Stockard JJ, Bickford RG, Myers RR, Aung MH, Dilley RB, Schauble JFHypotension induced changes in cerebral function during cardiac surgery . Stroke1974; 5: 730-46.
2.
Henriksen L. , Hjelms E., Lindeburgh T.Brain hyperperfusion during cardiac operations . J Thorac Cardiovasc Surg1983; 86: 202-208.
3.
Lundar T., Lindegaard KF, Froysaker T., Aasid R., Grip A., Nornes H.Dissociation between cerebral autoregulation and carbon dioxide reactivity during nonpulsatile cardiopulmonary bypass. Ann Thorac Surg1985; 40: 582-87.
4.
Govier AV, Reves JG, McKay RD et al. Factors and their influence on regional cerebral blood flow during nonpulsatile cardiopulmonary bypass. Ann Thorac Surg1984; 38: 592-600.
5.
Murkin JMCBF, CMRO2 and PaCO2 during CPB. The influence of acid-base management on cerebral blood flow and metabolism during cardiopulmonary bypass . Proc Amer Acad Cardiovasc Perf1986 ; 7: 121-23.
6.
Henriksen L.Brain luxury perfusion during cardiopulmonary bypass in humans. A study of the cerebral blood flow response to changes in CO2, O2 and blood pressure. J Cerebral Blood Flow and Metabolism1986; 6: 366-78
Pearson DT, Holden MP, Waterhouse PS, Clark JIGaseous miocroemboli during open heart surgery: detection and prevention . Proc AmerAcad Cardiovasc Perf1983; 4:103-109.
9.
Pearson DT, Holden MP, Poslad SJ, Murray A., Waterhouse PSA clinical evaluation of the gas transfer characteristics and gaseous microemboli production of two bubble oxygenators. Life Support Systems1984; 2: 252-66.
10.
Butler BDBiophysical aspects of gas bubbles in blood. Med Instrument1985; 18: 59-62.
11.
Swain JA, White FN, Peters RMThe effect of pH on the hypothermic ventricular fibrillation threshold . J Thorac Cardiovasc Surg1984; 87: 445-51.
12.
Kroncke GM, Nichols RD, Mendenhall JT, Myerowitz PD, Starling JREctothermic philosophy of acid-base balance to prevent fibrillation during hypothermia. Arch Surg1986; 121: 303-304.
13.
Brennan RW, Patterson RH, Kessler J.Cerebral blood flow and metabolism during cardiopulmonary bypass: evidence of microembolic encephalopathy. Neurology1971; 21: 665-66.
14.
Slogoff S., Girgis KZ, Keats ASEtiologic factors in neuropsychiatric complications associated with cardiopulmonary bypass. Anaesth Analg1982 ; 61: 903-11.
15.
Gallager EG , Pearson DTUltrasonic identification of sources of gaseous microemboli during open heart surgery. Thorax1973; 28: 295-305.
16.
van den Dungen Jjam, Karliczek GF, Brenken U., Wildevuur Crh.Clinical study of blood trauma during perfusion with membrane and bubble oxygenators . J Thorac Cardiovasc Surg1982; 83: 108-16.
17.
Wright G., Sanderson JMCellular aggregation and destruction during blood circulation and oxygenation . Thorax1976; 31: 405-409.
18.
van Oeveren W., Kazatchkine MD, Descamps-Latscha B. et al. Deleterious effects of cardiopulmonary bypass: prospective study of bubble versus membrane oxygenation . J Thorac Cardiovasc Surg1985; 89: 888-99.
Newland PE, Pastoriza-Pinol JV, McMillan J., Stirling GRA report on the use of five bubble oxygenators for cardiopulmonary bypass surgery. Anaesth Intens Care1982; 10: 45-49.
21.
Swain JAAcid-base, hypothermia and cardiac surgery. Perfusion1986; 1: 231-38.
22.
Parker D., Delpy DT, Halsall DNA new approach to inline gas monitoring: development of an oxygen sensor. Medical and Biological Engineering and Computing1983; 21: 134-37.
23.
Claremont DJ , Pagdin TM, Walton N.Continuous monitoring of blood PO2 in extracorporeal circuits: an in vitro analysis of a reusable oxygen electrode . Anaesthesia1983; 39: 362-69.
24.
Reeder GD, Hood AGAccuracy of oxygen partial pressure measurements: an in vitro study. J Extracorp Tech1983; 15: 89-95.
25.
Hill AG, Vinasky RP, Todd RW, Groom RC, Lefrak EAContinuous measurement of oxygen tension during cardiopulmonary bypass . Proc Amer Acad Cardiovasc Perf1984; 5: 39-42.
26.
Poslad SJ, Pearson DT, Murray A.Clinical comparison of one in vitro and three inline blood gas PO 2 sensors during cardiopulmonary bypass. Clin Phys Physiol Meas1987; 8: 249-59.
27.
Pearson DT, Holden MP, Poslad SJ, Murray A., Waterhouse PSA clinical evaluation of the performance characteristics of one membrane and five bubble oxygenators: gas transfer and gaseous microemboli production . Perfusion1986; 1: 15-26.
28.
Riley JB, Hurdle MB, Winn BA, Jallad MSUse of nitrogen in ventilation of artificial blood oxygenators. J Extracorp Tech1984; 16: 45-46.
29.
Kurusz M., Butler BDProblems relating to gaseous microemboli and the use of nitrogen with bubble oxygenators. J Extracorp Tech1984; 16: 114-15.
30.
Yost G.The bubble oxygenator as a source of gaseous microemboli. Med Instrument1985; 19: 67-69.
31.
Bastianen GWThe use of air with bubble oxygenators and its influence on the formation of microgas emboli. J NeSECC1984; 9: 25-27.
32.
Pearson DT, Poslad SJ, Murray A., Clayton R.Extracorporeal circulation material evaluation: microemboli. Life Support Systems1987; 5: 53-67.
33.
Ferguson TB , Burbank A., Burford THThe disposable bubble oxygenator. Evaluation of an improved model. Surgery1967; 61: 260-64.
