In practice, clinicians generally consider anemia (circulating hemoglobin concentration < 120 g.l−1 in non-pregnant females and < 130 g.l−1 in males) as due to impaired hemoglobin synthesis or increased erythrocyte loss or destruction. Rarely is a rise in plasma volume relative to circulating total hemoglobin mass considered as a cause. But does this matter? We explored this issue in patients, measuring hemoglobin concentration, total hemoglobin mass (optimized carbon monoxide rebreathing method) and thereby calculating plasma volume in healthy volunteers, surgical patients, and those with inflammatory bowel disease, chronic liver disease or heart failure. We studied 109 participants. Hemoglobin mass correlated well with its concentration in the healthy, surgical and inflammatory bowel disease groups (r=0.687–0.871, P<0.001). However, they were poorly related in liver disease (r=0.410, P=0.11) and heart failure patients (r=0.312, P=0.16). Here, hemoglobin mass explained little of the variance in its concentration (adjusted R2=0.109 and 0.052; P=0.11 and 0.16), whilst plasma volume did (R2 change 0.724 and 0.805 in heart and liver disease respectively, P<0.0001). Exemplar patients with identical (normal or raised) total hemoglobin masses were diagnosed as profoundly anemic (or not) depending on differences in plasma volume that had not been measured or even considered as a cause. The traditional inference that anemia generally reflects hemoglobin deficiency may be misleading, potentially resulting in inappropriate tests and therapeutic interventions to address ‘hemoglobin deficiency’ not ‘plasma volume excess’. Measurement of total hemoglobin mass and plasma volume is now simple, cheap and safe, and its more routine use is advocated.
Key pointsr Intermittent hypoxia leads to long-lasting increases in muscle sympathetic nerve activity and blood pressure, contributing to increased risk for hypertension in obstructive sleep apnoea patients.r We determined whether augmented vascular responses to increasing sympathetic vasomotor outflow, termed sympathetic neurovascular transduction (sNVT), accompanied changes in blood pressure following acute intermittent hypercapnic hypoxia in men.r Lower body negative pressure was utilized to induce a range of sympathetic vasoconstrictor firing while measuring beat-by-beat blood pressure and forearm vascular conductance. r IH reduced vascular shear stress and steepened the relationship between diastolic blood pressure and sympathetic discharge frequency, suggesting greater systemic sNVT.r Our results indicate that recurring cycles of acute intermittent hypercapnic hypoxia characteristic of obstructive sleep apnoea could promote hypertension by increasing sNVT.Abstract Acute intermittent hypercapnic hypoxia (IH) induces long-lasting elevations in sympathetic vasomotor outflow and blood pressure in healthy humans. It is unknown whether IH alters sympathetic neurovascular transduction (sNVT), measured as the relationship between sympathetic vasomotor outflow and either forearm vascular conductance (FVC; regional sNVT) or diastolic blood pressure (systemic sNVT). We tested the hypothesis that IH augments sNVT by exposing healthy males to 40 consecutive 1 min breathing cycles, each comprising 40 s of hypercapnic hypoxia (P ETCO 2 : +4 ± 3 mmHg above baseline; P ETO 2 : 48 ± 3 mmHg) and 20 s of Troy J. R. Stuckless is a native of Bayside, Ontario in Canada. He attained his Bachelor of Science in Kinesiology from Queen's University and practiced as a kinesiologist in Calgary before pursuing an Master of Science from the University of British Columbia's Okanagan Campus under the supervision of Dr Glen Foster. His research interests include vascular endothelial cell function and interactions between the autonomic nervous system and cardiovascular health. Troy is currently completing the Doctor of Dental Surgery Program at the University of Toronto.normoxia (n = 9), or a 40 min air-breathing control (n = 7). Before and after the intervention, lower body negative pressure (LBNP; 3 min at -15, -30 and -45 mmHg) was applied to elicit reflex increases in muscle sympathetic nerve activity (MSNA, fibular microneurography) when clamping end-tidal gases at baseline levels. Ventilation, arterial pressure [systolic blood pressure, diastolic blood pressure, mean arterial pressure (MAP)], brachial artery blood flow (Q BA ), FVC (Q BA /MAP) and MSNA burst frequency were measured continuously. Following IH, but not control, ventilation [5 L min -1 ; 95% confidence interval (CI) = 1-9] and MAP (5 mmHg; 95% CI = 1-9) were increased, whereas FVC (-0.2 mL min -1 mmHg -1 ; 95% CI = -0.0 to -0.4) and mean shear rate (-21.9 s -1 ; 95% CI = -5.8 to -38.0; all P < 0.05) were reduced. Systemic sNVT was increased following IH (0.25 mmHg burst -1...
Cerebrovascular CO2 reactivity (CVR) is often considered a bioassay of cerebrovascular endothelial function. We recently introduced a test of cerebral shear‐mediated dilatation (cSMD) that may better reflect endothelial function. We aimed to determine the nitric oxide (NO)‐dependency of CVR and cSMD. Eleven volunteers underwent a steady‐state CVR test and transient CO2 test of cSMD during intravenous infusion of the NO synthase inhibitor NG‐monomethyl‐l‐arginine (l‐NMMA) or volume‐matched saline (placebo; single‐blinded and counter‐balanced). We measured cerebral blood flow (CBF; duplex ultrasound), intra‐arterial blood pressure and PaCnormalO2${P_{{\rm{aC}}{{\rm{O}}_{\rm{2}}}}}$. Paired arterial and jugular venous blood sampling allowed for the determination of trans‐cerebral NO2− exchange (ozone‐based chemiluminescence). l‐NMMA reduced arterial NO2− by ∼25% versus saline (74.3 ± 39.9 vs. 98.1 ± 34.2 nM; P = 0.03). The steady‐state CVR (20.1 ± 11.6 nM/min at baseline vs. 3.2 ± 16.7 nM/min at +9 mmHg PaCnormalO2${P_{{\rm{aC}}{{\rm{O}}_{\rm{2}}}}}$; P = 0.017) and transient cSMD tests (3.4 ± 5.9 nM/min at baseline vs. −1.8 ± 8.2 nM/min at 120 s post‐CO2; P = 0.044) shifted trans‐cerebral NO2− exchange towards a greater net release (a negative value indicates release). Although this trans‐cerebral NO2− release was abolished by l‐NMMA, CVR did not differ between the saline and l‐NMMA trials (57.2 ± 14.6 vs. 54.1 ± 12.1 ml/min/mmHg; P = 0.49), nor did l‐NMMA impact peak internal carotid artery dilatation during the steady‐state CVR test (6.2 ± 4.5 vs. 6.2 ± 5.0% dilatation; P = 0.960). However, l‐NMMA reduced cSMD by ∼37% compared to saline (2.91 ± 1.38 vs. 4.65 ± 2.50%; P = 0.009). Our findings indicate that NO is not an obligatory regulator of steady‐state CVR. Further, our novel transient CO2 test of cSMD is largely NO‐dependent and provides an in vivo bioassay of NO‐mediated cerebrovascular function in humans. Key points Emerging evidence indicates that a transient CO2 stimulus elicits shear‐mediated dilatation of the internal carotid artery, termed cerebral shear‐mediated dilatation. Whether or not cerebrovascular reactivity to a steady‐state CO2 stimulus is NO‐dependent remains unclear in humans. During both a steady‐state cerebrovascular reactivity test and a transient CO2 test of cerebral shear‐mediated dilatation, trans‐cerebral nitrite exchange shifted towards a net release indicating cerebrovascular NO production; this response was not evident following intravenous infusion of the non‐selective NO synthase inhibitor NG‐monomethyl‐l‐arginine. NO synthase blockade did not alter cerebrovascular reactivity in the steady‐state CO2 test; however, cerebral shear‐mediated dilatation following a transient CO2 stimulus was reduced by ∼37% following intravenous infusion of NG‐monomethyl‐l‐arginine. NO is not obligatory for cerebrovascular reactivity to CO2, but is a key contributor to cerebral shear‐mediated dilatation.
We measured acute vascular responses to heat stress to examine the hypothesis that macrovascular endothelial-dependent dilation is improved in a shear-dependent manner, which is further modified by skin temperature. Twelve healthy males performed whole-body heating (+1.5°C esophageal temperature), bilateral forearm heating (~38°C skin temperature), and a time-matched (~60 min) control condition on separate days in counterbalanced order. Bilateral assessments of blood flow and brachial artery flow-mediated dilation (FMD) were performed before and 10 min after each condition protocols with duplex Doppler ultrasound. To isolate the influence of shear stress, a pneumatic cuff was inflated (~90 mmHg) around the right forearm during each condition to attenuate heat-induced rises in blood flow and shear stress. After forearm heating, FMD increased [cuffed: 4.7 (2.9) to 6.8 (1.5)%, non-cuffed: 5.1 (2.8) to 6.4 (2.6)%] in both arms (time P<0.01). Whole-body heating also increased FMD in the non-cuffed arm from 3.6 (2.2) to 9.2 (3.2)% and in the cuffed arm from to 5.6 (3.0)% to 8.6 (4.9)% (time P<0.01). After the time control, FMD decreased [cuffed: 6.3 (2.4) to 4.7 (2.2)%, non-cuffed: 6.1 (3.0) to 4.5 (2.6)%] in both arms (time P=0.03). Multiple linear regression (adjusted r2=0.263, P=0.003) revealed that changes in esophageal temperature, skin temperatures, and heart rate explained the majority of the variance in this model (34%, 31% and 21%, respectively). Our findings indicate that, in addition to shear stress, skin and core temperatures are likely important contributors to passive heating-induced vascular adaptations.
In contrast to [Hb], tHb-mass is an important determinant of physical fitness before major elective surgery. Further studies should determine whether low tHb-mass is predictive of poor outcome and whether targeted increases in tHb-mass might thus improve outcome.
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