Enhancement of brain p0(2) during cardiopulmonary bypass using a hyperosmolar oxygen carrying solution.

During the past decade a new syndrome has been recognized: cerebral hypoxia secondary to cardiopulmonary bypass, resulting in impairment of cognitive memory. The incidence of the syndrome appears to be no less that 30% in patients over 65 years of age undergoing cardiac surgery. There are several factors contributing to hypoxia produced by cardiopulmonary bypass. One of these factors is crystalloid pump prime and replacement solutions devoid of (1) oxygen carrying capacity and (2) devoid of protein and its colloid osmotic pressure. This shortcoming of cardiopulmonary crystalloid solutions is partially responsible for two of the three major pathologic effects of cardiopulmonary bypass: (1) hypoxia (2) interstitial fluid accumulation (anasarca, water-logging, edema). This report describes an oxygen carrying hyperosmolar solution which enhances brain p0(2) and diminishes interstitial fluid accumulation. This blood substitute consists of perfluorcarbons and saccharides, but could consist of a hemoglobin variant plus hyperosmolar ingredients other than saccharides. The advantage of a perfluorochemical is its ability to access small channels and to be centrifuged off the patient post-operatively with a cell saver. The advantage of saccharides is that they can be metabolized by the patient for energy, and they produce a moderate diuresis coming off bypass.

Changes in brain pH, PO2, PCO2, cerebral blood flow, and blood gases induced by a hyperosmolar oxyreplete hemosubstitute during cardiopulmonary bypass.

Eleven goats (mean weight, 69 +/- 16 kg) underwent 5 hrs of normothermic nonpulsatile cardiopulmonary bypass (CPB) using as priming fluid either a Ringer's based crystalloid priming solution (CP, n = 5) of a hyperosmolar oxyreplete hemosubstitute (HS, n = 6). The HS contained 20% w/v perfluorocarbon (perfluorodecalin), its osmolarity was 800-900 mOsm/1, and the administered dose of perfluorocarbon was 30-50 ml/kg. Otherwise, the experimental procedure was identical for both groups. PaCO2 was maintained above 35 mmHg and blood flow rate at 65 ml/kg. Brain tissue pH, PO2, and PCO2, cerebral blood flow (CBF), arterial and venous blood gases, and other systemic variables were monitored. During CPB, PVO2 and brain tissue PO2 were increased significantly in the HS group. The CBF per kilogram of weight also was significantly higher in the HS group. Metabolic acidosis developed in both groups and, surprisingly, brain tissue pH and pHV were lower in the HS group. The mean values of PVCO2 and brain tissue PCO2 indicate that brain tissue hypercapnia also occurred in both groups. The HS provided long-term stability and compatibility with electrolytes, and did not cause major complications or allergic reactions during CPB. Perfluorocarbon based HSs improve tissue oxygenation, eliminate the risk of infection due to homologous transfusions, do not require blood type matching, have a shelf life longer than that of blood, and, therefore, they can be an important factor in diminishing the incidence of complications after CPB.

Biopharmaceutical characterisation of a low-dose (75 mg) controlled-release aspirin formulation.

The release of aspirin from a 75 mg controlled-release formulation, designed to inhibit maximally thromboxane A2 production while sparing stimulated prostacyclin biosynthesis, was characterised in healthy subjects. The calculated in vivo release rate of aspirin matched the design goal of approximately 10 mg h(-1). The C(max) of aspirin associated with the controlled-release formulation was lowered 15-fold relative to a solution formulation of the same dose. The bioavailability of aspirin (based on salicylate concentrations) from the controlled-release formulation was approximately 90% relative to the solution, and drug release was not affected by co-administration of a standard breakfast.