Cardiac Markers PH 167 PDF

Summary

This is a presentation on cardiac markers for acute coronary syndrome (ACS) and congestive heart failure (CHF). It covers the anatomy and physiology of the heart, pathophysiology of atherosclerosis, and various cardiac markers. The document also includes information on the diagnosis and treatment of cardiac conditions.

Full Transcript

upcph

Cardiac Damage and Function
Raycha Lei Concess M. Rama-Sabandal, RMT, DAP&E, MPH
Department of Nutrition

COLLEGE OF PUBLIC HEALTH
UNIVERSITY OF THE PHILIPPINES MANILA
SEAMEO TROPMED Philippines
Regional Centre for Public Health, Hospital Administration, Environmental and Occupational Health
Outline
I. Review on the anatomy and physiology of the heart
II. Brief Pathophysiology of Atherosclerosis
III. Cardiac Damage (ACS vs CHF)
IV. Markers for Cardiac Damage
A. For ACS
B. For CHF
C. For CVD Risk
Session Outcomes:
Describe the anatomy of the heart
Explain the origin of general symptom of cardiac disease
Identify risk factors for coronary heart disease
Discuss the features of an ideal cardiac marker
Describe the clinical utility/diagnostic significance of each
cardiac marker
Review of Heart Anatomy and Physiology
Average human adult heart weights ~325 g in men
and 275 g in women
Pericardium – sac which encloses it
4 chambers of the heart: LA, RA, LV, RV
Cardiac wall has 3 layers:
Epicardium – outer most layer;
the coronary arteries (supply blood to the
cardiac wall) are located
Myocardium – middle layer;
contains bundles of straited muscle fibers
Endocardium – inner layer; continuous with the This Photo by Unknown Author is licensed
endothelium of blood vessels under CC BY-NC-ND

Most susceptible to myocardial ischemia
Review of Heart Anatomy and Physiology
Muscle fibers of the myocardium:
Their alternating contraction and relaxation generate the “pumping”
work of the heart
Contain the contractile proteins: actin and myosin
Contain troponins à regulate contraction

Cardiac cycle – has two intervals (systole, diastole)
Controlled by cardiac conducting system

Electrocardiogram (ECG) – records the changes in electrical potential and is
a graphic tracing of the variation in electrical potential caused by the
excitation of the heart muscle
Cardiovascular Diseases

Two of the most common CVDs that rely on a biochemical
(i.e. biomarker) diagnosis:

acute ischemic disease à acute myocardial infarction
(AMI) is the most severe form

heart failure à AKA congestive heart failure (CHF)
Epidemiology

In the Philippines (PSA, 2022):

Ischemic heart diseases were the leading cause of
death with 29,442 cases or 18.7 percent of the
total deaths in the country from Jan-Apr 2022.
1. Acute Myocardial Infarction
Occurs when there is imbalance of supply and demand for
oxygen in myocardium à injury to and the eventual death of
myocytes
Necrosis/cell death in myocardium: When blood supply is
blocked for more than a few minutes, many/most myocytes in
the affected region die
Lesser severity: may be missed or be called angina (stable to
unstable)
Angina: a condition marked by severe pain in the chest, often also
spreading to the shoulders, arms, neck
Stable angina – activity induced chest pain
Acute Coronary Syndrome (ACS)
Refers to all ischemic events in the heart, ranging from:
Cell death/necrosis
No cell death
Acute myocardial
Angina
infarction

ST segment elevation myocardial infarction (STEMI)
the ECG typically shows elevation of a portion called the ST
segment in severe form of AMI
Non-ST segment elevation myocardial infarction (NSTEMI
or non-STEMI)
Partial loss of coronary perfusion (may lead to necrosis if severe) but
the magnitude of cell death is generally less; ECG does not show
elevation of the ST segment
Acute Coronary Syndrome (ACS)
Refers to all ischemic events in the heart, ranging from:

No cell death Partial necrosis Complete necrosis
Angina NSTEMI STEMI

Cell death/necrosis
Acute myocardial
infarction
 ECGs from a patient with AMI The sequence is:
(A) normal,
(B) hours after infarction,
the ST segment
becomes elevated,
(C) hours to days later,
the T wave inverts and
the Q wave becomes
larger,
(D) days to weeks later,
the ST segment
returns to near normal,
and
(E) weeks to months later,
the T wave becomes
upright again, but the
large Q wave may
remain.
Patients with STEMI usually will develop Q waves on their ECG
à Q-wave MI
Atherosclerosis: major cause of ACS

Disease caused by a plaque (deposit of fatty material) being
formed on the inner lining of the coronary arteries that feed
the surface of the heart à contributes to significant narrowing
of the artery’s lumen
Plaques are vulnerable to rupture that results in the formation of a
platelet- and fibrin-rich thrombus leading to myocardial infarction
and ischemic stroke
Considered a chronic inflammatory disease as a result of
damages in the endothelium of blood vessels
Atherosclerosis

Many therapies are now oriented towards (1) inhibition of
thrombosis, (2) fibrinolysis, (3) platelet aggregation, (4)
inflammation

Irreversible cardiac injury consistently occurs when the
occlusion is complete for at least 15-20 minutes
Most of the damage occurs within the first 2 to 3 hours
Atherosclerosis

Restoration of coronary blood flow within the first 60 to 90
minutes results in the maximal salvage of tissue, but
treatment even up to 4 to 6 hours is associated with
increased survival.

Treatment:
Patients with STEMI: thrombolysis (clot dissolving agents),
percutaneous coronary intervention (PCI)
Patients with NSTEMI: combination of: coronary revascularization
(PCI or other), + anticoagulant, antiplatelet, anti-inflammatory
agents
Atherosclerosis

Precipitating Factors – elements that contribute to the
occurrence of the disorder
At the onset of AMI, the following precipitating factors have
been observed for patient activities:
Heavy exertion 13%
Modest or usual exertion 18%
Surgical procedure 6%
Rest 51%
Sleep 8%
Role of Clinical History in Diagnosis of ACS
Prodromal history of angina – abdomen à misdiagnosis of
indigestion
40-50% of patients with AMI
Severe pain but rarely Discomfort radiates to the
intolerable pain of an ACS shoulder, upper extremities,
Described as: constricting, neck, jaw (left side)
crushing, oppressing,
compressing With previous angina: more
Something sitting on or severe, longer, not relieved
squeezing sensation on the by rest
chest
Felt behind the sternum, Older individuals, diabetics
spreading frequently to both and women: w/o pain /
sides of the chest (left side); nonspecific symptoms
often radiates down left arm
May begin in the upper
Role of Cardiac Biomarkers
Cardiac biomarker
biochemical compound whose measurement is useful in
detecting cardiac disease, such as AMI or myocardial injury
Usefulness in detecting AMI, Usefulness in detecting
the biomarker: myocardial injury:
Must be released rapidly Persist in the circulation for
from the heart à circulation several days à more time
Provide sensitive and specific window for patients to be
diagnostic information diagnosed
Analytical assays: rapid, can
measure low concentrations
in blood
Diagnosis of AMI

In 1950s: Use of cardiac In 1986: WHO produced a
biomarkers used for criteria for AMI diagnosis
diagnosis of AMI started Two of the following
Aspartate aminotransferase must be met:
(AST) History of chest pain
Lactate dehydrogenase
Changes in ECG
(LD)
Elevation of serial
Total creatine kinase (CK)
α-hydroxybutyrate
cardiac biomarkers
(x2 than normal)
Cardiac injury
occurs in many
disease
processes,
beyond MI
2. Congestive Heart Failure (CHF)
Condition in which the heart
has lost its ability to pump Findings depend on many
enough blood to the body’s factors such as
tissues Clinical characteristics of
the patient
Encompasses a wide spectrum Extent and rate at which
of clinical conditions: the heart’s performance
A primary impairment in pump becomes abnormal
function (after a large AMI) Cause of the heart disease
Increased cardiac stiffness Concomitant co-
Unable to sustain life without morbidities
external support Part of the heart that is
New York Heart Association affected by abnormal
(NYHA) classification à often functioning
used to functionally stage CHF
patients
2. Congestive Heart Failure (CHF)
Severity of impairment ranges from mild (manifested
clinically only during stress) – to advanced (cardiac pump
function is unable to sustain life w/o external support)

Signs and symptoms are not specific à an objective
test for heart failure would be extremely useful

Ideally, the biomarker would increase progressively with
increasing severity of disease and not be
increased/decreased in conditions that mimic CHF; its
assay must be rapid.
 2. Congestive Heart Failure (CHF)
New York Heart Association Functional Classification Used
to Classify the Extent of Heart Failure*
NYHA Class Symptoms
I Cardiac disease, but no symptoms and no limitation in ordinary
physical activity (e.g., shortness o breath when walking,
climbing stairs, etc.)
II Mild symptoms (mild shortness o breath and/or angina) and
slight limitation during ordinary activity
III Marked limitation in activity due to symptoms, even during less-
than-ordinary activity (e.g., walking short distances [20-
100m]). Comfortable only at rest.
IV Severe limitations; experiences symptoms even while at rest
(mostly bedbound patients)
*as of April 2013
Recommended
specific laboratory
and clinical tests
for patients with
suspected heart
failure

cTnI or cTnT
determination is
recommended if the
clinical presentation is
suggestive of ACS

- ACC/AHA/Heart Failure
Society of America and
the European Society of
Cardiology
Cardiac Markers

Principle behind serum Detection of cardiac
biomarkers of cardiac proteins in plasma provides
damage: insight into the:
Cell death releases Occurrence
intracellular proteins Extent
from myocardium à
circulation Timing of MI

^All critical for proper
medical management
 upcph

Markers for ACS
Cardiac Markers

Initial markers Current markers Other markers

SGOT Troponin I Myoglobin
LD Troponin T Heart-type
CK-MB Fatty Acid-
Binding Protein
Ischemia-
Modified
Albumin
Cardiac Markers

First cardiac markers (used in clinical practice):
Glutamic oxaloacetic transaminase (GOT)
Lactate dehydrogenase
Creatine Kinase
 Initial Cardiac Markers

AKA aspartate transaminase (AST)
First cardiac markers: Became widely used in the diagnosis of MI
Glutamic shortly after its discovery
oxaloacetic
transaminase Cons: ↑ FN rate, labor-intensive nature of its
Lactate assay, short window of AST elevation
dehydrogenase AST was replaced by lactate dehydrogenase as the
Creatine Kinase marker of choice
 Initial Cardiac Markers

More sensitive marker of MI (vs AST)
Remains elevated for significantly longer after MI (up to two
First cardiac markers: weeks)
Glutamic Cons: ↓ specificity to cardiac muscle
oxaloacetic LD is involved in glycolytic pathway à takes place in nearly all cells
transaminase in the body
Lactate Also ↑ in other conditions (e.g. cancer, anemia)
dehydrogenase 5 LD isomers:
Creatine Kinase LD1 – myocardium
LD5 - skeletal muscle and liver
To differentiate: LD1:LD2 ratio à 0.75 after 24-48 hours the
onset of symptoms of MI and remains elevated up to 2
weeks à MI related elevation
Typically, this ratio is lesser among those without MI
 Initial Cardiac Markers

Like LD, CK is found in nearly all cells in the body
However, CK catalyzes the conversion of creatine to
First cardiac markers: creatine phosphate à greatly upregulated in the muscle
Glutamic cells and brain
oxaloacetic
transaminase Damage in these tissues (brain and muscle) à rapid ↑ in
plasma CK
Lactate
dehydrogenase In AMI, serum CK levels were found to exceed normal
range within 6-8 hours, reaches a peak of 2-10x by 24
Creatine Kinase
hours, then declines to normal range after 3-4 days
Primary means of enzymatic detection of AMI for years:
[plasma CK] > 2x normal à correlate with MI;
together with elevated AST and LDH
 Initial Cardiac Markers

High levels are found in striated muscles
↓ specificity of CK for MI marker, in spite of its high
First cardiac markers:
sensitivity
Glutamic ↑ levels: stroke, pulmonary disease, chronic alcoholism,
oxaloacetic
transaminase after strenuous exercise
Lactate 3 cytoplasmic isoenzymes of CK
dehydrogenase Dimers: combination of subunits (M: muscle, B: brain)
Creatine Kinase CK-MM – ↑ in muscle injury
CK-BB – ↑ in brain injury
CK-MB – ↑ in myocardial damage
15-30% is found in the heart
 Initial Cardiac Markers

Serum CK-MB
First cardiac markers:
increases at 4-6 hours after the onset of MI
Glutamic
oxaloacetic symptoms and quickly drop to normal levels
transaminase after 2-4 days
Lactate
dehydrogenase Considered most reliable serum maker of MI
Creatine Kinase and is still widely used today
Due to its higher specificity, and rapid elevation
after MI symptom
Initial Cardiac Markers

These 3 cardiac markers was the cornerstone of post-MI
management for several decades:
AST – for intermediate presentation
LD – for late presentation
CK – for early presentation

However, since they are not specific to myocardium and to
myocardial injury à extensive research lead to the discovery of
more tissue-specific cardiac biomarker
Troponins (Tn)
Complex of three proteins (regulatory proteins) that bind
to the thin filaments of cardiac muscles
Regulators of actin and myosin
TnT and TnI are nearly absent from normal serum – many
healthy individuals have undetectable levels à cardiac
muscle-specific isoform
TnC = present in both cardiac and skeletal muscles
binds calcium ions that regulate muscle contractions
Reference value: < 0.1 ng/mL (< 0.1 µg/L)
Troponins (Tn)
Diagnostic Significance:
Most important marker for cardiac injury (AMI)
Since they are derived from myocardium
Levels in the blood may elevate after AMI attack in the
absence of CK-MB elevations

Cardiac Troponins:
a. Troponin T (TnT)
b. Troponin I (TnI)
Structure of Troponins

Figure 34-4 Structure of cardiac troponin (cTn) complex and troponin forms released
following myofibril necrosis. (From Gaze DC, Collinson PO. Multiple molecular forms of
circulating cardiac troponin: analytical and clinical significance. Ann Clin Biochem
2008;45:349-59. Figure courtesy of Paul Collinson.)
Troponin T (TnT)
Tropomyosin-binding subunit
Valuable tool in the diagnosis of AMI
Useful for assessment of early and late AMI; elevated also in renal
diseases and muscular dystrophy
Sensitive marker for the diagnosis of unstable angina (angina at rest)
Useful in monitoring the effectiveness of thrombolytic therapy in
AMI patients
In AMI, it rises within 3-4 hours after onset of myocardial damage,
peak level is at 10-24 hours, return to normal in 7 days (but may
remain elevated for 10-14 days
Serum levels > 1.5 ng/mL à considered to be suggestive of AMI
Troponin I (TnI)
Inhibitory subunit or actin-binding unit
Highly specific for AMI à not elevated in renal failure
patients and no detectable amount in the skeletal muscles
Gold standard test for AMI
13x more abundant in the myocardium than CK-MB on
weight basis
Very sensitive indicator of even minor amount of cardiac
necrosis
In AMI, levels begin to rise 3-6 hours, peak in 12-18 hours,
return to normal in 5-10 days
Troponins
Methods:
measured in serum by
immunoassay
Reference values of TnT
and TnI as cardiac markers
depend on the antibodies
and calibrators used in the
immunoassay
 Other Markers of Cardiac Damage

Small heme protein found in skeletal and cardiac
muscle
Myoglobin Transports and stores oxygen from hemoglobin to
Heart-type fatty intracellular respiratory enzymes of contractile cells
acid-binding
protein (H-FABP)
Has higher affinity of oxygen than oxygen has
Ischemia-modified Approx. 2% of the total muscle protein
albumin (IMA) Having a molecular weight of only 18 kDA,
myoglobin apparently leaks from damage cells
rapidly than other proteins
Potential nephrotoxin à has to be excreted when
plasma concentration exceeds reference ranges
 Other Markers of Cardiac Damage

Diagnostic Significance:
One of the protein markers to diffuse out of
Myoglobin ischemic myocardium
Heart-type fatty Marker for chest pain (angina) and early detection
acid-binding of AMI
protein (H-FABP) In AMI (screening test), the onset is 1-3 hours, peak
Ischemia-modified level 5-12 hours, normalize in 18-30 hours
albumin (IMA) Useful marker for monitoring the success or failure
of reperfusion
↑: AMI, angina, rhabdomyolysis, muscle trauma,
extrenuous exercise, IM injection, acute renal
failure
 Other Markers of Cardiac Damage

Methods:
Measured in serum by immunoassay
Myoglobin
Heart-type fatty At high levels in urine, it produces a positive
acid-binding dipstick reaction for occult blood due to
protein (H-FABP)
pseudoperoxidase activity
Ischemia-modified
albumin (IMA) AMI value: >100 µg/L
 Other Markers of Cardiac Damage

Small protein, which behaves much like
myoglobin (kinetics and release)
Myoglobin Found in all muscles, but more abundant in
Heart-type fatty heart (vs myoglobin)
acid-binding
protein (H-FABP) Sensitivity: H-FABP> cTnT or myoglobin
Ischemia-modified Specificity: cTnT > H-FABP
albumin (IMA)
H-FABP and cTnI: can be used for early
diagnosis of MI/ACS
Using both: rule out patients bet 3 and 6 hours after
chest pain
 Other Markers of Cardiac Damage

Measures changes that occur in albumin in the presence
of ischemia à can detect ischemia before damage has
occurred to the heart
Myoglobin Free radical formation occurs during tissue ischemia is believed
Heart-type fatty to modify albumin within minutes of ischemia and lasts for about
acid-binding 6 hours
protein (H-FABP) These modification alter its ability to bind to transition metal by
its N-terminal domain
Ischemia-modified
albumin (IMA) Method: Spectrophotometric determination of albumin’s
binding to cobalt
IMA is not specific for cardiac damage but it has a clinical
sensitivity for ACS of 50-90%
Its use will complement troponin and CK-MB detection
 upcph

Marker for CHF: BNP
 https://www.researchgate.net/publication/332797145/figure/fig1/AS:779410676412426@15
62837394720/Pathways-of-NT-proBNP-and-BNP-synthesis-from-proBNP-The-proBNP-
was-cleaved-by-CORIN.png

B-type natriuretic peptide (BNP)
A hormone that is mainly released from the
myocardial ventricles à in response to
increased pressure and volume load
proBNP à cleaved by protease
N-terminal pro-B-type natriuretic peptide (NT-proBNP)
B-type natriuretic peptide (BNP) : active

Method:
Measured by immunoassay
Specimen:
For BNP: EDTA whole blood/plasma using plastic
blood collection tube
For NT-proBNP: serum, heparin plasma, EDTA
plasma
Reference values: laboratory must determine
their own; depends on age, sex
BNP: 100 pg/mL (aged