Previous investigations have established a strong correlation between local cerebral blood flow (LCBF) and local cerebral glucose utilization (LCGU). In the present study the relationship between density of perfused brain capillaries and LCBF or LCGU was investigated in conscious and anesthetized rats. Perfused capillaries were stained by labeling the plasma with the gamma globulin-coupled fluorochromes, fluorescein isothiocyanate (FITC) and lissamine-rhodamine B 200 (RB 200). The density of perfused capillaries was determined in 12 different brain structures by fluorescence microscopy of embedded brain sections following coronal sectioning in a cryostat. Significant differences were found among brain structures investigated; the lowest density of perfused capillaries was found in the white matter (e.g., corpus callosum 162 fragments/mm2), whereas the highest values were determined in the structures of the auditory system (e.g., inferior colliculus 810 fragments/mm2). LCBF and LCGU were measured in two separate groups of rats using standard autoradiographic methods. In all three experimental groups, the same structures were identified and measured with a high degree of accuracy and local resolution. Density of perfused capillaries correlated well with LCBF (r = 0.93) and even better with LCGU (r = 0.97). In addition to the relationship between LCGU and LCBF established by earlier studies, these data show the intimate interrelationship between LCGU, density of perfused capillaries, and LCBF.
Experimental uremia is known to cause cardiac hypertrophy. In the present study we examined the effect of uremia with or without concomitant treatment of hypertension by the converting enzyme Ramipril (125 micrograms/day) on micromorphometric indices of cardiac interstitium at the light microscopical and ultrastructural level. In male SD rats, 21 days of uremia caused an increase of total heart weight (1040 +/- 73 mg wet wt vs. 871 +/- 81 in controls, P less than 0.05) with an increase of both right and left ventricular weight. This was accompanied by reduction of capillary cross-sectional area despite unchanged capillary length. The volume density (cm3/cm3) of cardiomyocytes was unchanged (0.881 +/- 0.01 vs. 0.871 +/- 0.016 in controls), but volume density of interstitial tissue (excluding capillary lumen) was significantly increased (0.042 +/- 0.011 cm3 interstitial tissue/cm3 total heart tissue vs. 0.019 +/- 0.007 in controls). This was associated with signs of activation of interstitial cells, that is, increased volume of interstitial cell nuclei and interstitial cell cytoplasm. Concomitantly, a significant increase of volume density of non-cellular interstitial ground substance was found which was not normalized by antihypertensive treatment using Ramipril. After three months of uremia, electron microscopy showed collagen fiber deposition in the interstitium. Comparable interstitial fibrosis was not observed in hearts of rats with renovascular (one clip-two kidney) hypertension. It is concluded that uremia increases myocardial interstitial ground substance by mechanisms independent of hypertension. The data may be relevant for recent findings of diastolic heart malfunction secondary to impaired compliance in uremic patients.
Changes in distribution of intrarenal blood flow were studied in anesthetized rats during the acute phase of postischemic renal failure (1 h renal artery occlusion, 1 h reflow). Distribution of capillary plasma flow was determined by injecting fluorescein-isothiocyanate-globulin and lissamine-rhodamine-B200-globulin 1, 3, or 10 min prior to rapid freezing of the kidney. In histological sections it was possible to differentiate among the vessels perfused during the time of labeling because of their respective fluorescence. In these experiments all glomeruli became labeled within 1 min, although in contrast to the controls, the glomerular capillary network itself was not filled completely in the postocclusion organs. Incomplete labeling was far more pronounced, however, in the postglomerular network of the occlusion experiments. Due to this effect in the cortex and in the medulla, 11 and 58% of tissue, respectively, were found lying at a distance of more than 60 microns from the next vessel labeled after 1 min of dye circulation. In the control experiments there was no tissue within this distance. Prolonging the time of labeling up to 10 min caused little change in this pattern of distribution. In the occlusion experiments, the globulins were observed in nearly all Bowman spaces, but in less than half of the tubular lumina. The results strengthen the view that the ischemic insult leads primarily to disturbance of the postglomerular perfusion, which then results in trophic damage of the tubular system mainly within the renal medulla.
Connexins are known to play an essential role in the ischemic preconditioning (IP) of the heart; their functional role in this process, however, has not been clearly defined. For this reason, anesthetized rats were subjected to regional myocardial ischemia, with or without IP or reperfusion. In frozen sections of hearts, fluorescence immunohistochemical staining for connexin43 (Cx43) was performed. In contrast to undisturbed zones, tissue that had been subjected to ischemia revealed Cx43 immunostaining not only in the gap junctions but also in a conspicuous pattern in the free cellular membranes of the myocytes. In myocardium that was exposed to IP only, the ratio of immunofluorescence intensity in the free cellular membrane to that in the interior of the cell was 1.22 +/- 0.04 (ratio in non-ischemia-exposed area = 1.04 +/- 0.01). When 15 or 45 min of permanent ischemia followed IP, the effect became more evident (ratio = 1.31 +/- 0.03 and 1.46 +/- 0.03, respectively) and proved to be significantly greater than in the corresponding non-IP groups (ratio = 1.16 +/- 0.03 and 1.30 +/- 0.03, respectively, P< 0.01). Reperfusion led to an overall weakening of fluorescence intensities and a disappearance of the observed IP-specific differences. We conclude that IP initiates a redistribution of Cx43 from its natural position in the gap junctions toward the free plasma membrane, thereby improving the cell's chance of survival during the subsequent phase of prolonged ischemia by an unknown, supposedly gap junction-independent, mechanism.
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