Official Title
Does the Human Gut Microbiome Serve as a Novel Personalized Therapeutic Target for Coronary Atherosclerosis?
Brief Title
Does the Human Gut Microbiome Serve as a Novel Personalized Therapeutic Target for Coronary Atherosclerosis?
Protocol ID
NCT03009565
Lead Sponsor
Rabin Medical Center
Brief Summary
Background: The human gastrointestinal system is populated with a variety of symbiotic
microorganisms, namely microbiota. The microbiome is the total genetic data of the
microbiota. The human gut microbiota interacts extensively with the host through
metabolic exchange; thereby contribute to a variety of metabolic and immunologic
mechanisms in the human body. Coronary artery disease (CAD) is major cause of morbidity
and mortality worldwide and is a major field of interest in microbiota research. There
have been several findings that connect the gut microbiota to CAD pathophysiology, but
these data relates solely to the interaction between human gut microbiome and
cardiovascular risk factors. As far as known , data regarding patients who already
developed CAD is lacking.
Aims: To investigate gut microbiota of patients with CAD, thereby allowing the adjustment
of personalized treatment by changing the pro-atherosclerotic environment in the gut.
Methods: Study participants will include patients arriving to Rabin Medical Center with
suspected CAD. Patients will provide medical, lifestyle, and nutritional questionnaires.
Vital signs measurements will be taken as well as fecal samples and/or rectal swabs.
Blood samples will be drawn to measure blood chemistry including lipid profile and
trimethylamine-N-oxide (TMAO) levels. Patients will undergo cardiac CT and/or cardiac
catheterization in accordance with the decision of the cardiologist to evaluate and/or
treat CAD. Genomic DNA will be extracted from stool samples for Microbiome analysis.
Innovation: The hypothesis is that there is a unique microbiota pattern in patients with
coronary atherosclerosis, which may contribute to the pathogenesis and/or expression of
CAD. Knowing the unique microbiota in patients with coronary disease, would render it as
novel target for treatment, either primary or secondary prevention.
Collaboration: Between Cardiology department at Rabin Medical Center and the lab of Prof.
Eran Segal located at the Weizmann Institute of Science. The collaboration between these
two groups will combine the clinical expertise of treating cardiac patients with novel
scientific technology and concept.
Detailed Description
Introduction:
The human gastrointestinal system is populated with a variety of symbiotic
microorganisms, namely microbiota. Its total weight is approximately 2 kilograms,
containing trillions of microorganisms. The microbiome is the total genetic (metagenomic)
data of the microbiota. In recent years, the development of efficient methods for genome
sequencing and bio-informatics has enabled fast and accurate quantification and
qualification of the microbiome, made microbiome analysis leading method of microbiota
research.
Coronary artery disease (CAD) accounted for more than 8 million deaths yearly worldwide.
In particular, acute coronary syndrome (ACS) remains a major cause of morbidity and
mortality and is responsible for more than 1 million hospital admissions in the United
States annually. The pathophysiologic hallmark of ACS is coronary thrombosis caused by
atherosclerotic plaque injury, with two types of injuries being described. The first is
plaque rupture, which remains the most common cause of coronary athero-thrombosis, and
the second is superficial plaque erosion which is recognized with increasing frequency.
As opposed to plaque rupture, lesions that are caused by erosion do not have thin fibrous
caps, abundant inflammatory cells, or a large lipid core, but rather rich in
extracellular matrix, such as proteoglycans and glycosaminoglycans.
Imaging studies such as coronary computed tomographic angiography (CCTA) and diagnostic
coronary catheterizations with or without optical coherence tomography (OCT) are being
used increasingly in clinical practice in order to characterize the mechanism responsible
for unstable/vulnerable atherosclerotic plaque.
The human gut microbiota interacts extensively with the host through metabolic exchange
and co-metabolism of substrates; thereby contribute to a variety of metabolic and
immunologic mechanism in the human body. CAD is a major field of interest in microbiota
research, and there have been several findings that connect the gut microbiota to CAD
pathophysiology. First, microbiota was associated with metabolic syndrome, namely obesity
and insulin resistance. It is hypothesized that gut microbiota may increase short-chain
fatty acid, that eventually increase appetite, thus causing obesity. Another hypothesis
is that gut microbiota endotoxins may translocate into the bloodstream, elicit
inflammatory cascade that eventually promote atherosclerosis. Second, microbiota may also
have a role in the development of atherosclerosis. In patients with symptomatic
atherosclerosis, there is a unique microbiome pattern that may have pro-inflammatory
characteristics. Recently, a unique microbial pattern was found among patients with high
cardiovascular risk profile. Third, gut microbiota metabolize dietary phosphatidylcholine
(lecitine) to produce the metabolite trimethylamine-N-oxide (TMAO), which is associated
with increased risk of cardiovascular events.
The data published so far relates solely to the interaction between human gut microbiome
and cardiovascular risk factors. To the best of the investigator's knowledge and
understanding, the microbiome analysis of patients with an established diagnosis of CAD
(including ACS) is lacking.
Objectives:
The purpose of the current study is to investigate the gut microbiota of patients with
symptomatic CAD, both in stable and during acute phases. The investigators hypothesize
that the study participants would present with a unique microbiome signature that may
provide a novel insight into the pathophysiology of atherosclerotic CAD while affording
putative therapeutic implications.
After establishing the unique microbiome signature in a large cohort of CAD patients, the
investigators would correlate it to TMAO levels to further investigate its part in the
pathophysiology of CAD. In the final stage, the investigators would try to find ways to
adjust personalized treatment options to change the "pro-atherosclerotic" gut microbiota.
By using data from the current study with the investigators' previous 1000 patient cohort
with known microbiome and nutritional profile, it would be able to search for a specific
target for nutritional intervention, such as probiotics. Then, the investigators would
monitor the patients with sequencing the microbiome after the nutritional intervention.
Methods:
Study design and recruitment. Study participants will be patients aged 30-80 arriving to
Rabin Medical Center with suspected CAD and able to provide informed consent.
Participants will provide medical, lifestyle, and nutritional questionnaires. Blood
pressure and heart-rate measurements will be taken during hospitalization as well as
blood tests and fecal samples and/or rectal swabs. In order to evaluate and/or treat
suspected atherosclerotic disease participants will undergo cardiac CT and/or cardiac
catheterization in accordance with the standard of care and based upon the decision of
the treating cardiologist. Diagnostics and treatment options will be based only on
participants' medical condition and regardless of the aforementioned study protocol.
The control group will be selected to represent an age, sex and cardiovascular risk
factors -matched group without current CAD. Further exclusion criteria in the control
group will be antibiotic consumption in the following 3 months, inflammatory bowel
disease, or other significant chronic disease that may influence the microbiota (such as
cancer, autoimmune disease, and chronic immunosuppressive treatment). The control group
will undergo cardiac CT or coronary angiography according to clinical suspicion in order
to rule-out CAD and irrespective of the study protocol.
Blood samples. 10 ml venous blood will be collected into Ethylenediaminetetraacetic acid
(EDTA) and gel with clot activator -containing tubes from the enrolled patients in all
study participants. The concentrations of serum creatinine, troponin, creatine
phosphokinase (CPK), hemoglobin, triglycerides (TG), total cholesterol (TC), high-density
lipoproteins (HDL), low-density lipoproteins (LDL), glucose, c-reactive protein (CRP),
b-type natriuretic peptide (BNP) and hemoglobin A1c (HbA1C) will be measured by automatic
biochemistry analyzer.
In addition, the levels of TMAO will be measured from blood plasma by using Ultra-High
Performance Liquid Chromatography - Mass Spectrometric - Multiple Reaction Monitoring
(UHPLC-MS/MRM) as previously described.
Nutritional profiling. All participants will report their habits of food consumption by
filling up the Food Frequency Questionnaire (FFQ).
Cardiac CT analysis. Selected participants will undergo CT angiography for the evaluation
and quantification of CAD using a 256-slice system (Brilliance iCT, Philips Healthcare,
Cleveland, Ohio). Data will be acquired with a collimation of 96 X 0.625 mm and a gantry
rotation time of 330 ms. Intravenous injection of 60 to 90 ml of nonionic contrast agent
at a flow rate of 5 ml/s will be followed by a 30-ml saline chase bolus (3 ml/s).
Acquisition will be performed during an inspiratory breath hold while the
electrocardiogram will be recorded simultaneously to allow, dependent from the heart
rate, retrospective or prospective gating of the data. All images will be reconstructed
with a slice thickness of 0.67 mm and a slice increment of 0.34 mm. The complete dataset
will be transmitted to a dedicated CT workstation with a 3-dimensional reconstruction
tool specifically designed for coronary angiography (Philips Intellispace Portal, version
7.0) to allow for multiplanar reformations and quantitative plaque analysis. An
independent reader will review all studies. Each vessel containing significant stenosis
will be analyzed in curved multiplanar reformatted images in long-axis and
cross-sectional views. Diameters at the site of maximum stenosis and at proximal and
distal references will be measured. Degree of stenosis will be calculated as the ratio of
the difference between the diameter at maximum stenosis and the mean of diameters at the
proximal and distal references divided by the mean of diameters at proximal and distal
references and expressed as percentage. Remodeling index will be calculated as the outer
vessel area at the site of maximum stenosis divided by the mean of outer vessel areas at
proximal and distal references. Positive remodeling will be defined as a remodeling index
≥ 1.05. Plaque volume will be automatically calculated as the volume of all voxels
segmented between the luminal and outer vessel boundaries on curved multiplanar
reformatted images. Proximal and distal references will be used as the proximal and
distal ends of the plaques. The investigators will report the total volume of plaque and
volumes of plaque subtypes: calcified, non-calcified, and mixed plaques.
Cardiac catheterization and percutaneous coronary intervention (PCI). Patients will be
admitted to the catheterization laboratory according to their clinical presentation,
taking into account the current ESC/AHA clinical guidelines. The cardiac catheterization
procedure will be performed using standard percutaneous techniques via the radial or
femoral artery. Coronary lesions will be evaluated by the operator in terms of stenosis
by visual estimation or other using objective measurements, such as quantitative coronary
analysis (QCA). Coronary intervention, including balloon angioplasty and stent
implantation will be implemented as needed and according to the severity of coronary
stenosis i.e. (≥70% diameter stenosis). Adjunctive coronary imaging (OCT or intravascular
ultrasound) will be performed according to operator's discretion and regardless of the
study protocol. All patients will be treated during the procedure with anticoagulation
(mostly unfractionated heparin) using careful monitoring of activated clotting time
between 250-300 seconds. After the angioplasty procedure, all patients will be treated
with dual anti-platelet therapy combining aspirin and P2Y12 inhibitor (clopidogrel,
prasugrel or ticagrelor, according to the clinical indication) for 6-12 months, unless
there will be contra-indication, such as treatment with oral anti-coagulants.
Genomic DNA Extraction and Filtering. Genomic DNA from stool samples will be purified
using PowerMag Soil DNA isolation kit (MoBio) optimized for Tecan automated platform. For
shotgun sequencing, 100 ng of purified DNA will be sheared with a Covaris E220X
sonicator.
Microbiome analysis. Microbiome samples will be processed by an automated robotic
pipeline in 96-well format. Each sample group collected will be processed robotically for
both 16S and metagenomic sequencing.
Generating microbiome-based features. The investigators will employ and further extend a
computational pipeline that was developed for generating a rich set of features from a
metagenomic sample. These features will be the basis for models that identify
microbiome-based signatures.
Bacterial and viral abundances - Mapping the metagenome sample to a reference bacterial
genome database, and then counting the number of reads mapping to each bacteria,
resulting in a vector of relative bacterial abundances for each sample.
Bacterial diversity - Using the relative bacterial abundances derived above, the
investigators will compute several measures of the diversity of bacteria and viruses in a
metagenome sample (e.g., Shannon entropy of the relative abundance vector, number of
bacteria above some minimal abundance level), as sample diversity was shown to be
associated with certain physiological aspects of the host such as overall adiposity and
insulin resistance.
Bacterial growth rates - For each metagenome sample, the investigators will compute a
vector that corresponds to the growth rate of each bacteria in the sample, using a novel
method that was recently developed for this purpose. Briefly, by examining the pattern of
sequencing read coverage (depth) across the length of different bacterial genomes, the
investigators found that many bacteria exhibit a prototypical coverage pattern,
consisting of a single trough and a single peak. Notably, the location of the peak
coincides with the bacteria's known origin of replication, suggesting that the added read
coverage near the peak represents newly replicated DNA. For any given bacteria, the ratio
between the peak and trough coverage varies greatly across samples from different human
gut microbiomes, with high ratios being similar to those obtained during exponential
growth phase of bacteria grown in culture, and low ratios being similar to growth in
stationary phase.
Gene abundances - The investigators will compute the relative abundances of genes in
metagenome samples by applying a similar approach to that above for deriving relative
abundances of bacteria. To this end, rather than mapping the reads to the reference
bacterial genome database, the investigators will map them to a reference database of
bacterial genes which was recently extended and that collectively contain over 3 million
distinct bacterial genes. The derived gene abundance vectors are complementary to the
bacteria abundance vectors, with the advantage being mapping to genes whose embedding
bacterial genome is unknown and thus allowing more metagenome sequencing reads to be
mapped, and with the disadvantage of producing a much larger feature vector.
Biological pathway abundances - As another set of features that provide information at
the functional level of the microbiota, the investigators will use the KEGG database of
biological pathways51 and the above vector of gene abundance of each sample to compute an
abundance score for each biological pathway. The key advantage of this set of features is
that its associations provide direct hypotheses regarding the underlying mechanisms
through which the microbiota may be involved with the correlated phenotype.
Sample storage. The samples as well as remaining DNA and frozen serums will be stored in
-80C freezers. Unprocessed stool samples (e.g., not all samples collected annually will
be processed initially) will also be stored in -800C freezers.
Statistical analysis. Clinical data such as vital signs, cardiovascular risk factors
(age, gender, lipid profile, glycemic index, smoking status, previous CAD), chronic
co-morbidities, regular drug use, imaging findings on cardiac CT and/or cardiac
catheterization as well as cardiac enzymes levels will be collected at Rabin Medical
Center. At the Weizmann institute of science, in the computer science department by the
Segal Lab, the investigators will analyze the data. For each parameter an association
analyses will be performed to identify all of the microbiome parameters that are
associated with these clinical parameters.
After analyzing the microbiome signatures in those patients, where known probiotic and/or
nutritional interventions can lead to the desired change the investigators will intervene
and then monitor with sequencing the microbiome after the intervention.
Enrollment Count
800 participants
Eligibility Criteria
Inclusion Criteria:
- aged 30-80
- arriving to Rabin Medical Center with suspected CAD
- able to provide informed consent
Exclusion Criteria:
- antibiotic consumption in the following 3 months
- inflammatory bowel disease
- other significant chronic disease that may influence the microbiota (such as cancer,
autoimmune disease, and chronic immunosuppressive treatment)
Filters
Coronary (Artery) Disease
UNKNOWN
ADULT
OLDER_ADULT