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Query: UMLS:C0022116 (
ischemia
)
91,303
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Electrical properties of tissues sensitively reflect structural and physiologic changes. The authors examined the use of a dielectric spectrogram for instantaneous evaluation of ischemic injury of the liver. Wistar rats, which had enough collateral circulation for portal bypass with subcutaneous transposition of the spleen, were used. Four ischemic periods (15, 30, 60, and 120 min) were examined and followed by reflow. Permittivity and conductivity were measured at 39 frequency points in the 20 Hz-1 MHz range using an
LCR
meter system. They were then expressed in a loss tangent (LT) plot to clear their behavior. The maximum LT value (max-LT) and the minimum LT value (min-LT) of the normal liver were 3.98 +/- 0.28 and 2.98 +/- 0.22, and appeared in 15-20 kHz and 150-300 kHz, respectively. During the first 30 min after
ischemia
, max-LT decreased to 3.25 +/- 0.14 (p < 0.005) and its range shifted to 0.3-0.6 kHz, and min-LT decreased to 1.35 +/- 0.06 (p < 0.001) without shifting of range. Max-LT then decreased gradually and min-LT began to increase. After reflow, max-LT increased and higher max-LT was observed in the longer ischemic cases. Max-LT at 1 hr after reflow correlated negatively with recovery rate of bile flow at that time (y = -0.238x + 1.84, r2 = 0.82). Additionally, the difference between max-LT and min-LT at just before reflow (dif-LT) showed a significant correlation coefficient with recovery rate of bile flow at 1 hr after reflow (y = 2.22x -3.32, r2 = 0.92).
...
PMID:Dielectric spectrogram for instantaneous evaluation of ischemic injury of the liver. 857 24
The purpose of this study was to determine if graft viability during simple cold storage can be monitored from alteration of myocardial electrical impedance. Six anesthetized dogs underwent rapid cardiac extirpation and were placed in simple cold storage in saline for 12 hours. Myocardial electrical impedance was measured serially by use of a
LCR
meter and the changes of myocardial resistivity analyzed. Myocardial specimens were taken for myocardial ATP analysis and electron microscopic study during preservation. We investigated the correlation between myocardial resistivity and myocardial ATP content. Moreover in order to predict cardiac function after simple cold storage in saline, heterotopic cardiac transplantation in the neck was performed in mongrel dogs and left ventricular Emax (LV Emax) was measured with a micromanometer and conductance catheter method. It was then investigated whether or not it is feasible to predict cardiac function of the graft afer reperfusion from the changes in myocardial resistivity. Myocardial ATP remained above 50% of preischemic value 4 hours after preservation. Ultrastructural alterations of
ischemia
were observed in hearts preserved for 8 and 12 hours. In heterotopic cardiac transplantation, LV Emax at 120 minutes after reperfusion recovered to 94 +/- 13% of preischemic function in 4 hour-preserved heart, 72 +/- 10% in 8 hour-preserved heart. Percent recovery of LV Emax in the former was significantly higher than that in the latter (p<0.05). Turning points from reversible conditions to irreversible ones were between 4 and 8 hours based on myocardial ATP content, cardiac function after transplantation and morphological changes. With the time of preservation, resistivity began to increase in every dog and peaked during preservation. The time required to reach the peak point of resistivity ranged from 4 to 5.5 hours. Resistivity increase rate (RIR) decreased gradually during preservation and it was over 0.1 omega cm/min until a half-life of ATP. These results suggested that measurement of myocardial electrical impedance in the preserved heart should be feasible as an indicator of graft viability during preservation in heart transplantation.
...
PMID:Detection of myocardial ischemic injury during simple cold storage by measurement of myocardial electrical impedance. 869 62
We performed experimental and clinical studies with measurement of electrical character in the skeletal muscle to assess ischemic damage and reperfusion injury in lower limbs. In 14 dogs, the bilateral hind limbs were squeezed at the inguinal region to make
ischemia
and they were reperfused after various intervals. Conductivity (G) of the skeletal muscles in hind limbs was measured with an
LCR
meter, which is an impedance analyzer. Change of G from 0 to 3 h of reperfusion (Delta3G) was calculated. G was decreased during
ischemia
and increased after reperfusion. In those whose Delta3G as more than 2.1 mS/cm, serum creatine kinase and aldolase at 10 h after reperfusion were correlated significantly (P < 0.01) to Delta3G. In patients with an abdominal aortic aneurysm (N = 3), arteriosclerosis obliterans (N = 1), or acute arterial occlusion (AAO, N = 1), G of lower extremities was measured from arterial clamp to declamp. Conductivity markedly increased after reperfusion and serum creatine kinase was the highest in the patient with AAO. We suggested that measurement of G may provide monitoring of ischemic and reperfused phase injury in the skeletal muscle and may be applicable to prediction of the skeletal muscular reperfusion injury.
...
PMID:Evaluation of ischemic damage in the skeletal muscle with the use of electrical properties. 987 23
Hemorrhagic shock reflects low tissue perfusion that is inadequate to maintain normal metabolic functions. Often associated with this condition are impairments in cellular oxygen delivery and utilization. Rat strains divergent in their running endurance have been artificially selected over 12 generations. As these rats bred for high (HCR) vs low (
LCR
) aerobic running capacity have greater tissue O(2) utilization capacity and improved cardiovascular function, we hypothesized that HCR would be more tolerant (i.e., have greater survivability) to the global
ischemia
of hemorrhagic shock than
LCR
. To address this hypothesis, survival time to a severe-as substantiated by dramatic changes in plasma lactate, HCO(3), and base deficit-controlled hemorrhage was measured. Male rats were catheterized and, approximately 24 h later, an estimated >35% of the calculated blood volume was removed during a 26-min period while the rats were conscious and unrestrained. Rats were observed for 6 h or until death. Contrary to our hypothesis, survival time in HCR (220 +/- 63 min; n = 6) did not differ statistically (P = 0.46) from that in
LCR
(279 +/- 53 min; n = 7). Similarly, there were no statistical differences (P >or= 0.08) between rat lines in blood pH, lactate, HCO(3), and base deficit pre- or post-hemorrhage. In addition, few significant differences between lines in response to hemorrhage were detected by measures of cellular antioxidant status in heart, liver, or lung. Since animals with genetically greater tissue oxygen utilization capacity failed to show longer survival times, our results suggest that other mechanisms must play a more dominant role in determining survivability to hemorrhage under conditions of this hemorrhage.
...
PMID:Rat strains bred for low and high aerobic running capacity do not differ in their survival time to hemorrhage. 1965 68
