Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT03342833 |
| Other study ID # |
17.YH.0348 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
Phase 2
|
| First received |
|
| Last updated |
|
| Start date |
March 10, 2018 |
| Est. completion date |
April 1, 2021 |
Study information
| Verified date |
April 2021 |
| Source |
University of Leeds |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
The purpose of this current study proposal is to identify the potential physiological
adaptations arising from a combined BFR+HIIT training intervention in CHF patients. We
hypothesise that the addition of BFR to HIIT will increase whole-body V̇O2peak by promoting
vascular and skeletal muscle adaptations above that seen with HIIT alone. The secondary
outcomes of this study are to determine if such a training intervention leads to clinical
improvements in exercise intolerance symptoms and quality of life indices. Given that the
majority of previous research in to both BFR and HIIT has largely involved young, healthy and
relatively active participants, the final objective of this current proposal is to determine
the viability, tolerability and efficacy of these training modalities in an elderly cohort of
predominantly sedentary CHF patients.
Description:
Exercise training in CHF is a potentially effective intervention for improving symptomatic
and prognostic outcomes, but remains underutilised in contemporary CHF management in the
United Kingdom. This underutilisation may be partly the result of multiple approaches to
training but also due to inconsistent and overall modest results of any of the interventions
on important patient-orientated outcomes. A key consideration in this latter regard is
whether disease related symptoms (e.g. dyspnoea) during exercise training limit the
physiological work achievable during training, limiting the degree of the training stimulus
to below the level at which physiological adaptation can be achieved. For example, in COPD
participants only those in whom skeletal muscle fatigue was present after a training session
evidenced any improvement in functional exercise capacity and health-related quality of life
following a 3-month rehabilitation programme. Investigating novel approaches to training that
promote greater gains in training effect may therefore lead to greater changes in
patient-centred outcomes which will eventually stimulate greater uptake and alleviate the
clinical burden chronic heart failure.
Blood Flow Restriction (BFR) training is a novel strategy in which a pressure cuff is
inflated around the proximal portion of the exercising limbs (e.g. at the top of the arms or
legs) during exercise or in recovery periods between exercise bouts. The pressure of the cuff
is set to allow arterial blood flow but occlude venous return, subsequently altering (or
maintaining) the local metabolic milieu, resulting in upregulation of several downstream
pathways that augment the adaptive response to exercise. BFR has been successfully employed
previously in combination with resistance exercise (RE) training to augment skeletal muscle
hypertrophy in isolated peripheral muscles. Importantly, this training has been shown to
promote muscle hypertrophy with concomitant increases in isokinetic strength in elderly
individuals performing at low exercise work rates. This therefore demonstrates that BFR can
induce comparatively similar adaptations at a lower power in elderly populations, suggesting
this training strategy may have applications in other groups, such as CHF patients.
Additional studies have also demonstrated improvements in V̇O2peak by combining BFR with
traditional low-intensity endurance training or high-intensity interval training (HIIT).
Using a within-measures design, the first of these studies demonstrated that a 4-week
training intervention (4 sessions per week) of 45-mins single-leg cycling under ischaemic
conditions (induced by an external pressure of 50 mmHg in a pressure chamber) improved
time-to-fatigue and V̇O2peak significantly more than an identical training intervention on
the contralateral leg under normoxic (non-ischaemic) conditions. Further research with a
between-measures design showed that 8-weeks of low-intensity cycling (40% V̇O2peak) with
continuous BFR (160-210 mmHg) can increase both muscle strength and cross-sectional area as
well as V̇O2peak significantly more than a control intervention using the same protocol
without BFR. Interestingly, the control group exercised for longer during their training
sessions (45-mins vs 15-mins for BFR) demonstrating that BFR not only has the potential to
augment adaptations but is also a time-efficient modality of exercise. Given that lack of
time is frequently cited as a barrier to regular exercise training, novel training
interventions, such as BFR, that aren't time-consuming may be considered an attractive
alternative form of exercise.
HIIT is also promoted as a time-efficient training modality that is known to promote
comparable physiological adaptations to traditional high-volume low-intensity endurance
exercise training. HIIT typically involves repeated bouts of intense ('near-maximal')
exercise separated by brief periods of recovery. Some training studies have now combined BFR
with HIIT (BFR+HIIT), applying the pressure cuff during recovery periods rather than during
exercise. This combination of BFR+HIIT allows the working muscle to perform as normal during
the short bouts of exercise; however, application of the cuff during recovery was shown to
promote superior physiological adaptations above HIIT alone. Specifically, this study
demonstrated that 4-weeks (2 sessions per week) of sprint interval training (4-7 bouts of
maximal 30s cycling sprints with 4.5-mins recovery) combined with BFR (2-mins at 130 mmHg
during the recovery period) significantly increased V̇O2peak compared to a control group
performing the same training protocol without BFR.
Although the exact mechanisms responsible for this superior physiological response have yet
to be fully elucidated, it is likely that the combination of BFR and HIIT promotes localized
adaptations within the peripheral muscle tissues performing the exercise and then being
subjected to BFR i.e. in the case of cycling, the quadriceps muscle group. Such adaptations
are coordinated by the metabolic changes known to occur with both exercise and localized
ischaemia. These result in an increased expression of several intracellular transcription
factors, which subsequently orchestrate a cascade of downstream signalling pathways that
promote physiological adaptations within skeletal muscle. These adaptations include increased
capillarisation (angiogenesis), mitochondrial biogenesis, and a phenotypic switch towards
predominantly slow-oxidative non-fatiguing type 1 muscle fibres. There has also been the
suggestion that BFR can upregulate peripheral vascular adaptations. Collectively, these
increase muscle oxygen delivery (̇Q̇mO2) and uptake (V̇mO2), both of which are now considered
as crucial training-induced adaptive responses for increasing whole-body V̇O2peak and
ameliorating exercise intolerance symptoms in CHF patients.
Indeed, several exercise training interventions in CHF patients have previously focused on
promoting adaptive responses within the vasculature and peripheral skeletal muscles as a
means of increasing V̇O2peak. The rationale for these studies is based on the poor
correlation between LV ejection fraction and exercise intolerance symptoms in CHF.
Furthermore, it is now well recognised that several peripheral impairments within the
skeletal muscle system contribute to the symptoms of exercise intolerance in CHF. These
include vascular dysfunction, muscle fibre atrophy, reduced capillarisation, mitochondrial
dysfunction, and a shift towards predominantly fast-twitch glycolytic type IIx fibres.
Collectively, these contribute to poor symptoms and therefore previous exercise training
interventions in CHF patients have focused on promoting adaptations within the periphery as a
means of increasing V̇O2peak and ameliorating exercise intolerance. Many of these studies
have successfully demonstrated an increase in V̇O2peak primarily by promoting adaptations
within the periphery. As such, we believe that BFR+HIIT represents a novel training stimulus
that may promote adaptive responses within the vascular and skeletal muscle systems that are
likely to have significant effects in terms of increasing V̇O2peak, ameliorating exercise
intolerance and improving quality of life in CHF patients.
