Inflammation Clinical Trial
Official title:
The Influence of Breathing Techniques and Exposure to Cold on Inflammation During Human Endotoxemia, an Explorative Study'
Inflammatory cytokines play a pivotal role in rheumatoid arthritis (RA) and innovative
non-pharmacological therapies aimed at limiting cytokine production are highly warranted.
Recently, our group showed that healthy volunteers trained in an intervention developed by
'Iceman' Wim Hof were able to voluntarily attenuate the pro-inflammatory response during
experimental human endotoxemia (a model of systemic inflammation elicited by administration
of lipopolysaccharide [LPS] in healthy volunteers). Subjects trained in the intervention
exhibited profound increases in plasma adrenaline levels, a rapid increase of an
anti-inflammatory cytokine and subsequent attenuation of the pro-inflammatory response.
The intervention consists of three elements, namely meditation, exposure to cold and
breathing techniques. The meditation element is not likely to be involved. It was a very
minor part of the training program and was not practiced during the endotoxemia experiments.
Exposure to cold and the subsequent rewarming to normal body temperature may influence the
inflammatory response through the release of immunomodulatory molecules like HSP-70. Also,
exposure to cold can induce an ischemia-reperfusion-like state in the skin and peripheral
tissue that is known to be involved in the downregulation of pro-inflammatory cytokines and
upregulation of anti-inflammatory cytokines. The investigators anticipate that the third
element, breathing techniques, is the major contributor to the anti-inflammatory effects of
the intervention previously observed. The present study aims to explore the effects of the
breathing technique ('strength ventilation'), the exposure to cold, and these two elements
combined on the immune response during human endotoxemia. Elucidation of the relative
contribution of the elements is of importance to establish a feasible, safe, and effective
intervention for future use in patients.
Objective: The primary objective of the present study is to determine the effects of the
`strength ventilation` breathing technique and exposure to cold, both separately and in
combination, on the inflammatory response during human endotoxemia. To this end, a 2 by 2
design will be employed. Additionally, an evaluation of the influence of the cold exposure
and breathing technique on pain thresholds and oxygen tension in the mitochondria will take
place.
Auto-immune diseases are characterized by an inappropriate inflammatory response against
tissues in the body. These diseases, of which rheumatoid arthritis (RA) is the most
well-known, represent a major health care burden. Pro-inflammatory cytokines such as TNF-α,
IL-6 and IL-1β are central in the pathogenesis of RA and many other auto-immune diseases.
Biologics that antagonize inflammatory cytokines or their receptors, e.g. anti-TNF-α, soluble
TNF-α-receptor, anti-IL-6 receptor, and IL-1 receptor antagonist, are very effective
treatments. However, they are very expensive and can have serious side effects. Furthermore,
the consequences of RA are currently completely beyond the patients' sphere of influence.
Therefore, innovative therapies aimed at limiting inflammation in RA patients are warranted.
Recently, a study into the effects of an intervention developed by 'The Iceman' Wim Hof
revealed that it is possible to voluntarily attenuate the pro-inflammatory response during
experimental human endotoxemia (a standardized, controlled, and reproducible model of
systemic inflammation elicited by administration of lipopolysaccharide (LPS) in healthy
volunteers). The intervention developed by Hof consists of several elements, namely
meditation, exposure to cold and breathing techniques. Subjects trained in this intervention
exhibited profound increases in plasma adrenaline levels, a rapid increase of the
anti-inflammatory cytokine IL-10, and subsequent attenuation of the pro-inflammatory response
(e.g. plasma levels of TNF-α, IL-6, and IL-8) during experimental human endotoxemia. This
intervention could therefore represent a treatment modality that would empower RA patients to
exert self-control over their disease.
Based on these data, investigating the effectiveness of the intervention in RA patients is
highly warranted. The study described in this protocol is part of a larger project in which
the investigators ultimately strive to translate the intervention to clinical practice for RA
patients. However, there are important issues that need to be addressed first. For example,
feasibility and safety would be substantially improved if patients would only have to learn
or practice one of the three elements of the intervention. The meditation element is not
likely to be involved. It was a very minor part of the training program and was not practiced
during the endotoxemia experiments. Also, there is no objective manner to measure this
element and there is no hypothesis for a possible mechanism. Concerning the second element,
exposure to cold, it would especially be of value to determine whether this element has
additional value, because it is very demanding and might not be suitable for RA patients at
all. The investigators anticipate that the third element, breathing techniques, is the major
contributor to the anti-inflammatory effects of the intervention previously observed for
reasons outlined below.
Breathing techniques First, although the healthy volunteers were trained in all three
elements, subjects only practiced breathing techniques during the endotoxemia experiment.
Second, the breathing techniques were characterized by cyclic hyperventilation, which has
been shown before to result in increased adrenaline levels. Subjects practiced two types of
breathing techniques during the endotoxemia experiment in our previous endotoxemia study.
Both of these breathing techniques were characterized by cycles of hyperventilation. In one
of the techniques (hyper/hypoventilation), subjects held their breath for up to several
minutes after each hyperventilation period, while in the other technique (strength
ventilation), subjects held their breath for only 10 seconds during which all muscles were
tightened after each hyperventilation period.
Yet unpublished data (CMO 2014-1374) showed the effects of these two breathing techniques in
the absence of cold exposure (or meditation) on plasma adrenaline levels. The investigators
found these to be strongly correlated with the anti-inflammatory effects previously found.
Both breathing techniques resulted in comparable increases in plasma adrenaline levels.
Furthermore, adrenaline levels in subjects trained by Hof were comparable to those that were
trained by an independent trainer previously not familiar with the intervention developed by
Hof. Finally, adrenaline levels in subjects trained for 4 days were similar to those who were
trained for only 2 hours.
Based on these results, it is hypothesized that the strength ventilation technique is the
major contributor to the anti-inflammatory effects of the intervention previously observed.
However, the effects of solely this breathing technique on the inflammatory response is not
investigated yet. Furthermore, it cannot be ruled out that the exposure to cold has
additional effects, since there are several ways in which exposure to cold could contribute
to anti-inflammatory effects, as described below.
Exposure to cold First, exposure to cold and the subsequent rewarming to normal body
temperature may influence the inflammatory response through the release of immunomodulatory
danger associated molecular patterns (DAMP`s), more specifically TLR-4 ligands such as heat
shock protein 70 (HSP-70). It was shown that HSP-70 mRNA levels in isolated cardiac myocytes
increased during rewarming after 2.5 hours of hypothermia. Furthermore, pre-incubation of
human cells exposed to 4 °C for 1, 2, 3 and 4 hours induced synthesis and accumulation of
HSP-70 upon recovery to 37 °C. The relevance of HSP-70 for the inflammatory response is
evident from a study in which HSP-70 was shown to induce potent anti-inflammatory effects
resembling induction of endotoxin tolerance in human monocytes.
Second, exposure to cold can induce an ischemia-reperfusion-like state in the skin and
peripheral tissue. A study into the effects of cryotherapy showed that local cooling of the
skin decreases local tissue perfusion. The combination of tissue hypoperfusion and
reperfusion upon the reactive vasodilatation that follows after rewarming is a form of
ischemia/reperfusion (I/R). The potency of I/R to protect tissue against ischemic damage is
known as Ischemic Preconditioning (IPC). It has the potential to influence the immune
response through several pathways. For instance, recent animal work has shown that I/R
results in downregulation of pro-inflammatory cytokines such as TNF-α and IL-6 and
upregulation of anti-inflammatory cytokines such as IL-10. Furthermore, hypoxia-inducible
factor (HIF) has been shown to be a major contributor to the I/R-induced IL-10 response.
Third, exposure to cold could have a potentiating effect on the adrenaline release evoked by
the breathing techniques. In a study of human volunteers, adrenaline levels were increased
after 2 hours of sitting in a cold room. Interestingly, in a study during acute exercise in
human volunteers, cold exposure prior to exercise was associated with an added
immuno-stimulatory effect. Also, cytokineresponse of IL-1beta and IL-6 in ex vivo
LPS-stimulated blood was lower in experienced ice-swimmers compared to inexperienced
ice-swimmers.
Taken together, cold exposure may influence the in vivo response to endotoxemia. This might
be mediated by direct, adrenaline-independent effects or by enhancing adrenaline levels
elicited by strength ventilation.
Synthesis This study aims to explore the effects of two elements of the intervention
initially developed by Hof, namely the strength ventilation breathing technique and the
exposure to cold, on the immune response during human endotoxemia. Effects of both elements
separately as well as in combination will be tested, the latter to explore the interplay
between the elements.
In addition, an assesment will be made of the effects of the (combination of) breathing
techniques and cold exposure on pain perception. In previous studies, trained subjects
experienced substantially less flu-like symptoms during endotoxemia. This could be due to the
attenuated immune response in these subjects, but also through other effects induced by the
breathing techniques and/or cold exposure. To investigate this, quantitative sensory testing
(QST) is used, an objective technique to measure pain thresholds.
Finally, non invasive measurements of oxygen tension in the mitochondria will be used to
asses mitochondrial function during human endotoxemia by using the Protoporphyrin IX-Triplet
State Liftime Technique (PpIX-TSLT).
Mitochondrial dysfunction is an important element in the pathophysiology of sepsis. However,
a valid non-invasive method to measure mitochondrial function is not yet available. In animal
models, the PpIX-TSLT technique has shown to be a feasible technique to measure alterations
in mitochondrial oxygen tension during endotoxemia. This has never been studied in humans
during endotoxemia. Furthermore, the exposure to cold and especially the breathing technique
may influence oxygen tension in the mitochondria as well, as blood gas parameters (e.g. pCO2,
acid base balance etc.) fluctuate to a large extent during the practicing of this technique.
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