Myocardial protection: left ventricular ultrastructure after different forms of cardiac arrest

Clinically applied methods of cardioplegia show very different effects on the rapidity of decay of energy-rich phosphates as well as on kind and progression of ultrastructural alterations of the ischemic myocardium. Comparing the methods of cardioplegia according to Kirklin, St. Thomas's Hospit...

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Published inThe Thoracic and cardiovascular surgeon Vol. 35; no. 3; p. 148
Main Authors Schnabel, P A, Gebhard, M M, Pomykaj, T, Schmiedl, A, Preusse, C J, Richter, J, Bretschneider, H J
Format Journal Article
LanguageEnglish
Published Germany 01.06.1987
Subjects
Adenosine Triphosphate - metabolism
Animals
Bicarbonates
Calcium Chloride
Dogs
Female
Heart Arrest, Induced
Magnesium
Male
Myocardium - metabolism
Myocardium - ultrastructure
Potassium Chloride
Sodium Chloride
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Summary:Clinically applied methods of cardioplegia show very different effects on the rapidity of decay of energy-rich phosphates as well as on kind and progression of ultrastructural alterations of the ischemic myocardium. Comparing the methods of cardioplegia according to Kirklin, St. Thomas's Hospital and Bretschneider (solution HTK) with pure ischemia at 25 degrees C (model A) and Kirklin's or St. Thomas's cardioplegia and subsequent 210 min or HTK cardioplegia and 300 min ischemia at 22 degrees C plus 20 min subsequent reperfusion (model B) leads to the following results: Model A: Compared with pure ischemia cardioplegia according to Kirklin and the St. Thomas's Hospital slows down the decay of the left ventricular ATP-concentration by a mean factor of 3 and the progression of structural alterations of the left ventricular subendocardium by a factor of 2. HTK retards the ATP-decay by a factor of 6, the alterations of ultrastructure by a factor of 6.5. St. Thomas's solution, in contrast to all other methods of cardioplegia, at the onset of ischemia already causes a cellular edema of myocytes; the edema increases during ischemia, and at the ATP-concentration of 4 mumol per gram myocardium is more pronounced than with pure ischemia, Kirklin or HTK. After application of Kirklin's solution, in contrast, a cellular edema of capillary endothelia develops during ischemia, which at 4 mumol ATP is more pronounced than with each of the other methods. Model B: After global ischemia until the ATP-concentration of left ventricular myocardium is 4 mumol/g and a subsequent 20 minutes post-ischemic recovery the ultrastructural alterations in principle resemble those occurring during ischemia (model A).
ISSN:0171-6425
DOI:10.1055/s-2007-1020219