Cerebral blood velocity during concurrent supine cycling, lower body negative pressure, and head-up tilt challenges: implications for concussion rehabilitation

Introduction. The effect of concurrent head-up tilt and lower body negative pressure (LBNP) have been examined on middle cerebral artery velocity (MCAv) at rest; however, it is unknown the superimposed effect these factors have on blunting the elevation in cerebral blood velocity associated with moderate-intensity exercise. Methods. 23 healthy adults (11 females / 12 males, 20–33 years) completed three visits. The first consisted of a maximal ramp supine cycling test to identify the wattage associated with individualized maximal MCAv. Subsequent visits included randomized no LBNP (control) or LBNP at −40 Torr (experimental) with successively increasing head-up tilt stages of 0, 15, 30, and 45 degrees during the pre-described individualized wattage. Transcranial Doppler ultrasound was utilized to quantify MCAv. Two-factorial repeated measures analysis of variance with effect sizes were used to determine differences between days and tilt stages. Results. Between-day baseline values for MCAv, heart rate, and blood pressure displayed low variability with <5% variation. With no LBNP, MCAv was above baseline on average for all participants; however, 15 degrees and 30 degrees tilt with concurrent −40 Torr LBNP was sufficient to return MCAv to 100% of baseline values in females and males, respectively. Body-weight did not impact the association between tilt and pressure (R 2 range: 0.01–0.12). Conclusion. Combined LBNP and tilt were sufficient to reduce the increase in MCAv associated with moderate-intensity exercise. This exercise modality shows utility to enable individuals with a concussion to obtain the positive physiological adaptions associated with exercise while minimizing symptom exacerbation due to the notion of the Monro-Kellie doctrine.

[1]  C. Emery,et al.  The Effect of Supine Cycling and Progressive Lower Body Negative Pressure on Cerebral Blood Velocity Responses. , 2023, Journal of applied physiology.

[2]  L. Langevin,et al.  Partnering With Patients, Caregivers, and Clinicians to Determine Research Priorities for Concussion , 2023, JAMA network open.

[3]  D. Thijssen,et al.  The impact of age, sex, cardio-respiratory fitness, and cardiovascular disease risk on dynamic cerebral autoregulation and baroreflex sensitivity , 2022, European Journal of Applied Physiology.

[4]  Ibukunoluwa K. Oni,et al.  Neurovascular coupling on trial: How the number of trials completed impacts the accuracy and precision of temporally derived neurovascular coupling estimates , 2022, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[5]  C. Rickards,et al.  The Impact of Acute Central Hypovolemia on Cerebral Hemodynamics: Does Sex Matter? , 2021, Journal of applied physiology.

[6]  K. Schneider,et al.  Concurrent Validity of a Stationary Cycling Test and Buffalo Concussion Treadmill Test in Adults with Concussion. , 2021, Journal of athletic training.

[7]  Blair D. Johnson,et al.  Preliminary Evidence of Orthostatic Intolerance and Altered Cerebral Vascular Control Following Sport-Related Concussion , 2021, Frontiers in Neurology.

[8]  S. Billinger,et al.  Effects of Age and Sex on Middle Cerebral Artery Blood Velocity and Flow Pulsatility Index Across the Adult Lifespan. , 2021, Journal of applied physiology.

[9]  J. Smirl,et al.  Temporal evolution of neurovascular coupling recovery following moderate‐ and high‐intensity exercise , 2021, Physiological reports.

[10]  L. Lipsitz,et al.  Systemic and cerebral circulatory adjustment within the first 60 s after active standing: An integrative physiological view , 2020, Autonomic Neuroscience.

[11]  P. Howe,et al.  Benefits of exercise training on cerebrovascular and cognitive function in ageing , 2020, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[12]  C. Cullum,et al.  Impaired cerebral blood flow regulation in chronic traumatic brain injury , 2020, Brain Research.

[13]  J. Smirl,et al.  Comparison of cerebrovascular reactivity recovery following high‐intensity interval training and moderate‐intensity continuous training , 2020, Physiological reports.

[14]  J. Smirl,et al.  Comparison of diurnal variation, anatomical location, and biological sex within spontaneous and driven dynamic cerebral autoregulation measures , 2020, Physiological reports.

[15]  Christopher J. Marley,et al.  HIITing the brain with exercise: mechanisms, consequences and practical recommendations , 2020, The Journal of physiology.

[16]  J. Smirl,et al.  Dynamic cerebral autoregulation across the cardiac cycle during 8 hr of recovery from acute exercise , 2020, Physiological reports.

[17]  F. Verheugt,et al.  Cerebral blood flow is reduced in ME/CFS during head-up tilt testing even in the absence of hypotension or tachycardia: A quantitative, controlled study using Doppler echography , 2020, Clinical neurophysiology practice.

[18]  R. Shephard,et al.  The 2020 Physical Activity Readiness Questionnaire for Everyone (PAR-Q+) and electronic Physical Activity Readiness Medical Examination (ePARmed-X+): , 2019 .

[19]  N. Müller,et al.  Dose–Response Matters! – A Perspective on the Exercise Prescription in Exercise–Cognition Research , 2019, Front. Psychol..

[20]  P. Brassard,et al.  Six weeks of high‐intensity interval training to exhaustion attenuates dynamic cerebral autoregulation without influencing resting cerebral blood velocity in young fit men , 2019, Physiological reports.

[21]  L. Halsey The reign of the p-value is over: what alternative analyses could we employ to fill the power vacuum? , 2019, Biology Letters.

[22]  K. De Bock,et al.  Metabolic regulation of exercise-induced angiogenesis , 2019, Vascular biology.

[23]  S. Greenland,et al.  Scientists rise up against statistical significance , 2019, Nature.

[24]  V. Convertino,et al.  Lower Body Negative Pressure: Physiological Effects, Applications, and Implementation. , 2019, Physiological reviews.

[25]  J. Smirl,et al.  Dynamic cerebral autoregulation is attenuated in young fit women , 2019, Physiological reports.

[26]  D. Poulsen,et al.  Intracranial pressure changes after mild traumatic brain injury: a systematic review , 2018, Brain injury.

[27]  F. Verheugt,et al.  Cerebral blood flow changes during tilt table testing in healthy volunteers, as assessed by Doppler imaging of the carotid and vertebral arteries , 2018, Clinical neurophysiology practice.

[28]  R. Nusslock,et al.  Exercise-Mediated Neurogenesis in the Hippocampus via BDNF , 2018, Front. Neurosci..

[29]  R. Alarcón,et al.  Non‐normal data: Is ANOVA still a valid option? , 2017, Psicothema.

[30]  S. Lucas,et al.  Diminished dynamic cerebral autoregulatory capacity with forced oscillations in mean arterial pressure with elevated cardiorespiratory fitness , 2017, bioRxiv.

[31]  W. Meehan,et al.  Exercise induced recurrence of concussion symptoms after symptom free status , 2017, British Journal of Sports Medicine.

[32]  Michael M. Tymko,et al.  How to build a lower-body differential pressure chamber integrated on a tilt-table: A pedagogy tool to demonstrate the cardiovagal baroreflex , 2017 .

[33]  C. Rickards,et al.  The effects of superimposed tilt and lower body negative pressure on anterior and posterior cerebral circulations , 2016, Physiological reports.

[34]  Mark H. Wilson,et al.  Monro-Kellie 2.0: The dynamic vascular and venous pathophysiological components of intracranial pressure , 2016, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[35]  Y. Tzeng,et al.  Methodological comparison of active- and passive-driven oscillations in blood pressure; implications for the assessment of cerebral pressure-flow relationships. , 2015, Journal of applied physiology.

[36]  G. J. Crystal,et al.  Lower Body Negative Pressure: Historical Perspective, Research Findings, and Clinical Applications. , 2015, Journal of anesthesia history.

[37]  S. Lucas,et al.  High-Intensity Interval Exercise and Cerebrovascular Health: Curiosity, Cause, and Consequence , 2015, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[38]  J. Taylor,et al.  Cerebrovascular regulation, exercise, and mild traumatic brain injury , 2014, Neurology.

[39]  Joseph A Fisher,et al.  Integrative regulation of human brain blood flow , 2014, The Journal of physiology.

[40]  Daniël Lakens,et al.  Calculating and reporting effect sizes to facilitate cumulative science: a practical primer for t-tests and ANOVAs , 2013, Front. Psychol..

[41]  Diane Ebert-May,et al.  The Other Half of the Story: Effect Size Analysis in Quantitative Research , 2013, CBE life sciences education.

[42]  V. Claydon,et al.  Tilt testing with combined lower body negative pressure: a "gold standard" for measuring orthostatic tolerance. , 2013, Journal of visualized experiments : JoVE.

[43]  Aditi Vyas,et al.  Gender Differences in Orthostatic Hypotension , 2011, The American journal of the medical sciences.

[44]  J. Serrador,et al.  Cerebral autoregulation in the vertebral and middle cerebral arteries during combine head upright tilt and lower body negative pressure in healthy humans , 2010, 2010 Annual International Conference of the IEEE Engineering in Medicine and Biology.

[45]  Shigehiko Ogoh,et al.  Cerebral blood flow during exercise: mechanisms of regulation. , 2009, Journal of applied physiology.

[46]  Gordon H Guyatt,et al.  Design, analysis, and presentation of crossover trials , 2009, Trials.

[47]  C. Husten How should we define light or intermittent smoking? Does it matter? , 2009, Nicotine & tobacco research : official journal of the Society for Research on Nicotine and Tobacco.

[48]  Demosthenes B Panagiotakos,et al.  The Value of p-Value in Biomedical Research , 2008, The open cardiovascular medicine journal.

[49]  Stuart M. C. Lee,et al.  Lower body negative pressure exercise plus brief postexercise lower body negative pressure improve post-bed rest orthostatic tolerance. , 2007, Journal of applied physiology.

[50]  N. Samani,et al.  Influence of noninvasive peripheral arterial blood pressure measurements on assessment of dynamic cerebral autoregulation. , 2007, Journal of applied physiology.

[51]  Anusha Sivaramakrishnan,et al.  Quantifying the effect of posture on intracranial physiology in humans by MRI flow studies , 2005, Journal of magnetic resonance imaging : JMRI.

[52]  R. Bakeman Recommended effect size statistics for repeated measures designs , 2005, Behavior research methods.

[53]  Donald E. Watenpaugh,et al.  Lower-body negative-pressure exercise and bed-rest-mediated orthostatic intolerance. , 2002, Medicine and science in sports and exercise.

[54]  D. Hovda,et al.  The Neurometabolic Cascade of Concussion. , 2001, Journal of athletic training.

[55]  W G Hopkins,et al.  Measures of Reliability in Sports Medicine and Science , 2000, Sports medicine.

[56]  N. Wahlgren,et al.  Carotid artery blood flow and middle cerebral artery blood flow velocity during physical exercise. , 1996, Journal of applied physiology.

[57]  Y. Mayanagi,et al.  Effect of head up tilt on cerebral circulation. , 1994, Acta astronautica.

[58]  G Parati,et al.  Spectral and sequence analysis of finger blood pressure variability. Comparison with analysis of intra-arterial recordings. , 1993, Hypertension.

[59]  D. Bild,et al.  Orthostatic hypotension in older adults. The Cardiovascular Health Study. CHS Collaborative Research Group. , 1992, Hypertension.

[60]  B. Whipp,et al.  Bicarbonate buffering of lactic acid generated during exercise. , 1986, Journal of applied physiology.

[61]  D. Pendergast,et al.  Regulatory and autoregulatory physiological dysfunction as a primary characteristic of post concussion syndrome: implications for treatment. , 2007, NeuroRehabilitation.

[62]  Transcranial Doppler Ultrasound: Technique and Application , 2022 .