The prevalence and impact of orthostatic intolerance in young women across the hypermobility spectrum.

Orthostatic intolerance (OI) is frequently reported in young women with generalized hypermobility spectrum disorder (G-HSD) and hypermobile EDS (hEDS). However, it remains currently unclear whether OI is a comorbidity or fundamental part of the pathophysiology of G-HSD or hEDS. This study investigated the prevalence and impact of OI in young women across the hypermobility spectrum. Forty-five women (14-30 years, 15 controls, 15 G-HSD, and 15 hEDS) undertook a head-up tilt (HUT) and active stand test. Postural Orthostatic Tachycardia Syndrome (POTS) and Orthostatic Hypotension (OH) were assessed using age-related criteria. Autonomic dysfunction and quality-of-life questionnaires were also completed. The prevalence of POTS was higher in women with G-HSD than hEDS and control groups during HUT (43% vs. 7% and 7%, respectively, p < 0.05), but similar between groups during the active stand (47%, 27%, and 13% for G-HSD, hEDS, and control, respectively). No participants had OH. hEDS and G-HSD participants reported more severe orthostatic symptoms and poorer quality of life than controls. Although POTS was observed in hypermobile participants, there is no conclusive evidence that its prevalence differed between groups due to differences between the HUT and active stand assessments. Nevertheless, OI and broader autonomic dysfunction impacted on their quality of life.

Assessing breast lymphoedema following breast cancer treatment using indocyanine green lymphography.

PURPOSE: Breast lymphoedema is a largely unrecognised survivorship issue for women following breast cancer treatment. While a few objective methods have previously been applied to assess breast lymphoedema, none are capable of imaging breast lymphatics or identifying lymphatic morphological changes indicative of breast lymphoedema. The purpose of this study was to determine if indocyanine green (ICG) lymphography, a validated assessment technique in breast cancer-related lymphoedema), can visualise breast lymphatics and identify breast lymphoedema. Additionally, ICG lymphography was utilised to investigate lymphatic drainage pathways of the affected breast following breast-conserving therapy. METHODS: Twenty female participants (10 breast lymphoedema and 10 healthy controls) were recruited for this pilot study. All underwent a medical history, physical breast assessment, tissue dielectric constant measures of breast water content, and ICG lymphography. RESULTS: ICG lymphography identified lymphatic morphological changes in all breast lymphoedema participants (dermal backflow patterns = 10, collateral lymphatic drainage = 9) and none in the control group. The dominant lymphatic drainage pathway to the ipsilateral axilla was observed in all control participants but in only four breast lymphoedema participants. Collateral drainage pathways in the breast lymphoedema group were to: parasternal (6/10); contralateral axilla (4/10); intercostal (3/10); and clavicular (2/10) regions. CONCLUSION: These findings suggest ICG lymphography, through the identification of morphological lymphatic changes, is a potential qualitative objective assessment technique for breast lymphoedema. Furthermore, in this group of breast lymphoedema patients it identified changes to the normal drainage pathway of the breast. Understanding these changes will have implications for clinical management.

The use and effectiveness of exercise for managing postural orthostatic tachycardia syndrome in young adults with joint hypermobility and related conditions: A scoping review.

PURPOSE: Postural Orthostatic Tachycardia Syndrome (POTS) is a form of dysautonomia. It may occur in isolation, but frequently co-exists in individuals with hypermobile variants of Ehlers-Danlos Syndrome (EDS) and related conditions (chronic fatigue syndrome [CFS] and fibromyalgia). Exercise is recommended for non-pharmacological POTS management but needs to be individualised. This scoping review explores the current literature on use and effectiveness of exercise-based management for POTS, with specific focus on individuals with joint hypermobility and related conditions who experience hypermobility, and/or pain, and/or fatigue. METHODS: A systematic search, to January 2023, of Medline, EMBASE, AMED, CINAHL and the Cochrane library was conducted. Studies that reported on adolescents and adults who had been diagnosed with POTS using standard criteria and underwent an exercise-based training intervention were included. RESULTS: Following full-text screening, 10 articles were identified (2 randomised control trials, 4 comparative studies and 4 case reports). One comparative study reported a small subset of participants with EDS and one case report included an individual diagnosed with CFS; the remainder investigated a wider POTS population. Overall, 3 months of endurance followed by resistance exercise, graduating from the horizontal-to-upright position reduced POTS symptoms and improved quality-of-life. CONCLUSION: The findings highlight a paucity of higher-level studies documenting exercise for POTS management in people with joint hypermobility and related conditions. Results from the wider POTS population demonstrate exercise is safe and effective. Large, well-designed clinical studies exploring exercise for POTS management adapting to meet the complex musculoskeletal and non-musculoskeletal features of symptomatic joint hypermobility are needed.

Interaction of large artery stiffness and baroreceptor function explored through multiple measurement techniques - a pilot study.

Baroreceptors, sensors that play a role in controlling arterial blood pressure (BP), are mechanical stretch receptors located in the aortic arch and carotid sinuses. Factors affecting the degree of stretch in the vessel wall with BP, such as increased arterial stiffness, may compromise baroreceptor sensitivity (BRS) to BP changes. Yet, evidence of this is scattered, as both baroreceptor sensitivity (BRS) and arterial stiffness are calculated variables with multiple methodological approaches. This pilot study (n=10) investigates the correlation of arterial stiffness and BRS using multiple BRS calculation techniques (spectral and sequence methodologies at aortic and finger sites) and arterial stiffness measurement [carotid-femoral pulse wave velocity (cfPWV), carotid compliance and distensibility]. BRS was assessed under resting BP conditions and during BP altered by maneuvers (0.1 Hz controlled breathing and leg ischemia). Magnitude of arterial stiffness - BRS correlation was positive for carotid distensibility and compliance, and negative for cfPWV, supporting the theory. A sample size of 100 participants (not rounded - exact figure by power calculation) would be required to confirm or reject all permutations of correlation between BRS by multiple calculation methods and large artery stiffness by PWV and compliance/distensibility measures.

Effects of acetazolamide on cerebrovascular function and breathing stability at 5050 m.

One of the many actions of the carbonic anhydrase inhibitor, acetazolamide (ACZ), is to accelerate acclimatisation and reduce periodic breathing during sleep. The mechanism(s) by which ACZ may improve breathing stability, especially at high altitude, remain unclear. We tested the hypothesis that acute I.V. ACZ would enhance cerebrovascular reactivity to CO2 at altitude, and thereby lower ventilatory drive and improve breathing stability during wakefulness. We measured arterial blood gases, minute ventilation (˙VE) and middle cerebral artery blood flow velocity (MCAv) before and 30 min following ACZ administration (I.V. 10 mg kg⁻¹) in 12 healthy participants at sea level and following partial acclimatisation to altitude (5050 m).Measures were made at rest and during changes in end-tidal PCO2 and PO2 (isocapnic hypoxia). At sea level, ACZ increased resting MCAv and its reactivity to both hypocapnia and hypercapnia (P < 0.05), and lowered resting VE, arterial O2 saturation (Sa,O2 ) and arterial PO2 (Pa,O2) (P < 0.05); arterial PCO2 (Pa,CO2 ) was unaltered (P > 0.05). At altitude, ACZ also increased resting MCAv and its reactivity to both hypocapnia and hypercapnia (resting MCAv and hypocapnia reactivity to a greater extent than at sea level). Moreover, ACZ at altitude elevated Pa,CO2 and again lowered resting Pa,O2 and Sa,O2 (P <0.05). Although the ˙VE sensitivity to hypercapnia or isocapnic hypoxia was unaltered following ACZ at both sea level and altitude (P > 0.05), breathing stability at altitude was improved (e.g. lower incidence of ventilatory oscillations and variability of tidal volume; P < 0.05). Our data indicate that I.V. ACZ elevates cerebrovascular reactivity and improves breathing stability at altitude, independent of changes in peripheral or central chemoreflex sensitivities. We speculate that Pa,CO2-mediated elevations in cerebral perfusion and an enhanced cerebrovascular reactivity may partly account for the improved breathing stability following ACZ at high altitude.

Inspiratory muscle reflex control after incomplete cervical spinal cord injury.

In healthy individuals, loading inspiratory muscles by brief inspiratory occlusion produces a short-latency inhibitory reflex (IR) in the electromyographic (EMG) activity of scalene and diaphragm muscles. This IR may play a protective role to prevent aspiration and airway collapse during sleep. In people with motor and sensory complete cervical spinal cord injury (cSCI), who were able to breathe independently, this IR was predominantly absent. Here, we investigated the reflex response to brief airway occlusion in 16 participants with sensory incomplete cSCI [American spinal injury association impairment scale (AIS) score B or C]. Surface EMG was recorded from scalene muscles and the lateral chest wall (overlying diaphragm). The airway occlusion evoked a small change in mouth pressure resembling a physiological occlusion. The short-latency IR was present in 10 (63%) sensory incomplete cSCI participants; significantly higher than the IR incidence observed in complete cSCI participants in our previous study (14%; P = 0.003). When present, mean IR latency across all muscles was 58 ms (range 29-79 ms), and mean rectified EMG amplitude decreased to 37% preocclusion levels. Participants without an IR had untreated severe obstructive sleep apnea (OSA), in contrast to those with an IR, who had either had no, mild, or treated OSA (P = 0.002). Insufficient power did not allow statistical comparison between IR presence or absence and participant clinical characteristics. In conclusion, spared sensory connections or intersegmental connections may be necessary to generate the IR. Future studies to establish whether IR presence is related to respiratory morbidity in the tetraplegic population are required.NEW & NOTEWORTHY Individuals with incomplete cSCI were tested for the presence of a short latency reflex inhibition of inspiratory muscles, by brief airway occlusion. The reflex was 4.5 times more prevalent in this group compared with those with complete cSCI and is similar to the incidence in able-bodied people. Participants without this reflex all had untreated severe OSA, in contrast to those with an IR, who either had no, mild, or treated OSA. This work reveals novel differences in the reflex control of inspiratory muscles across the cSCI population.

Alterations in cerebral blood flow and cerebrovascular reactivity during 14 days at 5050 m.

Brain blood flow increases during the first week of living at high altitude. We do not understand completely what causes the increase or how the factors that regulate brain blood flow are affected by the high-altitude environment. Our results show that the balance of oxygen (O(2)) and carbon dioxide (CO(2)) pressures in arterial blood explains 40% of the change in brain blood flow upon arrival at high altitude (5050 m). We also show that blood vessels in the brain respond to increases and decreases in CO(2) differently at high altitude compared to sea level, and that this can affect breathing responses as well. These results help us to better understand the regulation of brain blood flow at high altitude and are also relevant to diseases that are accompanied by reductions in the pressure of oxygen in the blood.

Influence of indomethacin on the ventilatory and cerebrovascular responsiveness to hypoxia.

Indomethacin (INDO) has the potential to be a useful tool to explore the influence of cerebral blood flow and its responses to CO(2) on ventilatory control. However, the effect of INDO on the cerebrovascular and ventilatory response to hypoxia remains unclear; therefore, we examined the effect of INDO on ventilatory and cerebrovascular sensitivity to hypoxia and hypercapnia. We measured end-tidal gases, ventilation (V(e)), and middle cerebral artery velocity (MCAv) before and 90 min following INDO (100 mg) in 12 healthy participants at rest and during hyperoxic hypercapnia and isocapnic hypoxia. Following INDO, resting VE and end-tidal gases were unaltered (P > 0.05), whilst MCAv was lowered by 25 ± 19% (P < 0.001). INDO ingestion reduced MCAv-CO(2) reactivity by 46 ± 29% (2.9 ± 0.9 vs. 1.7 ± 0.9 cm s(-1) mmHg(-1); P < 0.001) and enhanced the VE-CO(2) sensitivity by 0.5 ± 0.5 L min(-1) mmHg(-1) (1.9 ± 1.5 vs. 2.3 ± 1.6 L min(-1) mmHg(-1); P < 0.05). No changes were observed in either the MCAv or VE responsiveness to isocapnic hypoxia following INDO ingestion (P > 0.05). These findings indicate that INDO does not alter cerebrovascular and ventilatory responsiveness to hypoxia, indicating a preserved peripheral chemoreflex in response to this pharmacological agent.

Influence of high altitude on cerebrovascular and ventilatory responsiveness to CO2.

An altered acid-base balance following ascent to high altitude has been well established. Such changes in pH buffering could potentially account for the observed increase in ventilatory CO(2) sensitivity at high altitude. Likewise, if [H(+)] is the main determinant of cerebrovascular tone, then an alteration in pH buffering may also enhance the cerebral blood flow (CBF) responsiveness to CO(2) (termed cerebrovascular CO(2) reactivity). However, the effect altered acid-base balance associated with high altitude ascent on cerebrovascular and ventilatory responsiveness to CO(2) remains unclear. We measured ventilation , middle cerebral artery velocity (MCAv; index of CBF) and arterial blood gases at sea level and following ascent to 5050 m in 17 healthy participants during modified hyperoxic rebreathing. At 5050 m, resting , MCAv and pH were higher (P < 0.01), while bicarbonate concentration and partial pressures of arterial O(2) and CO(2) were lower (P < 0.01) compared to sea level. Ascent to 5050 m also increased the hypercapnic MCAv CO(2) reactivity (2.9 +/- 1.1 vs. 4.8 +/- 1.4% mmHg(1); P < 0.01) and CO(2) sensitivity (3.6 +/- 2.3 vs. 5.1 +/- 1.7 l min(1) mmHg(1); P < 0.01). Likewise, the hypocapnic MCAv CO(2) reactivity was increased at 5050 m (4.2 +/- 1.0 vs. 2.0 +/- 0.6% mmHg(1); P < 0.01). The hypercapnic MCAv CO(2) reactivity correlated with resting pH at high altitude (R(2) = 0.4; P < 0.01) while the central chemoreflex threshold correlated with bicarbonate concentration (R(2) = 0.7; P < 0.01). These findings indicate that (1) ascent to high altitude increases the ventilatory CO(2) sensitivity and elevates the cerebrovascular responsiveness to hypercapnia and hypocapnia, and (2) alterations in cerebrovascular CO(2) reactivity and central chemoreflex may be partly attributed to an acid-base balance associated with high altitude ascent. Collectively, our findings provide new insights into the influence of high altitude on cerebrovascular function and highlight the potential role of alterations in acid-base balance in the regulation in CBF and ventilatory control.

Influence of indomethacin on ventilatory and cerebrovascular responsiveness to CO2 and breathing stability: the influence of PCO2 gradients.

Indomethacin (INDO), a reversible cyclooxygenase inhibitor, is a useful tool for assessing the role of cerebrovascular reactivity on ventilatory control. Despite this, the effect of INDO on breathing stability during wakefulness has yet to be examined. Although the effect of reductions in cerebrovascular CO(2) reactivity on ventilatory CO(2) sensitivity is likely dependent upon the method used, no studies have compared the effect of INDO on steady-state and modified rebreathing estimates of ventilatory CO(2) sensitivity. The latter method includes the influence of PCO(2) gradients and cerebral perfusion, whereas the former does not. We examined the hypothesis that INDO-induced reduction in cerebrovascular CO(2) reactivity would 1) cause unstable breathing in conscious humans and 2) increase ventilatory CO(2) sensitivity during the steady-state method but not during rebreathing methods. We measured arterial blood gases, ventilation (VE), and middle cerebral artery velocity (MCAv) before and 90 min following INDO ingestion (100 mg) or placebo in 12 healthy participants. There were no changes in resting arterial blood gases or Ve following either intervention. INDO increased the magnitude of Ve variability (index of breathing stability) during spontaneous air breathing (+4.3 +/- 5.2 Deltal/min, P = 0.01) and reduced MCAv (-25 +/- 19%, P < 0.01) and MCAv-CO(2) reactivity during steady-state (-47 +/- 27%, P < 0.01) and rebreathing (-32 +/- 25%, P < 0.01). The Ve-CO(2) sensitivity during the steady-state method was increased with INDO (+0.5 +/- 0.5 l x min(-1) x mmHg(-1), P < 0.01), while no changes were observed during rebreathing (P > 0.05). These data indicate that the net effect of INDO on ventilatory control is an enhanced ventilatory loop gain resulting in increased breathing instability. Our findings also highlight important methodological and physiological considerations when assessing the effect of INDO on ventilatory CO(2) sensitivity, whereby the effect of INDO-induced reduction of cerebrovascular CO(2) reactivity on ventilatory CO(2) sensitivity is unmasked with the rebreathing method.

Clinical screening of autonomic dysfunction in multiple sclerosis.

BACKGROUND AND PURPOSE: Multiple sclerosis (MS) can affect the autonomic nervous system. Although exercise may be beneficial for people with MS, those with autonomic dysfunction may have altered heart rate responses to exercise. We investigated the hypothesis that the pattern of increase in heart rate on commencement of a simple cycle test would be different in those participants with MS who had been shown to have autonomic dysfunction on laboratory testing compared with both control participants and MS participants not exhibiting autonomic involvement. METHOD: A controlled cohort study with a volunteer sample of 31 adults with MS (26 women, 5 men) with a mean age of 46 +/- 8.00 years (32-60 years), a median Expanded Disability Severity Scale of 3 (1-6) and a mean duration since diagnosis of 10.3 years (0.1-39 years). Thirty-one age-matched, non-disabled, sedentary but healthy adults (26 women, 5 men) with a mean age of 45 +/- 9.5 years (24-57) comprised the control group. Autonomic function was evaluated using continuous heart rate and blood pressure responses to rhythmical deep breathing, the Valsalva manoeuvre, passive postural change and a simple cycle test. RESULTS: There were no significant differences in age, height or weight (p < 0.05) between the two groups or on any of the autonomic test results (p < 0.05). Five participants with MS (16%) had abnormal autonomic function on laboratory testing, two of whom demonstrated an abnormal heart rate response to the cycle test. CONCLUSIONS: It is suggested that physiotherapists monitor the heart rate response to a dynamic exercise test in people with MS prior to prescribing an exercise programme to ensure patients' safety. Should the response appear delayed or attenuated, referral for more formal autonomic laboratory testing is recommended.

Distress during airway sampling in children with cystic fibrosis.

BACKGROUND: Oropharyngeal suction and oropharyngeal swab are two methods of obtaining airway samples with similar diagnostic accuracy in children with cystic fibrosis (CF). The primary aim was comparing distress between suctioning and swabbing. A secondary aim was establishing the reliability of the Groningen Distress Rating Scale (GDRS). METHODS: Randomised oropharyngeal suction or swab occurred over two visits. Two physiotherapists and the child's parent rated distress using the GDRS. Heart rate (HR) was also measured. RESULTS: 24 children with CF, mean age of 3 years, participated. Both physiotherapist and parent rating showed significantly higher distress levels during suction than swab. Inter-rater reliability for the GDRS was very good between physiotherapists, and good between physiotherapist and parents. CONCLUSION: The study found that oropharyngeal swab is less distressing in obtaining samples than oropharyngeal suction and that the GDRS was reliable and valid.

Human cerebral arteriovenous vasoactive exchange during alterations in arterial blood gases.

Cerebral blood flow (CBF) is highly regulated by changes in arterial Pco(2) and arterial Po(2). Evidence from animal studies indicates that various vasoactive factors, including release of norepinephrine, endothelin, adrenomedullin, C-natriuretic peptide (CNP), and nitric oxide (NO), may play a role in arterial blood gas-induced alterations in CBF. For the first time, we directly quantified exchange of these vasoactive factors across the human brain. Using the Fick principle and transcranial Doppler ultrasonography, we measured CBF in 12 healthy humans at rest and during hypercapnia (4 and 8% CO(2)), hypocapnia (voluntary hyperventilation), and hypoxia (12 and 10% O(2)). At each level, blood was sampled simultaneously from the internal jugular vein and radial artery. With the exception of CNP and NO, the simultaneous quantification of norepinephrine, endothelin, or adrenomedullin showed no cerebral uptake or release during changes in arterial blood gases. Hypercapnia, but not hypocapnia, increased CBF and caused a net cerebral release of nitrite (a marker of NO), which was reflected by an increase in the venous-arterial difference for nitrite: 57 +/- 18 and 150 +/- 36 micromol/l at 4% and 8% CO(2), respectively (both P < 0.05). Release of cerebral CNP was also observed during changes in CO(2) (hypercapnia vs. hypocapnia, P < 0.05). During hypoxia, there was a net cerebral uptake of nitrite, which was reflected by a decreased venous-arterial difference for nitrite: -96 +/- 14 micromol/l at 10% O(2) (P < 0.05). These data indicate that there is a differential exchange of NO across the brain during hypercapnia and hypoxia and that CNP may play a complementary role in CO(2)-induced CBF changes.

Differential effects of acute hypoxia and high altitude on cerebral blood flow velocity and dynamic cerebral autoregulation: alterations with hyperoxia.

We hypothesized that 1) acute severe hypoxia, but not hyperoxia, at sea level would impair dynamic cerebral autoregulation (CA); 2) impairment in CA at high altitude (HA) would be partly restored with hyperoxia; and 3) hyperoxia at HA and would have more influence on blood pressure (BP) and less influence on middle cerebral artery blood flow velocity (MCAv). In healthy volunteers, BP and MCAv were measured continuously during normoxia and in acute hypoxia (inspired O2 fraction = 0.12 and 0.10, respectively; n = 10) or hyperoxia (inspired O2 fraction, 1.0; n = 12). Dynamic CA was assessed using transfer-function gain, phase, and coherence between mean BP and MCAv. Arterial blood gases were also obtained. In matched volunteers, the same variables were measured during air breathing and hyperoxia at low altitude (LA; 1,400 m) and after 1-2 days after arrival at HA ( approximately 5,400 m, n = 10). In acute hypoxia and hyperoxia, BP was unchanged whereas it was decreased during hyperoxia at HA (-11 +/- 4%; P < 0.05 vs. LA). MCAv was unchanged during acute hypoxia and at HA; however, acute hyperoxia caused MCAv to fall to a greater extent than at HA (-12 +/- 3 vs. -5 +/- 4%, respectively; P < 0.05). Whereas CA was unchanged in hyperoxia, gain in the low-frequency range was reduced during acute hypoxia, indicating improvement in CA. In contrast, HA was associated with elevations in transfer-function gain in the very low- and low-frequency range, indicating CA impairment; hyperoxia lowered these elevations by approximately 50% (P < 0.05). Findings indicate that hyperoxia at HA can partially improve CA and lower BP, with little effect on MCAv.

Dynamic cerebral autoregulation and baroreflex sensitivity during modest and severe step changes in arterial PCO2.

Changes in the partial pressure of arterial CO2 (PaCO2) regulates cerebrovascular tone and dynamic cerebral autoregulation (CA). Elevations in PaCO2 also increases autonomic neural activity and may alter the arterial baroreflex. We hypothesized that hypercapnia would impair, and hypocapnia would improve, dynamic CA and that these changes would occur independently of any change in baroreflex sensitivity (BRS). In 10 healthy male subjects, incremental hypercapnia was achieved through 4-min administrations of 4% and 8% CO2. Incremental hypocapnia involved two 4-min steps of hyperventilation to change end-tidal PCO2, in an equal and opposite direction, to that incurred during hypercapnia. End-tidal, arterial and internal jugular vein PCO2 were sampled simultaneously at baseline and during each CO2 step. Dynamic CA and BRS was assessed at baseline and during each step change in PaCO2 using spectral and transfer-function analysis of beat-by-beat changes in mean arterial blood pressure (MAP), heart rate and flow velocity in the middle cerebral arterial (MCAv). Critical closing pressure (CCP), an estimate of cerebrovascular tone, was estimated from extrapolation of the MAP-MCAv waveforms. Hypercapnia caused a progressive increase in PaCO2 and MCAv whereas hypocapnia caused the opposite effect. Despite marked changes in CPP, there were no evident change in transfer-function gain, coherence, MAP variability or BRS; however, both MCAv variability and phase in the very-low frequency range was reduced during the most severe level of hyper- and hypocapnia (P < 0.05), and were related to elevations in ventilation (R2 = 0.42-0.52, respectively; P < 0.001). It seems that hyperventilation, rather than PaCO2, has an important influence on dynamic CA.

Resting heart rate variability and exercise capacity in Type 1 diabetes.

People with type 1 diabetes (T1D) have lower exercise capacity (V̇O2max) than their age-matched nondiabetic counterparts (CON), which might be related to cardiac autonomic dysfunction. We examined whether Heart Rate Variability (HRV; indicator of cardiac autonomic modulation) was associated with exercise capacity in those with and without T1D. Twenty-three participants with uncomplicated T1D and 17 matched CON were recruited. Heart rate (HR; ECG), blood pressure (BP; finger photo-plethysmography), and respiratory rate (respiratory belt) were measured during baseline, paced-breathing and clinical autonomic reflex tests (CARTs); deep breathing, lying-to-stand, and Valsalva maneuver. Baseline and paced-breathing ECG were analyzed for HRV (frequency-domain). Exercise capacity was determined during an incremental cycle ergometer test while V̇O2, 12-lead ECG, and BP were measured. In uncomplicated T1D, resting HR was elevated and resting HRV metrics were reduced, indicative of altered cardiac parasympathetic modulation; this was generally undetected by the CARTs. However, BP and plasma catecholamines were not different between groups. In T1D, V̇O2max tended to be lower (P = 0.07) and HR reserve was lower (P < 0.01). Resting Total Power (TP) had stronger positive associations with V̇O2max (R2 ≥ 0.3) than all other traditional indicators such as age, resting HR, and self-reported exercise (R2 = 0.042-0.3) in both T1D and CON Alterations in cardiac autonomic modulation are an early manifestation of uncomplicated T1D. Total Power was associated with reduced exercise capacity regardless of group, and these associations were generally stronger than traditional indicators.

A simplified method for quantifying the subject-specific relationship between blood pressure and carotid-femoral pulse wave velocity.

Devices that estimate blood pressure from arterial pulse wave velocity (PWV) potentially provide continuous, ambulatory blood pressure monitoring. Accurate blood pressure estimation requires reliable quantification of the relationship between blood pressure and PWV. Regression to population normal values or, when using limb artery PWV, changing hydrostatic blood pressure within the limb provides a calibration index. Population lookup tables require accurate anthropometric correlates, assuming no individual variation. Only devices that measure PWV in the limb can use limb position changes. This study proposes a method for developing a calibration curve independent of lookup tables and useful for large artery PWV measurement, such as carotid-femoral PWV (PWVcf). PWVcf was measured in 27 normal subjects (15 female, 36±19 years) in both the supine and standing position. The change in systemic pressure was measured and hydrostatic pressure change calculated from estimated vessel path length height, measured using body surface distances. Brachial diastolic blood pressure increased for all subjects from supine to standing (supine 70±8 mmHg, standing 83±8 mmHg, p<;0.001) with an additional hydrostatic change across the carotid-femoral path length of 19±2 mmHg (p<;0.001). PWVcf also increased in all subjects (supine 5.2±1.3 m/s, standing 7.3±2.2 m/s, p<;0.001). The subject-specific calibration index (ΔDP/ΔPWVcf) varied amongst the cohort (20±8 mmHg/m/s), was correlated with age (-0.57, p=0.002) and seated aortic systolic pressure (-0.38, p=0.048) and was always greater than zero. Thus, this study describes a simple but novel method of measuring an individualized calibration index using blood pressure and PWV measurements in the supine and standing position.

Influence of cerebral blood flow on central sleep apnea at high altitude.

STUDY OBJECTIVES: To further our understanding of central sleep apnea (CSA) at high altitude during acclimatization, we tested the hypothesis that pharmacologically altering cerebral blood flow (CBF) would alter the severity of CSA at high altitude. DESIGN: The study was a randomized, placebo-controlled single-blind study. SETTING: A field study at 5,050 m in Nepal. PATIENTS OR PARTICIPANTS: We studied 12 normal volunteers. INTERVENTIONS: Between days 5 to 10 at high altitude, CBF velocity (CBFv) was increased by intravenous (IV) acetazolamide (10 mg/kg) and reduced by oral indomethacin (100 mg). MEASUREMENTS AND RESULTS: Arterial blood gases, hypoxic and hypercapnic ventilatory responses, and CBFv and its reactivity to carbon dioxide were measured awake. Overnight polysomnography was performed. The central apnea-hypopnea index was elevated following administration of indomethacin (89.2 ± 43.7 to 112.5 ± 32.9 events/h; mean ± standard deviation; P < 0.05) and was reduced following IV acetazolamide (89.2 ± 43.7 to 47.1 ± 48.1 events/h; P < 0.001). Intravenous acetazolamide elevated CBFv at high altitude by 28% (95% confidence interval [CI]: 22-34%) but did not affect ventilatory responses. The elevation in CBFv was partly mediated via a selective rise in partial pressure of arterial carbon dioxide (PaCO2) (28 ± 4 to 31 ± 3 mm Hg) and an associated fall in pH (P < 0.01). Oral indomethacin reduced CBFv by 23% (95% CI: 16-30%), blunted CBFv reactivity, and increased the hypercapnic ventilatory response by 66% (95% CI: 30-102%) but had no effect on PaCO2 or pH. CONCLUSION: Our findings indicate an important role for cerebral blood flow regulation in the pathophysiology of central sleep apnea at high altitude.

The influence of tobacco smoking on the relationship between pressure and flow in the middle cerebral artery in humans.

BACKGROUND: Cigarette smoking is associated with an increased risk of stroke but the mechanism is unclear. The study examined whether acute and chronic cigarette smoking alters the dynamic relationship between blood pressure and cerebral blood flow. We hypothesised that acute and chronic smoking would result in a cerebral circulation that was less capable of buffering against dynamic fluctuations in blood pressure. Further, these changes would be accompanied by a reduction in baroreflex sensitivity, which is reduced after smoking (acute smoking). METHODS: We recruited 17 non-smokers and 15 habitual smokers (13 ± 5 pack years). Continuous measurements of mean cerebral blood flow velocity (transcranial Doppler ultrasound), blood pressure (finger photoplethysmography) and heart rate enabled transfer function analysis of the dynamic relationship between pressure and flow (gain, normalised gain, phase and coherence) and baroreflex sensitivity during supine rest before and after smoking a single cigarette (acute smoking). RESULTS: There were no between-group differences in gain, phase or coherence before acute smoking. However, both groups showed a reduction in gain and coherence, associated with a reduction in baroreflex sensitivity, and increase in phase after acute smoking. CONCLUSIONS: Contrary to our hypothesis, these findings suggest that in the face of a reduction in baroreflex sensitivity acute smoking may potentially improve the ability of the cerebral circulation to buffer against changes in blood pressure. However, chronic smoking did not alter the dynamic relationship between blood pressure and cerebral blood flow velocity. These results have implications on understanding mechanisms for attenuating stroke risk.

Cardiac baroreflex gain is frequency dependent: insights from repeated sit-to-stand maneuvers and the modified Oxford method.

Cardiac baroreflex gain is usually quantified as the reflex alteration in heart rate during changes in blood pressure without considering the effect of the rate of change in blood pressure on the estimated gain. This study sought to (i) characterize baroreflex gain as a function of blood pressure oscillation frequencies using a repeat sit-to-stand method and (ii) compare baroreflex gain values obtained using the sit-to-stand method against the modified Oxford method. Fifteen healthy individuals underwent the repeated sit-to-stand method in which blood pressure oscillations were driven at 0.03, 0.05, 0.07, and 0.1 Hz. Sixteen healthy participants underwent the sit-to-stand and modified Oxford methods to examine their agreement. Sit-to-stand baroreflex gain was highest at 0.05 Hz (8.8 ± 3.2 ms·mm Hg(-1)) and lowest at 0.1 Hz (5.8 ± 3.0 ms·mm Hg(-1)). Baroreflex gains at 0.03 Hz (7.7 ± 3.0 ms·mm Hg(-1)) and 0.07 Hz (7.5 ± 3.3 ms·mm Hg(-1)) were not different from the baroreflex gain at 0.05 Hz. There was moderate correlation between phenylephrine gain and sit-to-stand gain (r values ranged from 0.52 to 0.75; all frequencies, p < 0.05), but no correlation between sodium nitroprusside gain and sit-to-stand gain (r values ranged from -0.07 to 0.22; all p < 0.05). Bland-Altman analysis of phenylephrine gain and sit-to-stand gain showed poor agreement and a positive proportional bias. These results show that baroreflex gains derived from these 2 methods cannot be used interchangeably. Furthermore, cardiac baroreflex gain is frequency dependent between 0.03 Hz and 0.1 Hz, which challenges the conventional practice of summarizing baroreflex gain as a single number.