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Abstract
It has been suggested that some techniques of tissue preparation for esr spectroscopy may artifactually generate radicals. We have investigated this, together with the possibility that the susceptibility of the tissue to preparation artifacts may be altered by ischaemia and reperfusion. Three different methods of tissue processing have been assessed: (i) freeze-clamping (- 196 °C), using grooved, aluminium tongs which produce frozen cylinders of tissue (3 mm diameter) which fit directly into esr tubes; (ii) grinding of freeze-clamped tissue with a porcelain pestle and mortar; (iii) lyophilisation of ground, freeze-clamped, tissue. Isolated rat hearts (n = 7 or n = 5/group) were subjected to aerobic perfusion (10 min, 37 °C), total, global ischaemia (15 min) and reperfusion (30 sec). Hearts were freeze-clamped at the end of each period. Tissue was prepared by each of the three methods and esr spectra recorded at - 100 °C. In spectra from tissue which had been freeze-clamped only, broad high- and low-spin iron III signals (g = 1.9, g = 2.2-2.9 and g = 4.6) were seen together with a narrow, well-defined signal (g = 2.005), possibly from a semiquinone radical. In spectra from ground samples, an anisotropic signal (g∥ = 2.040 and g⊥ = 2.008), probably from a peroxyl radical, was observed in addition to the iron III signals. The intensity of the anisotropic signal varied with perfusion conditions; in ischaemic tissue it was decreased to 33 ± 10% of the control value and in reperfused tissue it was decreased to 76 ± 26%. In spectra from lyophilised samples, a narrow signal (g = 2.009), probably from a protein radical, was observed in addition to the iron III signals. The intensity of the signal at g = 2.009 was increased in ischaemic tissue to 170 ± 57% of the control value and in reperfused tissue to 241 ± 85%. In conclusion, artifactual generation of radicals can occur upon grinding (peroxyl radical) and lyophilisation (protein radical). Ischaemia and reperfusion may alter not only radical content per se but may also modify the susceptibility of the tissue to the artifactual production of radicals.