Cardiac Allograft Vasculopathy Clinical Trial
Official title:
Cardiac Mitochondrial Function After Heart Transplantation
Studies have shown that cardiac function is affected immediately after heart transplantation
(HTx), but seems to recover to some extent over the first year. This immediate effect is
associated with lack of oxygen in the tissue and reperfusion injury causing cellular energy
depletion, mitochondrial failure and cellular damage. This condition may progress into full
blown primary graft failure (PGF), characterized as deterioration of the transplanted heart,
which is seen in 3-30 % of HTx patients. In addition to PGF, chronic rejection owing to
cardiac allograft vasculopathy (CAV) may develop.
PGF and CAV remain the major heart related mortality causes, and additional assessment and
treatments are therefore needed.
Acute cellular rejection (ACR) is diagnosed based on endomyocardial biopsies (EMB), which are
routinely performed to ensure prober immunosuppression in HTx patients. ACR occur in
approximately 25% of HTx patients, and is associated with PGF and CAV. However, mitochondrial
function and integrity may prove to be a more sensitive marker of allograft rejection than
endomyocardial biopsies. Therefore, assessment of mitochondrial function may allow for
earlier detection of allograft rejection and dysfunction. This may be of particular
importance as emerging treatments are targeting both energy substrate supply for
adenosine-triphosphate generation produced by the mitochondria and mitochondrial function in
the failing heart.
Despite the association between graft rejection and mitochondrial function, it remains
unsettled whether mitochondrial function associate with PGF, ACR and CAV. Such findings may
be of prognostic importance and even elucidate new treatment targets. Hence, we evaluate the
mitochondrial status in HTx patients through four studies designed to assess different
aspects of the interplay between cardiac function and mitochondrial integrity and function.
Hypotheses:
Study 1: Primary graft pump function is correlated to mitochondrial function in the first
myocardial biopsy taken from the donor heart during the operation.
Study 2: Cardiac mitochondrial function improves over the first 3 months after a heart
transplantation.
Study 3: Heart transplant patients with moderate to severe coronary graft vasculopathy has
impaired mitochondrial function.
Study 4: Myocardial external energy efficiency by positron-emission tomography can be used as
a marker of mitochondrial function and chronic rejection in HTx patients.
Background
The prognosis after heart transplantation (HTx) has improved considerably since the first HTx
was performed in 1967. Studies from our group have shown both left and right ventricular
function is affected immediately after heart transplantation, but this seems to recover to
some extent over the first year. This immediate effect on the graft organ following HTx is
associated with tissue ischemia and reperfusion injury causing cellular energy depletion,
mitochondrial failure and subsequent apoptosis. The condition may progress into full blown
primary graft failure (PGF) with a need for mechanical cardiovascular support or inotropes
which is seen in 3-30 % of HTx patients. The cardiac injury will consequently increase the
risk of morbidity as well as mortality. In addition to acute PGF, a chronic rejection owing
to coronary arterial vasculopathy (CAV) may develop. Hence, despite advances in
peritransplantation treatment and immunosuppression, PGF and CAV remain the major heart
related mortality causes following HTx and additional assessment and treatments are therefore
needed.
Graft rejection is diagnosed, and the severity graded based on endomyocardial biopsies (EMB)
taken percutaneously through the jugular or femoral veins. These biopsies are routinely
performed at our institution to ensure prober immunosuppression following HTx.1 Acute
cellular rejection (ACR) may occur in approximately 25% of the patients which is associated
with PGF, CAV and later chronic rejection. However, mitochondrial function and integrity may
prove to be a more sensitive marker of allograft rejection. In heart failure, mitochondria
density changes while function and integrity is impaired linking the failing heart to energy
deprivation. Animal studies demonstrate that deterioration in total mitochondrial function
precedes histopathological changes during cardiac graft rejection following HTx. Therefore,
assessment of mitochondrial function following HTx may allow for earlier detection of
rejection and allograft dysfunction. This may be of particular importance as emerging
treatments are targeting both energy substrate supply for adenosine-triphosphate (ATP)
generation produced by the mitochondria as well as mitochondrial function in the failing
heart. At our institution, we have established methods to evaluate mitochondrial function in
myocardial tissue, and pilot studies have demonstrated feasibility with the use of EMB. In
addition, by use of non-invasive 11C-acetate positron-emission tomography (PET), we can
assess myocardial external energy efficiency (MEE) calculated by the ratio of myocardial
external work (EW) and oxidative metabolism (MVO2). Thus, enabling quantification of coupling
between mitochondrial energy production and mechanical work.
Despite the overt association between graft dysfunction/rejection and mitochondrial function,
it remains unsettled whether mitochondrial content and function associate with PGF, ACR and
CAV. Such findings may be of prognostic importance and even elucidate a new treatment target.
Hypotheses
1. Primary graft pump function is correlated to mitochondrial function in the first
myocardial biopsy taken from the donor heart during the operation
2. Cardiac mitochondrial function improves over the first 3 months after a heart
transplantation
3. Heart transplant patients with moderate to severe coronary graft vasculopathy has
impaired mitochondrial function
4. MEE can be used as a marker of mitochondrial function and chronic rejection in HTx
patients
Objectives
Study 1: To examine whether primary myocardial function is related to cardiac mitochondrial
function in de novo HTx patients
Study 2: To investigate whether cardiac mitochondrial function improves over time after HTx
along with improvement of cardiac function
Study 3: To examine whether heart transplanted patients with chronic rejection and graft
vasculopathy have impaired mitochondrial function
Study 4: To evaluate whether MEE can be used as marker of mitochondrial function and chronic
rejection
Design and endpoints
Study 1: The association between cardiac and mitochondrial function following HTx
Design: Myocardial mitochondrial function analyzed from 15 HTx patients taken from the donor
heart during the transplantation will be compared to EMB from 15 HTx patients at scheduled
biopsies (1 or 2 years after implantation)
Study 2: Development in cardiac and mitochondrial function following HTx Design:
Mitochondrial function measured at scheduled EBM follow-up (1,2,3,4,8,12 weeks and 6 months
after HTx) from 24 HTx patients. These results are compared to 15 patients with biopsies
performed at 1 and 2 years after HTx.
Study 3: The impact of coronary arterial vasculopathy on mitochondrial function Design:
Mitochondrial function assessed at scheduled EMB follow-up visits of patients with CAV as
determined by coronary angiography (scheduled procedure) 15 HTx patients CAV are compared to
15 HTx patients with without CAV.
Study 4: MEE as a non-invasive marker of mitochondrial function and allograft rejection
Design: 24 HTX patients scheduled for EMB will be examined twice with 11C-acetate-PET. It is
intended that we consecutively recruit patients enrolled in study 2. The first examination is
performed within 3 weeks following HTx and the second examination after 6 months. Up to 4
weeks between EMB and the second 11C-acetate PET examination is accepted.
(The HTx patient cohort which is subjected to biopsies 1 and 2 years after HTx in study 3
(n=15) is reused in study 1 and 2 as a comparable cohort. Hence, a total of 69 patients are
enrolled. However, it is anticipated that several patients from study 1 and are enrolled in
study 2 which will decrease the total number of participants.)
Methods
Mitochondrial function will be assessed in myocardial biopsies by High-resolution
respirometry and Electron microscopy
Cardiac functions is assessed by transthoracic echocardiography
Coronary Angiography is performed to assess the degree of CAV
Blood samples will be taken
In study 4, MEE will be assessed by positron emission tomography using validated kinetic
methods.
Ethical considerations
The project will be carried out in accordance with the principles of the Helsinki Declaration
II. The protocol, including the written participant information and consent forms must be
finally approved by the Research Ethics Committee of the Central Denmark Region and .
Publication and study plan All results, whether positive, negative or inconclusive will be
published in an international peer-reviewed scientific journal.
Perspectives Cellular rejection (ACR) shortly after HTx is strongly associated with the
long-term development of CAV and subsequent myocardial dysfunction. As graft failure and CAV
are the major long-term heart-related late mortality causes following HTx, it seems paramount
to modify long-term hazards such as ACR, CAV, and graft failure to significantly improve
post-transplant outcome.5 In this context mitochondrial function seems to be pivotal, hence,
approaches to assess mitochondrial function in HTx patient may prove to pave the way for new
follow-up algorithms and even treatment targets.
;
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