Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT00901563 |
| Other study ID # |
CZB/4/520/b |
| Secondary ID |
|
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
March 2009 |
| Est. completion date |
August 3, 2015 |
Study information
| Verified date |
June 2021 |
| Source |
University of Edinburgh |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Hypothesis - Rotigaptide will improve endothelial function in the context of endothelial
dysfunction.
The lining of blood vessels (endothelium) can react to hormones in the blood stream causing
the blood vessel muscle to relax (vasodilatation) and allow more blood to flow. The nitric
oxide and prostacyclin pathways are well documented in this process. However, evidence points
to the existence of a third powerful relaxant called endothelium derived hyperpolarising
factor (EDHF) but its identity and mechanism of action have proved elusive. As well as
causing blood vessels to relax and more blood to flow, EDHF may be involved in the
endothelium signaling, triggering release of a specialised clot dissolving factor called
tissue plasminogen activator (t PA). t PA is important to ensure small clots, which are
constantly being formed in the circulation, are rapidly dissolved and do not grow large
enough to cause heart attacks and strokes.
Evidence points towards the requirement for 'gap junctions' in the mediation of EDHF
responses. Gap junctions are specialised pores which allow small molecules and charge to pass
between cells. They are found between endothelial cells and the underlying muscle of the
blood vessel. A drug called Rotigaptide has been developed to cause gap junctions to open. It
has been safely administered in healthy volunteers and is now in a Phase II drug trial. By
opening gap junctions the investigators hypothesise that it could increase EDHF mediated
activity and vasodilatation. It represents a useful tool with which to examine the role of
gap junctions in EDHF activity in vivo.
Previously the investigators have demonstrated that rotigaptide does not contribute to
endothelial function in healthy volunteers. The investigators now wish to examine the effect
of rotigaptide in conditions of endothelial dysfunction. By limiting the blood flow to the
arm for 20mins the ability of the blood vessel to vasodilate is impaired. By administering an
intra-arterial rotigaptide infusion the investigators want to assess any functional
preservation.
Description:
BACKGROUND The endothelium plays a pivotal role in the control of vascular tone and is
responsible for the local release of profibrinolytic factors. Nitric oxide (NO), the original
endothelium-derived relaxing factor, and prostacyclin (PGI2) have now been well
characterised. The elucidation of their roles in vascular physiology and pathophysiology has
been fundamental to recent advances in the treatment and prevention of many cardiovascular
diseases. Whilst these factors are of major importance, evidence points to the existence of a
third powerful vasodilator called endothelium-derived hyperpolarising factor (EDHF).
Endothelium-dependent vasodilatation -
After blockade of both NO and PGI2, a substantial degree of endothelium-dependent
vasodilatation is still observed and is attributed to EDHF. Despite almost two decades of
research and debate, the exact nature of EDHF and its mechanism of action remain unclear.
Consistently, EDHF's role as a vasodilator is most prominent in the smaller resistance
arteries that are responsible for the control of systemic blood pressure and local organ
perfusion. As well as its involvement in physiological processes, alterations in EDHF
activity may contribute to the vascular effects of the myriad of conditions either caused by,
or resulting in, endothelial dysfunction. However, the lack of understanding of EDHF has
precluded its direct manipulation as a specific therapeutic target.
Endogenous fibrinolysis -
In addition to its function in the control of vascular tone, there is evidence to suggest
that EDHF may be responsible for the endothelial release of the pro-fibrinolytic factor,
tissue-type plasminogen activator (t-PA).
Thrombus formation and dissolution is a continuous process in the vasculature and is
regulated by dynamic interactions between pro-coagulant and pro-fibrinolytic factors.
Endogenous fibrinolysis is determined by the relative balance between the acute local release
of t-PA from the endothelium and its subsequent inhibition by plasma plasminogen activator
inhibitor type 1 (PAI-1). In the presence of an imbalance in the fibrinolytic system,
subclinical microthrombi on the surface of atherosclerotic plaques may propagate and
ultimately lead to arterial occlusion and tissue infarction.
The mechanisms via which t-PA release is mediated are incompletely understood. Bradykinin, an
endogenous endothelium-dependent vasodilator, causes the endothelial release of t-PA.
However, Brown et al have demonstrated that inhibition of prostacyclin and nitric oxide
synthesis does not diminish bradykinin mediated endothelial t-PA release in the human
forearm. Therefore, they suggest that EDHF is responsible for the endothelial release of t-PA
but, to date, this hypothesis has not been adequately addressed.
Gap Junctions -
Gap junctions are found at points of cell-cell contact where they form an aqueous pore
through which small hydrophilic molecules and ionic charge may pass. Each gap junction
comprises two hemichannels, or connexons that are composed of six connexin (Cx) subunits.
Although each connexon may be composed of a mix of connexin subtypes, Cx37, Cx40 and Cx43 are
particularly associated with mammalian endothelium and vascular smooth muscle.
The case for a pivotal role of gap junctions in the EDHF phenomenon has strengthened. Gap
junction plaques are most abundant in small resistance arteries and their distribution is
proportional to the magnitude of the EDHF-mediated response. These topographical data have
been extrapolated to argue for a direct link between gap junctions and EDHF. Furthermore,
murine knockout models provide direct evidence for a role of gap junctions and specific
connexins in the control of vascular tone.
Potentiation of Communication via Gap Junctions -
Rotigaptide (ZP-123) is a novel hexapeptide (Ac-D-Tyr-D-Pro-D-Hyp-Gly-D-Ala-Gly-NH2),
originally developed as an antiarrythmic agent it has now been safely administered to healthy
humans as a six day continuous infusion of up to 20 mg (0.30 mmol) per day and is now in
Phase II clinical trials. It has been shown to promote electrical coupling between
ventricular myocytes by increasing gap junction conductance potentially via alterations in
the phosphorylation status of Cx43 and it increases the number of gap junctions in the
ischaemic myocardium It potentiates gap junction-mediated dye transfer via Cx43 expressing
HeLa cells but not via Cx26 or Cx32 but its effects on electrical conduction and dye transfer
via Cx37 and Cx40, the other major vascular connexins, have yet to be assessed. However, we
have recently shown that Cx43 is required for the mediation of EDHF vasodilatation of human
subcutaneous resistance vessels.
We have recently demonstrated that rotigaptide does not enhance endothelium-dependent or
independent forearm arterial vasodilatation in healthy volunteers. However there may be a
role for potentiating gap junctions under some circumstances. In animal models of myocardial
infarction those treated with rotigaptide had significantly reduced infarction sizes.
Endothelial dysfunction is central to the pathophysiology of diabetes and is responsible for
the vascular complications associated with this condition. In animal models of diabetes
reduced expression of connexins has been demonstrated with blunted response to EDHF,
suggesting a link between endothelial dysfunction and gap junctions.
Endothelial dysfunction can be mimicked in vivo with brief periods of ischaemia, resulting in
a reduced response to endothelium-dependant vasodilators. In the forearm arterial
circulation, we will test the hypothesis that rotigaptide-induced enhancement of
communication via gap junctions attenuates ischaemic endothelial dysfunction.
