The right cerebral hemisphere of the rat was perfused in situ by retrograde infusion of HCO3 saline or blood into the right external carotid artery. Infusion rate was adjusted to minimize the contribution of systemic blood to flow in the hemisphere. During perfusion with whole or artificial blood, regional cerebral blood flow and blood volume were comparable to respective values in the conscious rat, whereas perfusion with HCO3 saline increased regional flow three- to fourfold due to the low viscosity of the saline perfusate. Perfusion with whole blood for 300 S or with HCO3 saline for 60 S did not alter the permeability of the blood-brain barrier. Cerebrovascular permeability coefficients of eight nonelectrolytes ranged from 10(-8) to 10(-4) cm X S-1 and were directly proportional to the octanol-water partition coefficient of the solute. Thus the in situ brain perfusion technique is a sensitive new method to study cerebrovascular transfer in the rat and permits absolute control of perfusate composition.
WMHI volume is associated with structural and functional brain changes even within a group of very healthy individuals. WMHI is associated with poorer frontal lobe cognitive function and, when severe, is accompanied by significantly reduced frontal lobe metabolism. Subjects with large WMHI volumes have significantly higher systolic blood pressure, brain atrophy, reduced cerebral metabolism, and lower scores on tests of frontal lobe function than age-matched controls. Large amounts of WMHI are, therefore, pathologic and may be related to elevated systolic blood pressure even when it is within the normal age-related range.
A mathematical model describing the kinetics of binding and release of substances by plasma proteins is presented. The effects of protein binding on the uptake of substances such as drugs from the capillary network of the brain are discussed. The model assumes equilibration between bound and free forms of drug in arterial blood and incorporates the on-off rate constants for the drug-protein complex and rate constants for passage of free drug across the blood-brain barrier and for drug metabolism in the brain. Regional cerebral blood flow and the related capillary transit time are important parameters in the model. Analytical expressions for bound and free drug concentrations and for the net extraction of drug are derived where practicable, and numerical solutions also are presented. Effects of changes in the total drug and protein concentrations in the plasma are discussed with special reference to the uptake of bilirubin by the brain.
Blood flow was examined in sciatic nerves of pentobarbital-anesthetized rats by means of laser Doppler flowmetry (LDF) and intravenous [14C]iodoantipyrine infusion. Continuous LDF signals demonstrated slow oscillations and acute, pressure-related changes in flow. The steady-state LDF signal was related linearly to nerve blood flow, as measured with [14C]iodoantipyrine, in intact nerves and nerves stripped of the epineurium. In 14 intact nerves, nerve blood flow averaged 0.27 +/- 0.03 (SE) ml X min-1 X g-1, whereas it averaged 0.13 +/- 0.01 in 5 stripped nerves. Autoradiographs of [3H]-nicotine-infused nerves and intra-arterial injection of 57Co-labeled microspheres demonstrated that flow was not uniform throughout the nerve cross section. The results indicate that LDF can be used to examine nerve blood flow in vivo, demonstrate a linear relation between the LDF signal and flow, and establish absolute values for blood flow in intact and stripped nerves of the anesthetized rat.
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