Roland J. Beuk

Reflex sympathetic dystrophy: evolution of microcirculatory disturbances in time.

&NA; Reflex sympathetic dystrophy (RSD) is a pain syndrome that is characterised by autonomic, motor and sensory disturbances. The syndrome has often been associated with sympathetic dysfunction. Therefore, we investigated whether there are disturbances in the sympathetic function of skin microcirculation in the various clinical stages of RSD. Laser Doppler flowmetry (LDF) was used to obtain information about total (mainly thermoregulatory) skin blood flow (TSBF), since blood flow in arteriovenous anastomoses and subpapillary plexus, which are richly innervated by sympathetic nerve endings, contributes predominantly to the flow signal as obtained by LDF. Capillary microscopy was used to appraise whether the trophic changes, as observed in RSD, result from an impaired nutritive skin blood flow (NSBF). Transcutaneous oximetry (TCPO2) was employed as a measure of the oxygenation of superficial skin layers. Skin temperature (ST) was also determined. Patients were divided into 3 clinical stages: stage I in case of a chronic warmth sensation, stage II in case of an intermittent warmth and cold sensation, and stage III in case of a chronic cold sensation. As compared to controls: (1) TSBF was increased (P < 0.05) at stage I and decreased at stages II (P < 0.05) and III (P < 0.001), (2) NSBF was decreased at stages II (P < 0.05) and III (P < 0.001), (3) TCPO2 was not impaired at any stage, (4) ST was increased (P < 0.01) at stage I and decreased (P < 0.05) at stage III. The present study is the first to report an increase of TSBF at stage I of RSD, which may be caused by a decrease in efferent sympathetic nerve impulses. At stages II and III both TSBF and NSBF were decreased which may reflect increased sensitivity of skin microvessels to (circulating) catecholamines.

Total Warm Ischemia and Reperfusion Impairs Flow in All Rat Gut Layers but Increases Leukocyte–Vessel Wall Interactions in the Submucosa Only

OBJECTIVE To study the effect of warm ischemia and reperfusion (I/R) on local perfusion and leukocyte-vessel wall interactions in vivo in all small bowel layers, and to quantify small bowel tissue injury histologically and by measuring intestinal fatty acid binding protein (I-FABP) release from the enterocytes. SUMMARY BACKGROUND DATA Gut injury as a result of I/R plays a pivotal role in a variety of clinical conditions, such as small bowel transplantation, heart or aortic surgery, and (septic) shock. The precise mechanism behind I/R injury and the role of microvascular changes remain unclear. The influence of warm I/R of the gut on microvascular parameters in the different gut layers has not been studied before. METHODS Anesthetized Lewis rats were either subjected to 30 minutes of ischemia and 1 hour of reperfusion or sham-treated as controls. After ligating the inferior mesenteric artery, total warm ischemia was induced by clamping the superior mesenteric artery. Intravital video microscopic measurements were obtained at intervals. Tissue injury of the small bowel and other organs was histologically evaluated afterward. In addition, plasma levels of I-FABP were determined to measure enterocyte damage. RESULTS After ischemia, mean red blood cell velocity decreased significantly in all layers of the small bowel, but no diameter changes were observed. Leukocyte-vessel wall interactions increased in the submucosa but not in the muscle layers. Plasma levels of I-FABP significantly increased from 30 minutes of reperfusion onward. The intestinal mucosa was severely injured; no histologic damage was detected in other tissues. CONCLUSIONS This is the first in vivo study showing that total warm ischemia of the rat gut impairs perfusion in the whole small bowel, whereas leukocyte-vessel wall interactions increase in the submucosal layer only. Therefore, the early inflammatory response to I/R seems to be limited to the submucosa. Both microvascular effects may have contributed to the severe morphologic and functional mucosal injury observed after I/R.

Skin blood flow abnormalities in a rat model of neuropathic pain: Result of decreased sympathetic vasoconstrictor outflow?

Loose ligation of a sciatic nerve in rats provokes signs and symptoms like those observed in human conditions of neuropathic pain. Some of these have been associated with sympathetic dysfunction. Since the skin microcirculation in the rat is strongly influenced by sympathetic tone, abnormalities in skin blood flow may be used as an indirect measure of sympathetic dysfunction. We measured, by means of laser Doppler flowmetry, skin blood flow at the plantar surface of the rat hind paw before and after ipsilateral loose sciatic nerve ligation. We assessed basal skin blood flow as well as the vasoconstrictor response which follows cooling of the rat abdomen. The effectiveness of this response may be used as a measure of sympathetic vasoconstrictor outflow. As compared to the values obtained before ligation (= 100%): (1) the vasoconstrictor response was impaired (65%, P < 0.01) from day 1 onwards, whereas (2) basal skin blood flow was increased (171%; P < 0.01) from day 3 until day 5, and decreased (51%, P < 0.0001) from day 7 until day 28. At day 28, blockade of impulse propagation in the loosely ligated sciatic nerve (by means of lidocaine) did not increase the lowered level of skin blood flow. These findings suggest that in the chronic construction injury model loose ligation of a sciatic nerve reduces sympathetic vasoconstrictor outflow, which, in turn may induce supersensitivity of skin microvessels to catecholamines.

The influence of local skin heating and reactive hyperaemia on skin blood flow abnormalities in patients with reflex sympathetic dystrophy (RSD).

Abstract. Skin blood flow in reflex sympathetic dystrophy (RSD) patients has been reported to develop from an increase at an early stage to a decrease at later stages. So far, it remains unclear whether these abnormalities are solely of microcirculatory origin, and result from functional vasospasm or structural vessel wall changes. Eighty‐seven RSD patients were categorized as follows: stage I in case of a stationary warmth sensation; stage II in case of an intermittent warmth and cold sensation; and stage III in case of a stationary cold sensation. Laser Doppler flowmetry (LDF) was used as a measure of total skin blood flow and transcutaneous oximetry (TCPO2) as a measure of vascular reactivity in the more superficial skin layers. Local skin heating and reactive hyperaemia were used to study the relative reserve capacity of skin microvessels. Finapres was used to assess digital arterial pressures. As compared to healthy volunteers (n=16), LDF under control conditions demonstrated an increase in skin blood flow at stage I (P<0.01). A decrease in skin blood flow under control conditions was seen at stages II (P<0.05) and III (P<0.05), but the relative flow reserve capacity, as measured with LDF, was not impaired at these stages. Regression analysis did not show a relation between LDF parameters and duration of the syndrome. TCPO2 revealed no differences between patient groups and controls. Regression analysis did not demonstrate a relation between TCPO2 parameters and duration of the syndrome. Digital systolic blood pressures were increased at stages II (P<0.05) and III (p<0.001). These findings indicate that abnormalities in skin blood flow, as observed in RSD patients, are of microcirculatory origin. The observed decrease in skin blood flow at stages II and III most likely results from functional vasospasm rather than from structural vessel wall changes.

Ischemia/reperfusion injury in rat mesenteric venules: Red blood cell velocity and leukocyte rolling

The authors determined the effects of 15 (n = 9) and 30 (n = 12) minutes of warm ischemia on the rat mesentery and compared the results with those of a sham-operated group (n = 10). Red blood cell velocity and number of rolling leukocytes were assessed before ischemia as well as 10, 20, 30, 60, 90, and 120 minutes after the start of reperfusion. Leukocyte rolling is considered to be an early step of the inflammatory process. Leukocytes roll along the vessel wall at a velocity that is clearly lower than that of the other blood cells. The preischemic values of red blood cell velocity and number of rolling leukocytes in the 15- and 30-minute ischemia groups did not differ from those of the sham group. In the sham group, no significant changes in red blood cell velocity and number of rolling leukocytes were observed over time. Compared with the sham group, the red blood cell velocity of the 15-minute ischemia group was significantly lower at 30, 60, 90, and 120 minutes after the start of reperfusion the number of rolling leukocytes did not differ significantly. For the 30-minute ischemia group, red blood cell velocity also was significantly lower at 20, 30, 60, 90, and 120 minutes after the start of reperfusion, and the number of rolling leukocytes was higher at 10, 20, and 30 minutes after the start of reperfusion. The results of this study indicate that short periods of total warm ischemia of the rat small bowel and subsequent reperfusion result in a significantly impaired microcirculatory blood flow in the mesentery. However, a prolonged period of ischemia is required to increase leukocyte-vessel wall interactions. In the future, this model will enable us to study the effect of pharmacological interventions during an early stage of the inflammatory response to ischemia/reperfusion in the gut.

Effect of repetitive asphyxia on leukocyte-vessel wall interactions in the developing chick intestine

BACKGROUND/PURPOSE Information on leukocyte-vessel wall interactions (LVWI) during development of the immature intestine is scarce. The authors designed an experimental model for studying the microcirculation in the developing intestine of chick fetuses at days 13 (n = 12), 15 (n = 17), and 17 (n = 19) of incubation (0.6, 0.7, and 0.8 of the incubation time, respectively) using intravital microscopy. METHODS The authors investigated whether episodes of asphyxia increase LVWI and induce tissue damage in the developing intestine. Asphyxia was induced by clamping of the chorioallantoic vein for 6 periods of 5 minutes each, with 5-minute intervals, whereas in sham groups a sham procedure was performed. Video recordings were made before as well as 10, 20, and 30 minutes after the end of the asphyxia or sham protocol. RESULTS Baseline number of rolling leukocytes per minute significantly increased (P < .001) from 0 at 0.6 incubation to 1.5 and to 4 at 0.7 and 0.8 incubation time, respectively. At 0.6 and 0.7 incubation no adherent leukocytes were observed under baseline conditions, whereas at 0.8 incubation single leukocytes adhered to the venular wall. LVWI variably increased during the course of the experiments. Asphyxia neither enhanced LVWI nor induced histological damage in the intestine. CONCLUSIONS These findings indicate that (1) leukocyte-vessel wall interactions mature during fetal development, and (2) repetitive episodes of asphyxia induce neither an inflammatory response nor histological tissue injury in the developing intestine from 0.6 to 0.8 incubation. The authors hypothesize that immaturity of leukocyte-vessel wall interactions, as part of the nonspecific host defense to invading bacteria, might play a role in the development of necrotizing enterocolitis in premature neonates.