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PCR Detection of Mycobacterium tuberculosis
- 1. Polymerase Chain Reaction (PCR) for Mycobacterium tuberculosis BY- WAKIB AMIN MAZUMDER GROUP-18
- 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.