Defective regulation of cerebral oxygen transport after severe birth asphyxia

RAMAEKERS, Vincent; Casaer, P.

doi:10.1111/j.1469-8749.1990.tb08467.x

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Defective regulation of cerebral oxygen transport after severe birth asphyxia

RAMAEKERS, Vincent; Casaer, P.

1990 • In Developmental Medicine and Child Neurology, 32 (1), p. 56-62

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https://hdl.handle.net/2268/169289

DOI
10.1111/j.1469-8749.1990.tb08467.x

PubMed
2404811

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Keywords :

Asphyxia Neonatorum/metabolism/physiopathology; Cerebrovascular Circulation; Gestational Age; Humans; Infant, Newborn; Oxygen/blood; Ultrasonography

Abstract :

[en] Cerebral artery Doppler ultrasonography was used to study the cerebral blood-flow velocity and cerebral oxygen transport of infants requiring a blood transfusion to correct anaemia. Mean flow velocity, pulsatility index and haemoglobin concentration were determined before and after transfusion. 11 stable preterm infants demonstrated an inverse relationship between haemoglobin concentration (or estimated arterial oxygen content) and mean flow velocity, indicating the presence of a homeostatic mechanism keeping brain oxygen transport within certain limits. Three infants with severe post-asphyxial encepalopathy had relatively high mean flow velocities and low pulsatility indices both before and after transfusion. There were no circulatory adjustments in response to an increase in haemoglobin concentration. Thus severe asphyxia at birth disrupted the homeostatic mechanism responsible for keeping brain oxygen transport constant. These findings stress the importance of close monitoring of arterial oxygen content, particularly for infants with severe post-asphyxial encephalopathy.

Disciplines :

Pediatrics
Neurology

Author, co-author :

RAMAEKERS, Vincent ; 1Department of Neuropaediatrics, RWTH, University of Aachen, West Germany

Casaer, P.

Language :

English

Title :

Defective regulation of cerebral oxygen transport after severe birth asphyxia

Publication date :

January 1990

Journal title :

Developmental Medicine and Child Neurology

ISSN :

0012-1622

eISSN :

1469-8749

Publisher :

Wiley-Blackwell, United States

Volume :

Issue :

Pages :

56-62

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 18 June 2014

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Bibliography

Archer L.N.J., Evans D.H., Patton J.Y., Levene M.I. (1986) Controlled hypercapnia and neonatal cerebral artery Doppler ultrasound waveforms. Pediatric Research 20:218-221.
Archer L.N.J., Evans D.H., Patton J.Y., Levene M.I., Levene M.I., Evans D.H. (1986) Cerebral artery Doppler ultrasonography for prediction of outcome after perinatal asphyxia. Lancet 2:1116-1118.
Bergqvist G. (1974) Viscosity of the blood in the newborn infant. Acta Paediatrica Scandinavica 63:858-864.
Brown M.M., Marshall J. (1985) Regulation of cerebral blood‐flow in response to changes in blood viscosity. Lancet 1:604-609.
Brown M.M., Marshall J., Wade J.P.H., Marshall J. (1985) Fundamental importance of arterial oxygen content in the regulation of cerebral blood flow in man. Brain 108:81-93.
(1975) Ulstrasound angiology. Arteries and veins., Goslings, R. G., King, D. H., Marcus, A. W., Adamson, L., Edinburgh:, Churchill Livingstone; .
(1971) Transport of oxygen and carbon dioxide in the blood and body fluids. Textbook of Medical Physiology, Guyton, A. C., Guyton, A. C., 4th edn., Philadelphia:, W. B. Saunders; .
Lassen N.A. (1986) The luxury perfusion syndrome and its possible relation to acute metabolic acidosis localised within the brain. Lancet 2:1113-1115.
(1987) Asphyxia: a reappraisal. Update in Intensive Care and Emergency Medicine. , Levene, M. I., Vincent, J. L., New York:, Springer; 422-428.
Levene M.I., Kornberg J., Williams T.H.C. (1985) The incidence and severity of post‐asphyxial encephalopathy in full‐term infants. Early Human Development 11:21-28.
Levene M.I., Sands C., Grindulis H., Moore J.R. (1986) Comparison of two methods of predicting outcome in neonatal seizures. Lancet 1:67-69.
Lou H., Lassen N.A., Friis‐Hansen B. (1979) Impaired autoregulation of cerebral blood flow in the distressed newborn infant. Journal of Pediatrics 94:118-121.
Perlman J.M. (1985) Neonatal cerebral blood flow velocity measurement. Clinics in Perinatology 12:179-194.
Perlman J.M., Volpe J.J. (1983) Seizures in the preterm infant: effects on cerebral blood flow velocity, intracranial pressure and arterial blood pressure. Journal of Pediatrics 102:288-293.
Ramaekers V.Th., Casaer P., Marchal G., Daniëls H. (1987) Variability in cerebral blood flow and the upper limits of cerebral blood flow autoregulation in preterm infants. Neuropediatrics 18:121.
Siesjö B.K. (1984) Cerebral circulation and metabolism. Journal of Neurosurgery 60:883-908.
Van Bel F., Van de Bor M. (1985) Cerebral oedema caused by perinatal asphyxia. Helvetica Paediatrica Acta 40:361-369.
Volpe J.J. Neurology of the Newborn , 2nd edn., Philadelphia:, W. B. Saunders; 1987, 161-195.
Younkin D.P., Reivich M., Obrist W.D., Delivoria‐Papadopoulos M. (1981) Physiologic responses of neonatal rCBF. Journal of Cerebral Blood Flow and Metabolsim 1:273-274.