnia
in the-10-Torr (less than eupneic) range reduced ventilation in the awake and sleeping dog to the same degree as did CB hyperoxia [CB PO2 (PCBO2); > 500 Torr; C.A. Smith, K.W. Saupe, K. S. Henderson, and J. A. Dempsey. J. Appl. Physiol. 79:689-699, 1995], suggesting a powerful inhibitory effect of
hypocapnia
at the carotid chemosensor over a range of PCO2 encountered commonly in physiological hyperpneas. The primary purpose of this study was to assess the ventilatory effect of CB
hypocapnia
on the ventilatory response to concomitant CB hypoxia. The secondary purpose was to assess the relative gains of the CB and central chemoreceptors to
hypocapnia
. In eight awake female dogs the vascularly isolated CB was perfused with hypoxic blood (mild, PCBO2 approximately equal to 50 Torr or severe, PCBO2 approximately equal to 36 Torr) in a background of normocapnia or
hypocapnia
(10 Torr less than eupneic arterial PCO2) in the perfusate. The systemic (and
brain)
circulation was normoxic throughout, and arterial PCO2 was not controlled (poikilocapnia). With CB
hypocapnia
, the peak ventilation (range 19-27 s) in response to hypoxic CB perfusion increased 48% (mild) and 77% (severe) due to increased tidal volume. When CB
hypocapnia
was present, these increases in ventilation were reduced to 21 and 27%, respectively. With systemic
hypocapnia
, with the isolated CB maintained normocapnic and hypoxic for > 70 s, the steady-state poikilocapnic ventilatory response (i.e., to systemic
hypocapnia
alone) decreased 15% (mild CB hypoxia) and 27% (severe CB hypoxia) from the peak response, respectively. We conclude that carotid body
hypocapnia
can be a major source of inhibitory feedback to respiratory motor output during the hyperventilatory response to hypoxic carotid body stimulation.
...
PMID:Ventilatory effects of specific carotid body hypocapnia and hypoxia in awake dogs. 907 65
The present study analyses the cardiovascular response to acute hypocapnic hypoxia (simulating the effect of respiration at high altitude) both in healthy, unacclimatised subjects and in subjects with moderate anaemia, by means of a mathematical model of short-term cardiovascular regulation. During severe hypoxia, cardiac output and heart rate (HR) exhibit a significant increase compared with the basal level (cardiac output: +90%; HR: +64%). Systemic arterial pressure remains quite constant or shows a mild increase. Coronary blood flow increases dramatically (+200%), thus maintaining a constant oxygen delivery to the heart. However, blood oxygen utilisation in the heart augments, to fulfil the increased power of the cardiac pump during hypoxia. Cerebral blood flow rises only at very severe hypoxia but, owing to the vasoconstrictory effect of
hypocapnia
, its increase (+80%) is insufficient to maintain oxygen delivery to the brain. The model suggests that a critical level for the aerobic metabolism in these organs (heart and
brain)
is reached at an oxygen partial pressure in arterial blood (PaO2) of approximately 25 mmHg. Moderate anaemia during normoxia is compensated by an increase in cardiac output (+22%), a decrease in total peripheral resistance (-30%) and an increase in O2 extraction from blood (+40%). As cardiovascular regulation mechanisms are already recruited in anaemic subjects at rest, their action soon becomes exhausted during hypocapnic hypoxia. Critical levels for vital functions are already reached at a PaO2 of approximately 45 mmHg.
...
PMID:Modelling study of the acute cardiovascular response to hypocapnic hypoxia in healthy and anaemic subjects. 1512 44
