Chronic Passive Heating in Individuals With T2DM
Study Details
Study Description
Brief Summary
Type 2 diabetes mellitus (T2DM) is a metabolic condition characterized by chronic hyperglycemia and progressive insulin resistance, which progressively lead to macro- and microvascular damage and subsequent impairments in blood pressure (BP) control. Therapeutic approaches to manage T2DM focus on improving glycaemic control and BP and include pharmaceutical treatments (e.g. Metformin and insulin), physical activity and exercise, and calorie restriction. However, pharmaceutical interventions can be expensive and are associated with low adherence. Although exercise and diet programs have been shown to be effective, like pharmaceutical interventions, they often have poor adherence in people with T2DM. With the number of people with T2DM (464 million) continuing to rise and expected to reach 700 million by 2045, the costs associated with the clinical management of this condition are likely to become unsustainable. There is, therefore, a need to explore the potential of alternative interventions. In particular, interventions which may be cheaper than clinical management and have better adherence than exercise, and hypoglycemic agents, to improve glycemic control and deleterious cardiovascular manifestations of this condition.
Passive heating may be one such intervention with therapeutic potential.
Condition or Disease | Intervention/Treatment | Phase |
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N/A |
Detailed Description
Current estimates suggest 422 million people worldwide live with a form of diabetes, of which ~ 90% have type 2 diabetes mellitus (T2DM). The total direct and indirect cost of care for individuals with diabetes in the UK is £23.7 billion, equating to ~ 20% of the annual NHS budget, this figure is expected to rise to ~£39.8 billion by the year 2035. Approximately 85-90% of cases of T2DM arise from a poor lifestyle and obesity, with the remaining 10-15% resulting from genetic predispositions. Current interventions include pharmaceutical treatments, exercise and calorie restrictive diets, which aim to improve glycaemic control. However, pharmaceutical interventions carry a high financial cost, while exercise and diet programmes have a low adherence rate in individuals with T2DM. With the prevalence of T2DM continuing to increase, the costs associated with the clinical care of these individuals are likely to become unsustainable. Simple, inexpensive interventions to improve the clinical profile of this group are therefore needed.
One emerging potential therapy to improve glucose homoeostasis is passive heating. Preliminary evidence suggests passive heating may have beneficial effects for metabolic health in animal models and in humans. In 1999, the use of hot tubs (38-41°C , 30 mins / day for 3 weeks) was shown to reduce fasting plasma glucose concentrations by ~14% (1.3 mmol.L-1) and decrease HbA1c by ~10-11 mmol/mol in 8 individuals with T2DM. Given the rate of turnover in haemoglobin this reduction is surprising as the treatment period was run over 3 weeks and the total haemoglobin turnover takes ~115 days. While more recent work has been conducted into the effects of a single bout of passive heating in healthy adults and individuals with T2DM (including ourselves, under review), none have been done on chronic heating since Hooper. Hooper postulated that an increase in skeletal muscle blood flow may be responsible for this increased glucose clearance, citing evidence that this can modulate insulin mediated glucose uptake. Other mechanisms have also been purported, but have yet to be elucidated, including; increased insulin sensitivity, altered inflammatory response, activation of heat shock proteins (HSP), altered gut microbiome and butyrate. Repeated passive heating results in transient increases in deep body temperature and may improve glucose homeostasis via similar mechanisms to exercise.
Regular aerobic exercise also improves macro- and microvascular function, muscle oxygenation, autonomic function, cardiorespiratory fitness, lung function and delays age related muscle loss. Acute exercise studies show that insulin sensitivity after 1h of moderate exercise does not change, however, insulin sensitivity appears to be improved following bouts longer than an hour or performed at greater intensity. Increases in insulin sensitivity have a curvilinear relationship with energy expenditure and could also be due to greater HSP expression. However, it is unrealistic for people with T2DM to perform this level of activity. Passive heating may be one supplemental exercise mimetic to augment improvements in insulin sensitivity, cardiorespiratory fitness and muscle strength, and function.
The investigators recently provided evidence that acute passive heating in poeple with T2DM (currently under review for publication) is well tolerated and increases extracellualr [HSP70], and energy expenditure, and reduce diabstolic blood pressure. There is a growing body of evdience that suggests passive heating may improve many facets of human physiology, however, the mechanisms that underpin these benefits have yet to be established and future research needs to explore these further.
Study Design
Arms and Interventions
Arm | Intervention/Treatment |
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Experimental: Passive heating 8-12 x1 h water immersion (to the clavicle, @40 °C, rectal temperature ~38.5 °C and <39 °C) sessions over a period of 14 days. |
Procedure: Passive heating
8-12 x1 h water immersion (to the clavicle, @40 °C, rectal temperature ~38.5 °C and <39 °C) sessions over a period of 14 days.
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Outcome Measures
Primary Outcome Measures
- Insulin sensitivity [Change from pre (day 1) - post 8-12 days of 1 hour of passive heating]
Does chronic passive heating improve insulin sensitivity? Calculated using the Stumvoll equation with glucose and insulin concentrations.
Secondary Outcome Measures
- Plasma glucose concentration [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating reduce plasma [glucose]?
- Glycated hemoglobin (HbA1c) [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating reduce HbA1c?
- Plasma eHSP70 concentration [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating increase plasma [eHSP70]?
- Plasma IL-6 concentration [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating reduce plasma [IL-6]?
- Plasma IL-10 concentration [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating increase plasma [IL-10]?
- Resting metabolic rate [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating reduce plasma resting metabolic rate?
- Flow mediated dilation [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating improve macrovascular function? Measured via ultrasound
- Iontophoresis [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating improve microvascular function? Assessed via iontophoresis or the forearm with ACh and Insulin, Area under the curve is the unit.
- Resting heart rate [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating reduce resting heart rate?
- Stroke volume [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating increase stroke volume? Measured noninvasively via thoracic impedance
- Total peripheral resistance [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating reduce total peripheral resistance? Measured noninvasively via thoracic impedance
- Cardiac output [pre - post following 8-12 days of 1 hour of passive heating]
Does chronic passive heating increase cardiac output? Measured noninvasively via thoracic impedance. L/min is the unit.
Eligibility Criteria
Criteria
Inclusion Criteria:
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Male or female (post-menopausal) aged 35 years or above.
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Diagnosed with T2DM as defined by the WHO (≥48 mmol/mol).
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Participant is willing and able to give informed consent for participation in the study.
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Participant is able to understand and fully cooperate with the study protocol.
Exclusion Criteria:
Severe peripheral neuropathy (to the point to which they cannot sense temperature)
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Uncontrolled hypertension (≥180 systolic / 100 diastolic mmHg)
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Taking any medication which may interfere with data interpretation or safety
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Who have had a myocardial infarction or cerebro-vascular event
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Any cardiac abnormalities which restrict hard exercise
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Current smokers or who have stopped within 3 months
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Participant is unable to understand and/or fully cooperate with the study protocol
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Any other serious medical condition which would interfere with data interpretation or safety will be excluded from participation.
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Skin ulcerations
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Eczema
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Pre-existing postural hypertension
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Existing cardiac diseases (identified during screening)
Contacts and Locations
Locations
Site | City | State | Country | Postal Code | |
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1 | Department of Sport and Exercise Science | Portsmouth | Hampshire | United Kingdom | PO1 2ER |
Sponsors and Collaborators
- University of Portsmouth
- Portsmouth Hospitals NHS Trust
Investigators
None specified.Study Documents (Full-Text)
None provided.More Information
Publications
None provided.- 006