Infection Clinical Trial
Official title:
the Influence of Remote Ischemic Preconditioning on Inflammation During Human Endotoxemia, a Pilot Proof-of-principle Study
In a wide range of auto-inflammatory and infectious diseases attenuation of the immune response could be beneficial. Remote ischemic preconditioning (RIPC) has been identified as a means of protecting patients undergoing cardiac surgery from perioperative myocardial ischemic damage. This protection can be divided in a `first window of protection` directly after preconditioning and a `second window` that protects patients 12-48 hour after preconditioning. Repeated RIPC might have additional value, possibly by combining beneficial effects of the first and second windows of protection. The mechanisms behind these effects are under investigation, but attenuation of the inflammatory response is a major candidate. However, this has not yet been demonstrated in the setting of systemic inflammation in humans in vivo. This study aims to investigate the effects of (repeated) ischemic preconditioning on inflammation during human endotoxemia.
Although the immune system is essential to survival, a variety of diseases originate from
inappropriate or excessive activation of the immune response. Examples include a wide range
of auto-inflammatory disease, infectious diseases such as sepsis, but also after major
surgery like cardiac artery bypass grafting, after radiation therapy in the treatment of
cancer, or following organ transplantation. In these instances, attenuation of the immune
response could be beneficial.
The concept of ischemic preconditioning (IPC) was first described in the 1980`s. Murry and
colleagues showed a protective effect of preconditioning the heart with 4 cycles of 5-minute
long ischemia on the extent of myocardial infarction in dog hearts. Follow-up animal studies
showed the same protective effects on the heart by introducing the cycles of ischemia to
distant, or `remote`, organs like the kidney or the gut. Furthermore, this principle of
`remote ischemic preconditioning` (RIPC) was also shown to be effective in humans when using
a tourniquet to temporary cut off blood supply to one of the limbs, either an arm or a leg.
As such, RIPC has been identified as a cheap and easy method of protecting patients
undergoing elective CABG surgery from perioperative myocardial ischemic damage. In recent
studies, two different timeframes in which RIPC exerts its protective effects have been
identified. The classical or `early window of protection' protects in the 1-2 hour after the
RIPC stimulus while a `second window of protection` is evident 12-24 hours after RIPC and
lasts for 48-72 hours. Multiple-dose RIPC may be of additional value, as 7 daily doses of
RIPC in humans resulted in protection of endothelial dysfunction, with both the local and
remote beneficial effects lasting for up to 8 days after the last RIPC dose. This could be
due to additive or synergistic effects of combining the first and second windows of
protection.
The mechanisms behind the observed protective effects are however still subject of
investigation. Several have been put forward, of which attenuation of the inflammatory
response is a major candidate.
For instance, recent animal work has shown that RIPC results in downregulation of
pro-inflammatory cytokines such as TNF-α and IL-6 and upregulation of anti-inflammatory
cytokines such as IL-10. In support of the latter, the cardioprotective effects of RIPC were
absent in IL-10 knockout mice or in wild-type mice treated with a monoclonal antibody
against the IL-10 receptor. Hypoxia-inducible factor (HIF) has been shown to be a major
contributor to this RIPC-induced IL-10 response.
Adenosine appears to be a major determinant of the anti-inflammatory and tissue-protective
effects of RIPC. In a in vivo forearm model, adenosine and ischemic preconditioning both
resulted in the same reduction in ischemia-reperfusion injury. Also, administration of
exogenous adenosine can mimic the protective effects of IPC, and antagonizing the adenosine
receptor with caffeine blocks the protective effects of RIPC and augments the
anti-inflammatory IL-10 response to lipopolysaccharide (LPS). Interestingly, one of the
pathways in which ischemia-reperfusion can increase adenosine levels is through upregulation
of CD73, which is dependent on the aforementioned HIF.
Another possible mechanism behind the anti-inflammatory effects of RIPC is release of
Toll-like receptor (TLR) ligands, which in turn induce an endotoxin tolerance-like state.
Endotoxin tolerance is a refractory state of the immune system after challenge with the TLR4
ligand LPS, characterized by diminished cytokine production upon a subsequent LPS challenge.
However, induction of endotoxin tolerance was found to occur not only after LPS challenge
but also using other TLR(4)-ligands, so-called 'cross-tolerance'. A possible candidate to
induce tolerance in RIPC is heat shock protein 70 (HSP70), as extracellular HSP70 has been
shown to induce tolerance to LPS in monocytes in vitro. Furthermore, in rats receiving
ischemic preconditioning of the lower extremity, HSP70 expression was increased in the
spinal cord and myocardium, and HSP70 upregulation was found in cardiomyocytes after RIPC in
infants undergoing cardiac surgery. However, other, yet unidentified TLR ligands could also
be involved.
From the abovementioned studies, it appears that RIPC exerts significant effects on the
immune response. However, this has not yet been demonstrated in the setting of systemic
inflammation in humans in vivo. Furthermore, the mechanisms behind the putative
anti-inflammatory effects and possible additive or synergistic effects of repeated RIPC
(thereby combining both the first and second windows of protection) are unknown as well.
This study aims to investigate the effects of (repeated) ischemic preconditioning during
human endotoxemia, a standardized controlled model of inflammation.
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Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Open Label, Primary Purpose: Basic Science
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