The painful vaso-occlusive crises (VOC) that characterize sickle cell disease (SCD) progress over hours from the asymptomatic steady-state. SCD patients report that VOC can be triggered by stress, cold exposure and pain itself. We anticipated that pain could cause neural-mediated vasoconstriction, decreasing regional blood flow and promoting entrapment of sickle cells in the microvasculature. Therefore, we measured microvascular blood flow in the fingers of both hands using plethysmography and laser-Doppler flowmetry while applying a series of painful thermal stimuli on the right forearm in 23 SCD patients and 25 controls. Heat pain applied to one arm caused bilateral decrease in microvascular perfusion. The vasoconstriction response started before administration of the thermal pain stimulus in all subjects, suggesting that pain anticipation also causes significant vasoconstriction. The time delay between thermal pain application and global vasoconstriction ranged from 5 to 15.5 seconds and increased with age (p < 0.01). Although subjective measures, pain threshold and pain tolerance were not different between SCD subjects and controls, but the vaso-reactivity index characterizing the microvascular blood flow response to painful stimuli was significantly higher in SCD patients (p = .0028). This global vasoconstriction increases microvascular transit time, and may promote entrapment of sickle cells in the microvasculature, making vaso-occlusion more likely. The rapidity of the global vasoconstriction response indicates a neural origin that may play a part in the transition from steady-state to VOC, and may also contribute to the variability in VOC frequency observed in SCD patients.
Painful vaso-occlusive crisis (VOC), a complication of sickle cell disease (SCD), occurs when sickled red blood cells obstruct flow in the microvasculature. We postulated that exaggerated sympathetically mediated vasoconstriction, endothelial dysfunction and the synergistic interaction between these two factors act together to reduce microvascular flow, promoting regional vaso-occlusions, setting the stage for VOC. We previously found that SCD subjects had stronger vasoconstriction response to pulses of heat-induced pain compared to controls but the relative degrees to which autonomic dysregulation, peripheral vascular dysfunction and their interaction are present in SCD remain unknown. In the present study, we employed a mathematical model to decompose the total vasoconstriction response to pain into: 1) the neurogenic component, 2) the vascular response to blood pressure, 3) respiratory coupling and 4) neurogenic-vascular interaction. The model allowed us to quantify the contribution of each component to the total vasoconstriction response. The most salient features of the components were extracted to represent biophysical markers of autonomic and vascular impairment in SCD and controls. These markers provide a means of phenotyping severity of disease in sickle-cell anemia that is based more on underlying physiology than on genotype. The marker of the vascular component (BMv) showed stronger contribution to vasoconstriction in SCD than controls (p = 0.0409), suggesting a dominant myogenic response in the SCD subjects as a consequence of endothelial dysfunction. The marker of neurogenic-vascular interaction (BMn-v) revealed that the interaction reinforced vasoconstriction in SCD but produced vasodilatory response in controls (p = 0.0167). This marked difference in BMn-v suggests that it is the most sensitive marker for quantifying combined alterations in autonomic and vascular function in SCD in response to heat-induced pain.
Sickle cell disease (SCD) subjects exhibit subjective hypersensitivity to cold and heat perception in experimental settings, and triggers such as cold exposure are known to precipitate vaso-occlusive crisis by still unclear mechanisms. Decreased microvascular blood flow (MBF) increases the likelihood of vaso-occlusion by increasing entrapment of sickled red blood cells in the microvasculature. As SCD subjects have dysautonomia, we anticipated that thermal exposure would induce autonomic hypersensitivity of their microvasculature with an increased propensity towards vasoconstriction. We exposed 17 SCD and 16 control subjects to a sequence of predetermined threshold temperatures for cold and heat detection as well as cold and heat pain via a thermode placed on the right hand. MBF was measured on the contralateral hand using photo-plethysmography, and cardiac autonomic balance was assessed using heart rate variability. Thermal stimuli at both detection and pain thresholds caused significant decrease in MBF in the contralateral hand within seconds of stimulus application, with SCD subjects showing significantly stronger vasoconstriction (p=0.019). Furthermore, SCD subjects showed greater progressive decrease in blood flow than controls, with poor recovery between episodes of thermal stimulation (p=0.042). SCD subjects had faster vasoconstriction than controls (p=0.033), especially with cold detection stimulus; individuals with higher anxiety also vasoconstricted faster (p=0.007). Augmented vasoconstriction responses and progressive decrease in perfusion with repeated thermal stimulation in SCD is indicative of autonomic hypersensitivity in the microvasculature. This is likely to increase red cell entrapment in response to clinical triggers like cold or stress that have been associated with vaso-occlusive crisis in SCD.
Sickle cell disease (SCD) is a monogenic hemoglobinopathy associated with significant morbidity and mortality. Cardiopulmonary, vascular and sudden death are the reasons for the majority of young adult mortality in SCD. To better understand the clinical importance of multi‐level vascular dysfunction, in 2009 we assessed cardiac function including tricuspid regurgitant jet velocity (TRV), tissue velocity in systole(S′) and diastole (E′), inflammatory, rheologic and hemolytic biomarkers as predictors of mortality in patients with SCD. With up to 9 years of follow up, we determined survival in 95 children, adolescents and adults with SCD. Thirty‐eight patients (40%) were less than 21 years old at initial evaluation. Survival and Cox proportional‐hazards analysis were performed. There was 19% mortality in our cohort, with median age at death of 35 years. In the pediatric subset, there was 11% mortality during the follow up period. The causes of death included cardiovascular and pulmonary complications in addition to other end‐organ failure. On Cox proportional‐hazards analysis, our model predicts that a 0.1 m/s increase in TRV increases risk of mortality 3%, 1 cm/s increase in S′ results in a 91% increase, and 1 cm/s decrease in E′ results in a 43% increase in mortality. While excluding cardiac parameters, higher plasma free hemoglobin was significantly associated with risk of mortality (p=.049). In conclusion, elevated TRV and altered markers of cardiac systolic and diastolic function predict mortality in a cohort of adolescents and young adult patients with SCD. These predictors should be considered when counseling cardiovascular risk and therapeutic optimization at transition to adult providers.
PurposeThe purpose of this work was to noninvasively detect and quantify microvascular blood flow changes in response to externally applied pain in humans. The responsiveness of the microvasculature to pain stimulation might serve as an objective biomarker in diseases associated with altered pain perception and dysregulated vascular functions. The availability of such a biomarker may be useful as a tool for predicting outcome and response to treatments, particularly in diseases like sickle cell anemia where clinical manifestations are directly linked to microvascular perfusion. We, therefore, developed a method to distinguish the blood flow response due to the test stimulus from the blood flow measurement that also includes concurrent flow changes from unknown origins.Subjects and methodsWe measured the microvascular blood flow response in 24 healthy subjects in response to a train of randomly spaced and scaled heat pulses on the anterior forearm. The fingertip microvascular perfusion was measured using laser Doppler flowmetry. The cross-correlation between the heat pulses and the blood flow response was computed and tested for significance against the null distribution obtained from the baseline recording using bootstrapping method.ResultsWe estimated correlation coefficients, response time, response significance, and the magnitude of vasoreactivity from microvascular blood flow responses. Based on these pain response indices, we identified strong responders and subjects who did not show significant responses.ConclusionThe cross-correlation of a random pattern of painful stimuli with directly measured microvascular flow can detect vasoconstriction responses in a noisy blood flow signal, determine the time between stimulus and response, and quantify the magnitude of this response. This approach provided an objective measurement of vascular response to pain that may be an inherent characteristic of individual human subjects, and may also be related to the severity of vascular disorders.
INTRODUCTION: Sickle cell disease is an inherited blood disorder characterized by vaso-occlusive crises (VOC). HbS in red blood cells (RBC) polymerizes rapidly after it releases oxygen to tissues, causing RBC to become rigid. Anything that decreases flow in the microvasculature increases the chance that this flexible-to-rigid transformation occurs causing the rigid blood cell to lodge in the microvasculature, therefore increasing the chance of vaso-occlusion and the risk of VOC. Although hypoxia and stress are known risk factors for crises, the exact mechanism that initiates VOC events is not well known. We have previously shown that transient hypoxia causes parasympathetic withdrawal and sighs cause vasoconstriction more frequently in SCD subjects than in normal controls. Pain is the hallmark of SCD and is a consequence of VOC but has not been considered as a possible trigger of vasoconstriction that may lead to VOC. OBJECTIVES: To determine if heat induced pain causes decrease in peripheral blood flow (PBF) in SCD. METHODS: 30 SCD and 30 control subjects (healthy and sickle cell traits) were recruited at Children's Hospital Los Angeles (CHLA). Quasi-periodic pulses of pain were induced on the right forearm using TSA-II neuro analyzer heating thermode. We implemented a technique using cross correlation analysis to detect changes in complex microvascular flow signals measured bilaterally on the hands, using laser-Doppler flowmeter (LDF), Peripheral Arterial Tonometer (PAT) and photo-plethysmography (PPG). We also measured the average drop from baseline in the microvascular flow during the heat pain. Data were analyzed using one- and two- sample Student t-test. RESULTS: Data on 53 subjects were analyzed. There was a significant correlation between heat pain pulses and PBF responses, as well as a significant drop in blood flow in all study participants (PPG signal, both p<0.001), indicating that heat pain pulses lead to vasoconstriction. Males had higher correlation (p<0.005) and stronger vasoconstriction (p<0.05) during heat stimuli compared to females. Other Signals (LDF and PAT) had a similar pattern but were less significant. The vasoconstriction response consisted of two components, the first one occurred prior to administration of the painful stimulus indicating that anxiety or anticipation of pain causes significant vasoconstriction. Application of the painful stimulus causes further vasoconstriction. CONCLUSIONS: The findings demonstrate a significant decrease in PBF in both SCD and controls in response to heat pain and possibly to pain anticipation. The decrease in PBF could play a critical role in the genesis of VOC in SCD by markedly prolonging microvascular transit time, increasing the likelihood of red cell entrapment when sickle red cells transform from flexible to rigid. Furthermore, the potent vasoconstriction response to pain in SCD means that pain resulting from VOC could potentially trigger a cascade effect in which vasoconstriction could lead to even more serious VOC. Since regional blood flow is regulated by the autonomic nervous system (ANS), which has been described to be dysfunctional in SCD, our study calls attention to the ANS as a factor in the genesis of crisis in this disorder. Disclosures No relevant conflicts of interest to declare.
Recent studies have shown that individuals with sickle cell disease (SCD) exhibit greater vasoconstriction responses to physical autonomic stressors, such as heat pain and cold pain than normal individuals, but this is not the case for mental stress (MTS). We sought to determine whether this anomalous finding for MTS is related to inter-group differences in baseline cardiac and vascular autonomic function. Fifteen subjects with SCD and 15 healthy volunteers participated in three MTS tasks: N-back, Stroop, and pain anticipation (PA). R–R interval (RRI), arterial blood pressure and finger photoplethysmogram (PPG) were continuously monitored before and during these MTS tasks. The magnitude of vasoconstriction was quantified using change in PPG amplitude (PPGa) from the baseline period. To represent basal autonomic function, we assessed both cardiac and vascular arms of the baroreflex during the baseline period. Cardiac baroreflex sensitivity (BRSc) was estimated by applying both the “sequence” and “spectral” techniques to beat-to-beat measurements of systolic blood pressure and RRIs. The vascular baroreflex sensitivity (BRSv) was quantified using the same approaches, modified for application to beat-to-beat diastolic blood pressure and PPGa measurements. Baseline BRSc was not different between SCD and non-SCD subjects, was not correlated with BRSv, and was not associated with the vasoconstriction responses to MTS tasks. BRSv in both groups was correlated with mean PPGa, and since both baseline PPGa and BRSv were lower in SCD, these results suggested that the SCD subjects were in a basal state of higher sympathetically mediated vascular tone. In both groups, baseline BRSv was positively correlated with the vasoconstriction responses to N-back, Stroop, and PA. After adjusting for differences in BRSv within and between groups, we found no difference in the vasoconstriction responses to all three mental tasks between SCD and non-SCD subjects. The implications of these findings are significant in subjects with SCD since vasoconstriction reduces microvascular flow and prolongs capillary transit time, increasing the likelihood for vaso-occlusive crisis (VOC) to be triggered by exposure to stressful events.
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