Polymerase chain reaction (PCR) is a laboratory technique used to make many copies of a specific DNA segment. PCR relies on thermal cycling, heating and cooling the DNA sample to trigger a series of reactions that replicate the target DNA sequence exponentially.
PCR requires DNA template, primers, DNA polymerase enzyme, and nucleotides. Primers flank the target region on DNA to be amplified. In a thermal cycler, the sample undergoes cycles of denaturation (separating DNA strands), annealing (primers bind to flanking regions), and extension (DNA polymerase synthesizes new strand).
After 30-40 cycles, sufficient copies of the target DNA segment have been produced to allow detection and analysis. PCR’s sensitivity allows identifying trace amounts of DNA and has made PCR a foundational tool of molecular biology research and clinical diagnostics.
PCR applications include cloning and sequencing DNA, analyzing forensic samples, detecting viruses or bacteria, DNA fingerprinting, and studying genetic diseases. Quantitative PCR allows quantifying DNA. Reverse transcription PCR (RT-PCR) first transcribes RNA into cDNA for amplification. Real-time PCR monitors amplification as it occurs. Variations alter PCR conditions for specialty applications.
Since its invention in the 1980s, PCR has revolutionized life sciences and biomedical research. Automated thermal cyclers and optimized reagents have made PCR a standard, inexpensive, and readily accessible molecular technique available in all laboratories.
2. Introduction
• Polymerase chain reaction (PCR) is important in
diagnosing tuberculosis (TB) due to its sensitivity, speed, and
specificity.
• It can detect low levels of TB DNA, provides rapid results,
and accurately identifies the TB bacteria, reducing the risk of
false positives.
• PCR can also detect drug-resistant strains, diagnose
extrapulmonary TB, and monitor treatment response,
especially useful for HIV-positive patients.
• The most common target genes for Mycobacterium
tuberculosis PCR tests are IS6110 and rpoB. These genes
are specific to M. tuberculosis and are used for DNA
amplification.
3. PCR Fundamentals
• Polymerase Chain Reaction (PCR): A molecular
technique amplifying specific DNA sequences, enabling
the detection of even trace amounts of MTB DNA.
• Primers: Short DNA segments designed to bind
specifically to MTB DNA sequences for amplification.
• DNA Polymerase: Enzyme responsible for DNA
replication in PCR.
• Denaturation: The step in PCR where DNA strands are
separated by heating.
• Annealing: Cooling step where primers bind to the
target DNA.
• Extension: DNA polymerase adds nucleotides to form
new DNA strands.
4. Advantages of PCR-Based Methods
• Speed and Accuracy: PCR-based methods for MTB detection are
known for their speed and accuracy in identifying the bacterium.
• Sensitivity: PCR can detect MTB DNA at extremely low
concentrations, vital for early diagnosis.
• Minimal Handling of Infectious Material: PCR minimizes the need
for extensive handling of potentially infectious MTB samples,
enhancing laboratory safety.
• Reduction of False Positives: Reduced risk of contamination leads to
fewer false-positive results, aiding clinical decision-making.
• Variants of PCR: Different PCR methods, such as nested PCR and
real-time PCR, offer varying degrees of sensitivity and specificity for
MTB detection.
5. Challenges in TB Diagnosis
• Traditional Methods: Microscopy and culture-based
techniques are often slow, less sensitive, and prone to
contamination.
• Rapid Detection Need: Rapid, accurate diagnosis is
essential to prevent transmission and initiate timely
treatment.
• Sputum Sample Quality: The quality of sputum
samples can significantly affect the accuracy of
detection.
• Risk of Drug Resistance: Delayed diagnosis
contributes to drug-resistant TB strains, posing a
significant global health threat.
6. Types of Sample Collection
• Various types of samples used for TB PCR, such as sputum,
blood, urine, cerebrospinal fluid, and tissue samples.
• Sputum is the most common and widely used sample for TB
diagnosis.
• Blood samples can be used for extrapulmonary TB
diagnosis, particularly when pulmonary samples are not
available.
• Cerebrospinal fluid samples are crucial for diagnosing TB
meningitis.
7. PCR Variants
1. LAMP: Loop-Mediated Isothermal Amplification, which is a single-
tube technique for the amplification of DNA, a low-cost alternative and
faster method.
2. Nested PCR: Uses two sets of primers for increased specificity.
3. Multiplex PCR: Amplifies multiple targets in one reaction, saving
time.
4. Real-time PCR (qPCR): Allows real-time monitoring of DNA
amplification.
5. Digital PCR: Offers precise DNA quantification using partitions.
8. Biochips in MTB detection
• Biochips : Biochips are microarray-
based diagnostic tools that can
simultaneously screen for multiple
MTB genetic markers.
• High Throughput: Biochips offer
high-throughput detection, allowing
the analysis of numerous genetic
markers in a single reaction.
• Multiplex PCR: PCR combined with
biochips enables the simultaneous
amplification and detection of multiple
MTB genes.
9. Line Probe Assay (LPA)
• LPA for MTB Detection: The Line Probe Assay
(LPA) is a molecular diagnostic technique
designed for rapid detection of MTB and its
resistance to specific anti-TB drugs.
• Target Genes: LPA targets specific MTB genes
associated with drug resistance. Specifically for
the mutations in rpoβ, and both inhA and katG
genes.
• Strip Hybridization: LPA uses strip
hybridization to detect amplified DNA and
determine drug susceptibility.
• Rifampicin and Isoniazid Resistance: LPA is
particularly useful in identifying resistance to
10. Hybridization Technique
• Hybridization in MTB Detection: Hybridization is a
process used to identify MTB DNA by matching it
with specific complementary probes.
• Probes for MTB Genes: Specific DNA probes are
designed to hybridize with MTB genes, allowing for
their detection.
• Stringent Washes: Stringent washing steps ensure
that only complementary MTB DNA remains bound to
the probes.
• Detection of Drug Resistance: Hybridization
techniques can also be adapted to detect drug
11. Interpretation of PCR Result
Positive
• Detection of Mycobacterium
tuberculosis DNA in the
sample.
• Indicates the presence of TB
infection in the patient.
• Further tests may be needed
to determine the stage and
severity of the infection.
Negative
• No Mycobacterium
tuberculosis DNA detected in
the sample.
• Doesn't necessarily rule out
TB infection.
• Low bacterial load in the
sample.
12. Hain Strips
• Role of Hain Strips: Hain Strips are a crucial component of
hybridization-based MTB detection.
• Specific Probes: Hain Strips contain immobilized probes that
match with MTB DNA sequences.
• Drug Resistance Detection: Hain Strips can also detect
mutations associated with drug resistance
• Advantages: High specificity, ease of use, and rapid results are
key features
13. Device Makers: Hain Lifescience
• Hain Lifescience's Role: Hain Lifescience is a
prominent provider of molecular diagnostic tools for
TB detection.
• Development of LPAs: Hain Lifescience played a
significant role in the development and
commercialization of Line Probe Assays (LPAs) for
MTB detection.
• Global Impact: Hain LPAs have been widely
adopted globally for their accuracy in detecting MTB
14. Truelab Micro-PCR Machines
• Truelab Micro-PCR Machines: Truelab DuoDx
and QuattroDx are micro-PCR machines designed
for MTB detection.
• Portability: These machines are compact and
portable, making them suitable for use in
resource-limited settings.
• Real-Time PCR: Truelab Micro-PCR Machines
often utilize real-time PCR for continuous
monitoring of DNA amplification.
• GeneXpert Compatibility: Some models are
compatible with GeneXpert cartridges, providing
integrated testing for MTB and resistance.
15. Challenges and Limitations
• Cost of Equipment: High initial costs associated with PCR
machines can be a barrier to their widespread use, particularly in
resource-limited settings.
• Skilled Personnel: Skilled laboratory personnel are required for
the operation and maintenance of PCR instruments.
• Infrastructure Requirements: Adequate laboratory
infrastructure, including temperature-controlled environments, is
essential for PCR.
• Sample Quality: The quality of sputum samples can significantly
affect the accuracy of PCR-based MTB detection.
16. Importance of Early Detection
• Early Detection Significance: Early detection through
PCR significantly reduces the risk of TB transmission to
others and minimizes disease complications.
• Contact Tracing: PCR results enable prompt contact
tracing to identify and test individuals exposed to TB, further
containing the spread.
• Public Health Impact: Timely diagnosis plays a pivotal role
in achieving TB control targets set by public health
organizations worldwide.