Acute Kidney Injury Clinical Trial
Official title:
Impact of Perfusion Pressure During Extracorporeal Circulation on Postoperative Kidney Function
In Denmark around 3500 procedures are conducted involving a heart-lung-machine per year. An
increase in the prevalence of postoperative kidney insufficiency have been observed
following these procedures, during the last years. Kidney related complications are
associated with a higher mortality and morbidity.
The reason and mechanisms behind this impaired kidney function is unknown. One possible
cause could be that the blood pressure used in the heart-lung-machine is too low, during
surgery. In the PPC trial we plan to include 100 patients. One half of the patients are
operated with a normal, lower, blood pressure on the heart-lung-machine. The other half
receives a blood pressure of > 60 mmHg during surgery.
The primary goal of the trial is to measure the kidney function (GFR) the day before surgery
compared to day 4 - 6 and 4 months (+/- 14 days) after surgery. During the surgery a
catheter is inserted through the femoral vein into the kidney vein. This makes it possible
to measure several biochemical markers and the oxygen consumption of the kidney, during the
surgery. Urine samples are also collected and analyzed.
The study hypothesis:
The glomerular filtration rate (GFR) is better preserved after cardiac surgery with extra
corporal circulation with an intended increased periprocedural arterial blood pressure
compared to current practice.
1. Introduction:
Renal function and cardiac surgery
Impaired kidney function is a well known complication to cardiac surgery and is
observed in up to 30% of the patients, depending on the definition of acute kidney
injury (AKI). The precise pathophysiological mechanisms are unknown, it is, however,
quite obvious that AKI is not initiated by a single harmful factor but seems to be the
result of different combined factors. Known risk factors for the development of
postoperative AKI are cardiac incompensation, poor ejection fraction, gender, chronic
obstructive lung disease, insulin dependent diabetes mellitus (IDDM), previous heart
surgery, acute surgery, complexity of surgery, preoperative creatinine levels and
prolonged duration of extracorporeal perfusion. These associations are not necessarily
causal. It is not surprising that a subacute operation for a severe aortic stenosis in
a patient with preoperatively poor circulation and a marginally increased S-creatinine,
results in impaired renal function postoperatively. However, to conclude that cardiac
surgery is the reason for AKI is not justified.
Several peroperative factors are likely to contribute in the development of AKI. Renal
perfusion and oxygen delivery might be reduced (hypotension, lack of pulsatile flow
during extracorporeal circulation (ECC), vasoactive pharmacological agents,
anaesthesia), risk for emboli, general inflammatory response, direct nephrotoxins (free
haemoglobin, free radicals, gentamycin etc.) and haemodilution. Current knowledge is
limited and the general insight into regional perfusion during extracorporeal perfusion
(heart-lung-machine) is very sparse.
There do, however, exist guidelines regarding flow and blood pressure during ECC, but
these are based upon empiric data, which are controversial and vary from centre to
centre.
The primary focus has been on regional cerebral perfusion and the possibilities to
reduce the frequency of cerebral complications after cardiac surgery. This interest can
easily be explained by the obvious catastrophic consequences for the patient due to
coma, hemiparesis or serious cognitive dysfunction. The consequences of AKI are less
evident, however there is a direct and strong association between a moderately
increased postoperative creatinine level, reduced glomerular filtration rate (GFR) and
30 day mortality as long term survival.
A recent analysis of the kidney function of lung transplanted patients in our
department after use of ECC showed that GFR was dramatically reduced by 40% 14 days
after surgery. This impairment has furthermore been shown to be irreversible.
Cyclosporine A is known to be nephrotoxic in the long term, but this can hardly explain
the observed GFR reduction after 14 days, which must result from the combined influence
of surgical/anaesthesiological trauma, cyclosporine, and side effects of antibiotic,
antiviral, antifungal and immunosuppressive treatment.
Data from our internal prospective registry shows an increasing incidence of patients
with renal complications. In 2008 temporary dialysis was necessary in 7% of the
patients (76/1130) and in 19% of the patients a postoperative increase of S-creatinine
> 200 μmol/l was observed, mirroring a reduction in kidney function of 60-70%. We
assume that the kidney function is completely normalized over time, but this is
actually not known because these patients are not routinely controlled on a cardiac
surgery outpatient basis. Currently, we are gathering 1-year outcome data on patients,
who have undergone postoperative dialysis in 2008.
One of the reasons for the increasing frequency of AKI might be increasing patient age,
and thereby, an increase in comorbidity. At the same time the administration of ECC has
changed. Ten years ago patients were routinely cooled during ECC. This is not the case
anymore and results in a reduced degree of peripheral vessel constriction and
consequently reduced blood pressure. The question regarding which blood pressure and
which blood flow is optimal during ECC remains controversial, but generally a much
lower blood pressure is now accepted, as long as the calculated blood flow is
maintained and cerebral saturation values are sufficient (not measured routinely).
The literature on the subject is sparse but two randomized trials exists. One had a
primary focus on kidney autoregulation at different perfusion pressures, the other
recent trial could not demonstrate significant differences in kidney function measured
by s-creatinine at 3 different perfusion pressures. However, S-creatinine is a very
crude method for measuring kidney function. In addition, the trial included patients
with low risk of postoperative AKI.
Postoperative increase in S-creatinine typically occurs on day 2 or 3 after surgery,
and S-creatinine does not increase before GFR is reduced below 50%. This implies that
the possible initial 50% reduction in kidney function cannot be detected by routine
biochemistry. It is fair to assume that kidney injury occurs during surgery or within
the first postoperative 24 hours. From a biochemical point of view there is an apparent
lack of robust and reliable early markers of tubular kidney damage, which would allow a
relevant early clinical intervention, and possible prevention of AKI aggravation.
Creatinine kinases MB and troponins are very reliable markers for cardiac damage and
can reveal acute myocardial infarction within hours after the occlusion of coronary
vessels. A corresponding early diagnosis of AKI does not exist. At the same time it
seems likely that specific enzymatic or cell membrane components could be detectable in
the urine a few hours after an AKI. There has been some focus on possible candidates
for early detection of AKI, but none have shown to be sufficiently robust for clinical
use, yet.
During the last 20 years there have been a few trials with focus on prevention and
prophylactic intervention to avoid AKI with anti-inflammatory drugs, natriuresis
inducing agents (ANP) or renal blood flow increasing pharmacological intervention.
However, none of these interventions have had sufficiently convincing effects for
further clinical testing. A recent Japanese study seems to indicate that prophylactic
infusion of ANP can reduce postoperative kidney impairment, but these results need
confirmation.
Our department is currently performing a phase 2 trial in cooperation with Action
Pharma (a Danish biotech company) in which we are testing AP214, a new small
anti-inflammatory protein, with potential kidney protective characteristics
(clinicaltrials.gov: 00903604). At the same time we are investigating if AP214 can
reduce the nephrotoxic effect of cyclosporine in a pig kidney transplant model.
Summary / Conclusion:
- An increasing incidence of renal complications is seen after cardiac surgery.
- The aetiology is unknown.
- It is unclear if the reduction in renal function is reversible.
- Renal complications are associated with increased short- and long term mortality
and morbidity after cardiac surgery.
- Renal regional perfusion during extracorporeal circulation is poorly understood,
and the impact of blood pressure and perfusion on postoperative kidney function in
patients with increased risk for AKI after cardiac surgery is unknown.
- There are several potential biochemical markers for the early detection of acute
tubular kidney damage, however there is a substantial lack of clinical data.
- Several interventions might be kidney protective, however there are no robust
clinical data.
2. Hypothesis for the PPC trial
The glomerular filtration rate (GFR) is better preserved after cardiac surgery with ECC
with an intended increased periprocedural arterial blood pressure compared to current
practice.
3. Methods
1. Design:
Phase 1: Randomized proof of concept trial, n = 12. Simple 1:1 randomisation.
Phase 2: If the proof of concept trial turns out positive and logistically
feasible (which we have shown, see later) the trial will be extended to include 2
x 50 patients. There are no similar trials or data in the literature on which to
base an estimate of the necessary trial size. N = 100 is a qualified assumption
based on what is clinically possible to include within a 1-1½ year period. As
earlier shown in the lung transplant population GFR was reduced with 40%. A
clinically relevant improvement of an average reduction in GFR would be a
reduction of 20%. However, GFR data are quite heterogeneous and some patients have
perfectly normal GFR's throughout surgery and the postoperative course, while
others develop pronounced AKI.
Phase 3: Test of different preventive and prophylactic interventions (AP214,
proANP, reduced haemodilution, pulsatile flow during ECC).
Trial size and outcome measures will be dependent on results from phase 2. There
are no earlier data on continuous saturation measurement in renal venous blood or
sequential mass spectrometric analysis of urine in a cardiac surgery population.
Current results will therefore decide on future primary outcome measures.
2. Inclusion- and exclusion criteria:
Patients with increased risk of postoperative AKI, who give written consent after
appropriate information, are included.
Inclusion criteria are:
- Age > 70
- Combined procedures (heart valve-, bypass surgery and aortic aneurysm)
Exclusion criteria are:
- Age < 70
- S-creatinine > 200 µmol/L
- Acute operation
- Endocarditis
3. Intervention:
Control group:
Operation procedure and ECC run are performed according to current guidelines at
the Dept. of Thoracic and Cardiovascular Surgery / Rigshospitalet.
Intervention group:
During ECC run a MAP > 60 mmHg is maintained.
In both groups GFR measurements are performed using the Cr-EDTA clearance method.
GFR is measured the day before surgery, day 4-6 after surgery and finally after 4
months (+/- 14 days).
A catheter is inserted in the renal vein through the femoral vein. The position is
controlled by fluoroscopy. Repeated saturation measurements, by blood gas
analysis, will be performed during and in the first 24 hours after surgery. Blood
samples are taken from the same access. The catheter is removed before discharge
from the intensive care unit.
4. Outcome measures:
Primary outcome measure: Cr-EDTA clearance, the day before surgery, at day 4 - 6
and 4 months (+/- 14 days) after surgery
Secondary outcome measures:
- Oxygen consumption on-line in renal venous blood
- Renal renin and proANP excretion
- U-NGAL, U-Apolipoprotein M, U-IL-18, U-KIM-1 and S-cystatin C
- Urine proteomics (mass spectrometry)
Tertiary outcome measures:
Standard clinical data collection (haemodynamics, diuresis, routine biochemistry)
and clinical outcome in terms of time in intensive care, time to discharge,
incidence rates of adverse- and serious adverse events.
5. Economy:
This investigation is a non-profit trial. None of the project members have economic
interests in the trial. The involved clinical departments cover direct and indirect expenses
regarding the prolonged admission, GFR-measurements and additional biochemical analyses
estimated to be 15.800 DKK per patient.
The Danish Heart Association covers the salary for Ph.D. student Kristian Kandler.
5: Perspectives
This project combines expert knowledge from different medical fields on a highly scientific
and clinical level (advanced cardiac surgery in high risk patients, advanced postoperative
intensive care, innovative monitoring (invasive, biochemical, clinical physiology). We
expect to provide original, innovative and scientifically relevant results that will
contribute to a better understanding of the renal pathophysiology and autoregulation during
and after cardiac surgery. As a clinical randomised trial this study may show new
possibilities to reduce the incidence of postoperative renal complications in a group of
patients with significant mortality and morbidity.
;
Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Open Label, Primary Purpose: Prevention
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