Tuberculosis (TB) remains a formidable global health challenge, persisting as one of the top infectious disease killers worldwide. According to the World Health Organization (WHO), an estimated 10 million people fell ill with TB in 2022, with 1.3 million dying of the disease [1].
While efforts to combat TB have made significant strides, the emergence of antimicrobial resistance to first- and second-line antibiotics poses a new frontier in the battle against these bacterial infections. Moreover, close cousins of the TB-causing bacteria, known as nontuberculous mycobacteria (NTM) wreak further havoc in diagnosis and therapy management as they lead to infections with overlapping clinical symptoms and diagnostic readouts [2].
How to diagnose mycobacteria? What solutions are best for mycobacteria detection?
In the ever-evolving field of mycobacteria detection, laboratories and clinicians are embracing innovative techniques to enhance precision and efficiency. This overview delves into cutting-edge methods tailored for the detection of NTM and the TB-causing M. tuberculosis complex (MTBC).
Decisions are never unilateral, but rather a culmination of multiple indicators carefully gathered and analyzed. Physicians collect information from various sources, considering factors such as the patient's travel history to high-risk regions, clinical symptoms, radiographic/imaging findings (X-Ray or CT), and laboratory results. These insights, coupled with the expertise of mycobacteria laboratories capable of diagnosing TB, NTM, and drug resistances, form the backbone of effective TB management strategies [3].
References
[1] WHO Tuberculosis Fact Sheet, Tuberculosis (who.int)
[2] WHO Tackling the drug-resistant TB crisis (who.int)
[3] WHO Diagnostic testing for TB, HIV and drug-resistant TB (who.int)
Microscopy serves as a cornerstone in the diagnostic arsenal against tuberculosis (TB), offering a rapid and cost-efficient procedure. Techniques such as direct microscopy with Ziehl-Neelsen stain and fluorescent microscopy with auramine illuminate acid-fast bacilli in stained and acid-washed smears, enabling quick detection of mycobacteria. Despite its speed, microscopy exhibits limitations in sensitivity, often failing to detect TB in samples with low bacterial loads. Moreover, microscopy lacks the capacity to differentiate between TB and NTM, leaving clinicians without crucial species-specific information and insight into drug resistance profiles.
Culture remains the gold standard in TB diagnosis, requiring decontaminated samples for accurate results. In Germany, a rigorous approach entails three cultures per sample, including one liquid and two solid cultures. However, the slow growth rate of mycobacteria (M. tuberculosis doubling time 16-20 h compared to Escherichia coli 20 min) extends the time to result significantly, taking 2-3 weeks (liquid medium) for MTBC detection and up to 8 weeks for complete drug resistance profiling, underscoring the need for expedited diagnostic methods.
PCR (Polymerase Chain Reaction) emerges as a pivotal tool in TB diagnostics, offering unparalleled sensitivity and rapid detection of MTBC and drug resistances. In fact, WHO endorses these tests for initial TB diagnosis, emphasizing their role in facilitating prompt treatment decisions and reducing transmission. By detecting known resistance-associated mutations, PCR provides clinicians with crucial information for tailored treatment plans, although culture confirmation remains imperative due to genotypic-phenotypic discrepancies. Further ability of PCR to detect and differentiate between different species of NTM make molecular diagnostics indispensable among many mycobacteria labs. The benefits of PCR extend beyond mere sensitivity, encompassing minimal sample handling, multiplexing capabilities for comprehensive resistance profiling, and rapid result turnaround, ultimately enhancing patient outcomes and public health interventions.
[WHO] guidelines are accompanied by an operational handbook to facilitate rapid implementation and roll out of rapid molecular tests.
In addition to PCR, alternative diagnostic methods such as sequencing and Matrix-Assisted Laser Desorption/Ionization Time-of-Flight (MALDI-TOF) mass spectrometry offer distinct advantages in mycobacteria diagnostics. While sequencing provides detailed genetic insights into MTBC species and additional drug resistances, MALDI-TOF mass spectrometry enables rapid differentiation between MTBC and NTM and identifies specific NTM species, complementing PCR where necessary.
Laboratories and clinicians navigate a diverse array of techniques to unveil the elusive TB pathogen. From microscopy to the precision of molecular assays, each method plays a crucial role in unraveling TB's mysteries. With innovative approaches like MALDI-TOF mass spectrometry emerging, the diagnostic journey continues, promising advancements in early detection and targeted management strategies.