Multidrug-resistant tuberculosis
Multidrug-resistant tuberculosis (MDR-TB) is a form of tuberculosis disease caused by strains of Mycobacterium tuberculosis that are resistant to at least isoniazid and rifampicin, the two most potent first-line anti-tuberculosis drugs.[1][2] This resistance complicates diagnosis and treatment, leading to higher rates of treatment failure, relapse, and death compared to drug-susceptible TB.[3] MDR-TB contributes substantially to the global burden of antimicrobial resistance, with an estimated 150,000 deaths attributable to multidrug- or rifampicin-resistant TB (MDR/RR-TB) in 2023 alone.[4] Despite international efforts, treatment success rates for MDR/RR-TB remain low at approximately 63% globally, reflecting persistent challenges in detection, access to effective regimens, and patient adherence.[5] The incidence of MDR-TB has shown limited decline in many regions, particularly in low-resource settings where weak healthcare infrastructure exacerbates transmission and acquired resistance.[6] The emergence of MDR-TB primarily results from selective pressure exerted by incomplete or improper treatment of drug-susceptible TB, allowing resistant mutants to proliferate, alongside person-to-person transmission of pre-existing resistant strains.[3] Factors such as inadequate drug supply, poor case management, and high population density in underserved areas amplify these risks, underscoring the causal role of systemic failures in healthcare delivery over isolated patient behaviors.[7] Unlike drug-susceptible TB, MDR-TB requires extended regimens often lasting 18–24 months, involving second-line drugs with greater toxicity, higher costs, and increased likelihood of adverse events, which further strain public health resources.[5] Recent advances include shorter all-oral regimens like the 6-month BPaLM combination (bedaquiline, pretomanid, linezolid, moxifloxacin), which have demonstrated improved tolerability and efficacy in treating MDR-TB and even extensively drug-resistant forms, though scalability remains limited by drug availability and monitoring needs.[8] These developments highlight ongoing causal interventions targeting bacterial persistence and resistance mechanisms, yet MDR-TB persists as a formidable barrier to tuberculosis elimination, demanding enhanced surveillance, rapid diagnostics, and robust prevention strategies to curb its spread.[9]Definition and Classification
Criteria for MDR-TB
Multidrug-resistant tuberculosis (MDR-TB) is defined as tuberculosis caused by Mycobacterium tuberculosis strains resistant to at least isoniazid and rifampicin, the two cornerstone first-line anti-TB drugs, as established by the World Health Organization (WHO).[1] This resistance must be confirmed through drug susceptibility testing (DST) on clinical isolates, distinguishing MDR-TB from drug-susceptible forms.[10] The Centers for Disease Control and Prevention (CDC) aligns with this, emphasizing that drug resistance, including MDR, requires laboratory verification rather than clinical suspicion alone.[11] Diagnosis relies on phenotypic DST, which measures bacterial growth inhibition in the presence of drugs using media like Löwenstein-Jensen or automated systems such as Mycobacteria Growth Indicator Tube (MGIT), typically requiring 2–8 weeks for results.[12] Genotypic methods, including nucleic acid amplification tests (e.g., Xpert MTB/RIF assay detecting rifampicin resistance mutations in the rpoB gene) and line probe assays for both isoniazid (katG, inhA genes) and rifampicin, enable faster detection within hours to days.[13] WHO recommends initial rapid molecular testing for all TB suspects in high-burden settings, followed by culture-based confirmation for comprehensive susceptibility profiles.[12] Resistance to both drugs must be demonstrated; isolated rifampicin resistance qualifies as rifampicin-resistant TB (RR-TB), a proxy often overlapping with MDR-TB but not identical.[10] Criteria exclude empirical classification without DST, as false positives from prior exposure or non-compliance can mislead; confirmed MDR-TB prompts second-line regimen initiation.[14] In resource-limited areas, WHO-endorsed shorter regimens (9–12 months) apply only to bacteriologically confirmed MDR/RR-TB cases meeting specific susceptibility criteria to fluoroquinolones and second-line injectables.[15] Global surveillance data from 2022 indicate that among 410,000 estimated MDR/RR-TB cases, DST coverage reached 83% in high-burden countries, underscoring lab confirmation's role in accurate epidemiology.[1]Distinction from Drug-Susceptible and Other Resistant Forms
Multidrug-resistant tuberculosis (MDR-TB) is defined as tuberculosis caused by Mycobacterium tuberculosis strains resistant to at least isoniazid and rifampicin, the two most potent first-line anti-TB drugs, whereas drug-susceptible TB (DS-TB) involves strains fully responsive to these agents along with pyrazinamide and ethambutol in standard short-course regimens.[1][11] This core resistance profile necessitates distinct diagnostic confirmation via phenotypic or molecular drug susceptibility testing (DST), as DS-TB diagnosis relies primarily on smear, culture, or nucleic acid amplification tests without routine DST for first-line drugs unless risk factors suggest otherwise.[1][16] Clinically, DS-TB treatment typically spans 6 months with high cure rates exceeding 85% under directly observed therapy, short-course (DOTS) protocols, achieving bacteriological conversion in 80-90% of cases within 2 months.[3] In contrast, MDR-TB regimens last 9-24 months, incorporating second- and third-line drugs like fluoroquinolones, injectables (e.g., amikacin), and newer agents such as bedaquiline or pretomanid, with global treatment success rates around 61% as of 2020, hampered by toxicity, adherence challenges, and additional resistances.[1][3] Untreated, DS-TB mortality approaches 50% within 5 years, while MDR-TB exceeds 80% due to prolonged infectivity and limited therapeutic options.[16] MDR-TB differs from rifampicin-resistant TB (RR-TB), which involves resistance solely to rifampicin (with isoniazid susceptibility preserved in some cases), allowing potential use of isoniazid-inclusive shorter regimens (e.g., 6-9 months with high-dose isoniazid) rather than full MDR protocols assuming dual resistance.[17][18] Poly- or mono-drug resistances (e.g., isoniazid-only) permit adjusted first-line therapy with success rates closer to DS-TB (70-90%), unlike MDR-TB's reliance on individualized DST-guided combinations.[3] Extensively drug-resistant TB (XDR-TB), a MDR-TB subset resistant to at least one fluoroquinolone and one injectable second-line drug (e.g., capreomycin), yields even poorer outcomes, with historical success below 40% but recent all-oral regimens improving to ~90% in trials like Nix-TB.[19][9] These distinctions underscore MDR-TB's intermediate severity between DS-TB's manageability and XDR-TB's refractoriness, driving tailored surveillance and response strategies.[11]Mechanisms of Resistance
Evolutionary and Genetic Origins
Multidrug-resistant Mycobacterium tuberculosis evolves through spontaneous chromosomal mutations selected by subtherapeutic drug exposure during treatment, conferring resistance to both isoniazid and rifampicin. Rifampicin resistance primarily stems from point mutations in the rpoB gene, which encodes the β-subunit of RNA polymerase; the S450L mutation predominates, occurring in 70–82% of resistant isolates globally. Isoniazid resistance arises mainly from katG Ser315Thr substitutions, disrupting catalase-peroxidase activity essential for drug activation, or from mutations in the inhA promoter region that upregulate an efflux pump and alter mycolic acid synthesis; these account for over 90% of cases. Such mutations arise at mutation rates of approximately 10^{-8} to 10^{-10} per nucleotide per generation, but selective pressure from incomplete therapy amplifies their prevalence.[20][21] The stepwise acquisition of these mutations defines the evolutionary trajectory to MDR-TB, with isoniazid resistance often preceding rifampicin resistance, though reverse orders occur. Initial resistance-conferring mutations impose fitness penalties, including slower replication rates (up to 20–50% reduction in vitro) and diminished virulence in animal models, due to impaired core functions like transcription fidelity (rpoB) or oxidative stress response (katG). Compensatory mutations mitigate these costs without sacrificing resistance; for rpoB variants, alterations in rpoA or rpoC (e.g., L431P in rpoC) restore RNA polymerase stability and promoter interaction, observed in 20–30% of rifampicin-resistant strains. Epistatic interactions between mutations further modulate fitness, with certain combinations enhancing overall adaptability under dual-drug selection.[22][20] Phylogenetically, MDR-TB disproportionately emerges within specific M. tuberculosis lineages, particularly lineage 2 (Beijing sublineage) and LAM variants, which harbor higher baseline mutation rates and hypermutable genotypes predisposing to resistance. Whole-genome sequencing reveals that while single resistance alleles are ancient (predating modern chemotherapy), MDR-defining combinations have arisen independently multiple times since the mid-20th century, often in urban hotspots with dense transmission networks. In Portugal, for example, Lisboa3-A and Q1 clades, originating in Lisbon around the 1940s–1960s, independently evolved MDR profiles by the 1970s via rpoB S450L and inhA promoter shifts, spreading nationally through human mobility. Transmission of fitter MDR strains now sustains most epidemics, outpacing de novo evolution in untreated hosts.[22][21]Molecular Pathways for Key Drug Resistances
Resistance to rifampicin in Mycobacterium tuberculosis primarily arises from point mutations in the rpoB gene, which encodes the β-subunit of RNA polymerase, the enzyme's target that rifampicin inhibits by binding to its DNA-RNA interface and blocking elongation of nascent RNA chains beyond 2-3 nucleotides. Over 95% of rifampicin-resistant isolates harbor mutations within the 81-base pair rifampicin resistance-determining region (RRDR, codons 507-533) of rpoB, with the Ser531Leu (S531L) substitution being the most common, detected in 50-70% of cases worldwide and conferring high-level resistance (MIC >32 μg/mL) by sterically hindering drug binding without severely impairing polymerase function. Other frequent RRDR mutations include Asp516Val/Tyr, His526Tyr/Asp, and His526Asn, each altering critical residues in the rifampicin-binding pocket and variably impacting fitness costs, such as reduced growth rates in some strains.[23][24][25] Isoniazid, a prodrug activated by the KatG catalase-peroxidase enzyme to form an electrophilic adduct that covalently binds InhA (enoyl-ACP reductase) and disrupts mycolic acid synthesis in the cell wall, exhibits resistance via distinct molecular routes reflecting its multi-step activation and targeting. High-level resistance (MIC >5 μg/mL), seen in 40-60% of isoniazid-resistant isolates, stems from katG mutations, predominantly Ser315Thr (S315T), which substitutes a key residue in the heme-binding site, reducing KatG's peroxidative activity by up to 50% and preventing efficient prodrug oxidation without abolishing catalase function entirely. Low- to moderate-level resistance (MIC 0.2-5 μg/mL), comprising 15-30% of cases, results from promoter mutations in the inhA operon (e.g., -15C>T or -8T>C), upregulating InhA expression 2- to 20-fold and overwhelming the limited activated isoniazid through target overproduction; these often co-occur with fabG1 variants for compounded effect. Less common mechanisms include ahpC promoter mutations enhancing alkyl hydroperoxidase activity as a compensatory peroxidase, though these confer only marginal resistance alone.[26][27][28] In multidrug-resistant TB, co-occurrence of rpoB and katG/inhA mutations drives combined resistance, with katG S315T frequently paired with rpoB S531L, amplifying selective pressure during monotherapy lapses; compensatory mutations in rpoA or rpoC can mitigate rpoB-associated fitness deficits by restoring RNA polymerase assembly and processivity. Efflux pumps like Rv1258c contribute minimally to intrinsic resistance but may amplify mutational effects under subtherapeutic drug levels. These pathways underscore M. tuberculosis' reliance on chromosomal mutations over plasmid-mediated or horizontal transfer mechanisms, with mutation frequencies around 10^{-8} to 10^{-10} per cell per generation enabling rapid evolution in high-burden settings.[29][30]| Drug | Gene/Region | Common Mutation(s) | Molecular Effect |
|---|---|---|---|
| Rifampicin | rpoB (RRDR) | S531L, D516V, H526Y | Reduces drug affinity to RNA polymerase β-subunit binding pocket; high-level resistance.[23] |
| Isoniazid | katG | S315T | Impairs KatG activation of prodrug; high-level resistance.[26] |
| Isoniazid | inhA promoter | -15C>T, -8T>C | Increases target enzyme overexpression; low- to moderate-level resistance.[27] |
Variants and Progression
Rifampicin-Resistant TB (RR-TB)
Rifampicin-resistant tuberculosis (RR-TB) refers to infection with Mycobacterium tuberculosis strains resistant to rifampicin, a first-line antibiotic essential for standard short-course therapy due to its bactericidal activity against actively replicating bacilli.[1] Unlike multidrug-resistant TB (MDR-TB), which requires concurrent resistance to both rifampicin and isoniazid, RR-TB encompasses isolates resistant solely to rifampicin (mono-resistance) or in combination with other drugs but not necessarily isoniazid; approximately 20-30% of RR-TB cases lack isoniazid resistance, distinguishing them from the subset classified as MDR-TB.[15] [31] This broader categorization facilitates rapid detection via molecular tests targeting rifampicin resistance, as mutations conferring it often predict broader resistance patterns.[32] Resistance primarily arises from point mutations in the rpoB gene encoding the β-subunit of RNA polymerase, with over 96% occurring in an 81-base-pair rifampicin resistance-determining region (RRDR); common variants include Ser531Leu and His526Tyr, which alter the drug-binding pocket and reduce affinity without fully impairing polymerase function.[33] These mutations emerge sporadically at rates of about 10^{-8} to 10^{-10} per bacterium during monotherapy or inadequate treatment, accelerating under selective pressure from inconsistent rifampicin exposure in high-burden settings.[34] RR-TB strains exhibit fitness costs, such as slower growth, but compensatory mutations in rpoA or rpoC can restore virulence, enabling sustained transmission.[35] Globally, an estimated 450,000 individuals developed RR-TB in 2021, with incidence stabilizing at around 400,000 annually through 2023 after a pre-2020 decline, representing about one-third of all TB cases in high-resistance regions like eastern Europe and central Asia.[36] [37] Rifampicin mono-resistance accounts for roughly 10-15% of RR-TB, often linked to prior treatment interruptions rather than primary transmission, though community spread is increasing in urban slums with poor adherence.[38] Detection relies on genotypic assays like Xpert MTB/RIF, which identify rpoB mutations with >95% sensitivity for RR-TB, enabling same-day diagnosis over culture-based phenotypic testing that delays results by weeks.[11] Treatment for RR-TB diverges from drug-susceptible TB by excluding rifampicin, typically involving high-dose isoniazid (if susceptible), ethambutol, pyrazinamide, and second-line agents like fluoroquinolones or injectables, with regimens extended to 9-12 months for mono-resistant cases versus 6-18 months for MDR-overlapping RR-TB.[8] WHO guidelines prioritize all-oral shorter regimens, such as 6-month BPaLM (bedaquiline, pretomanid, linezolid, moxifloxacin) for fluoroquinolone-susceptible MDR/RR-TB, achieving success rates of 68-85% but with risks of ototoxicity and neuropathy from linezolid.[39] [40] Untreated or mismanaged RR-TB progresses to chronic pulmonary disease with cavitation, higher mortality (up to 20% annually), and potential amplification to polyresistance via ongoing isoniazid pressure if susceptibility is unconfirmed.[41] Adherence challenges and drug interactions necessitate directly observed therapy and susceptibility-guided adjustments to avert further resistance evolution.[42]Extensively Drug-Resistant TB (XDR-TB)
Extensively drug-resistant tuberculosis (XDR-TB) denotes a subset of multidrug-resistant or rifampicin-resistant TB (MDR/RR-TB) characterized by additional resistance to critical second-line agents, complicating therapeutic options and elevating mortality risks. The World Health Organization (WHO) updated its definition in January 2021 to encompass Mycobacterium tuberculosis strains resistant to rifampicin (with or without isoniazid resistance), any fluoroquinolone (e.g., levofloxacin or moxifloxacin), and at least one Group A drug, which includes bedaquiline or linezolid.[43] This revision, informed by genomic surveillance and clinical data, replaced prior criteria reliant on injectable agents (e.g., amikacin, capreomycin) to better align with emerging resistance profiles and facilitate individualized regimens.[44] Prior to 2021, XDR-TB was defined as MDR-TB plus resistance to any fluoroquinolone and at least one of three second-line injectables, but shifts in drug utilization and cross-resistance necessitated the change.[45] XDR-TB typically emerges through sequential selection pressures on MDR strains during suboptimal treatment, driven by genetic mutations in targets like DNA gyrase (gyrA/gyrB for fluoroquinolones) and ATP synthase (atpE for bedaquiline), amplifying transmissibility in high-burden settings.[46] Molecular diagnostics, such as whole-genome sequencing, reveal that XDR strains often harbor compounded efflux pump overexpression and ribosomal mutations, reducing efficacy of remaining agents.[47] Unlike RR-TB or standard MDR-TB, XDR variants exhibit heightened virulence in some lineages (e.g., Beijing strains), correlating with clustered outbreaks in congregate environments.[48] Epidemiologically, XDR-TB constitutes 5–10% of global MDR-TB cases, with laboratory-confirmed pre-XDR or XDR instances exceeding 25,000 in 2020, predominantly in regions like Eastern Europe, southern Africa, and India where diagnostic capacity lags.[49][50] The 2024 WHO Global Tuberculosis Report underscores that while MDR/RR-TB incidence stabilized at approximately 410,000 cases annually, XDR subsets drive disproportionate deaths—up to 15–20% of total TB fatalities—due to delayed detection and regimen failures.[4] Transmission mirrors drug-susceptible TB via airborne droplets but persists in nosocomial and community clusters, exacerbated by HIV co-infection and incarceration.[51] Treatment for XDR-TB demands individualized, all-oral regimens spanning 6–18 months, incorporating Group B/C drugs (e.g., clofazimine, cycloserine) alongside novel agents like pretomanid in the BPaL regimen (bedaquiline, pretomanid, linezolid), which showed 89–94% efficacy in trials but requires susceptibility confirmation to avoid amplification.[52] Global success rates hover at 44.2% (successful outcomes including cure or treatment completion), well below the WHO's 75% benchmark, attributed to drug toxicities (e.g., ototoxicity, neuropathy), adherence barriers, and incomplete susceptibility profiles.[52][53] In pediatric cases, outcomes improve slightly with surgery or shorter regimens, yet meta-analyses report 50–60% unfavorable results, highlighting needs for pediatric formulations.[54] Prognostic factors include low baseline bacillary load, non-cavitary disease, and early bariatric intervention, but overall case-fatality exceeds 50% without prompt molecular-guided therapy.[55] Challenges persist from supply chain disruptions for newer drugs and variable access in low-resource areas, underscoring the imperative for expanded genomic surveillance to curb progression to "totally drug-resistant" phenotypes.[56]Pre-XDR, Totally Drug-Resistant, and Emerging Strains
Pre-XDR tuberculosis (pre-XDR-TB) refers to cases of multidrug-resistant or rifampicin-resistant TB (MDR/RR-TB) with additional resistance to either a fluoroquinolone or a second-line injectable drug, but not both, as defined by the World Health Organization (WHO) in its January 2021 update to resistance classifications.[43] This category bridges MDR-TB and extensively drug-resistant TB (XDR-TB), highlighting progressive resistance that complicates treatment regimens reliant on these drug classes; pre-XDR-TB/FQ involves fluoroquinolone resistance alongside MDR/RR-TB, while pre-XDR-TB/injectable denotes resistance to agents like amikacin, capreomycin, or kanamycin without fluoroquinolone involvement.[57] Unlike XDR-TB, which requires MDR/RR-TB plus resistance to both any fluoroquinolone and at least one second-line injectable, pre-XDR-TB retains some susceptibility in one of these critical categories, allowing for tailored shorter regimens in fluoroquinolone-susceptible cases but demanding vigilant susceptibility testing.[11] These definitions aim to standardize surveillance and guide individualized therapy, with pre-XDR-TB comprising a subset of the estimated 410,000 incident MDR/RR-TB cases globally in 2022, though exact proportions vary by region due to uneven diagnostic access.[58] Totally drug-resistant TB (TDR-TB), also termed super-XDR-TB in some contexts, describes strains resistant to all standard first- and second-line anti-TB drugs tested in vitro, a concept first proposed in 2012 based on 12 cases in Iran where patients remained culture-positive after 18–24 months of therapy despite exposure to multiple agents including isoniazid, rifampicin, fluoroquinolones, injectables, and others like ethionamide and cycloserine.[59] Similar reports emerged from India in 2011–2012, involving strains resistant to at least 12 drugs, but the term lacks official WHO endorsement due to ambiguities in testing scope—excluding newer agents like bedaquiline or delamanid—and potential laboratory inconsistencies; critics argue it overlaps with XDR-TB without adding diagnostic utility, as "total" resistance ignores experimental or salvage therapies.[60] Case numbers remain low and sporadic, with fewer than 100 documented globally by 2013, primarily in high-burden settings like Mumbai slums, where treatment failure rates exceeded 80% in affected cohorts; however, without standardized criteria, TDR-TB reports risk inflating perceptions of untreatability, as some strains respond to novel combinations.[61] Emerging strains of drug-resistant TB increasingly exhibit resistance to newer core drugs introduced since 2012, such as bedaquiline, pretomanid, and linezolid, threatening the efficacy of shortened regimens like BPaLM (bedaquiline, pretomanid, linezolid, moxifloxacin).[62] A January 2025 genomic analysis of over 10,000 MDR-TB isolates from 73 countries revealed clustered transmission of bedaquiline-resistant lineages in Eastern Europe and Central Asia, with resistance mutations (e.g., in Rv0678) arising de novo during treatment and spreading person-to-person, complicating global targets to treat 75% of eligible MDR/RR-TB cases by 2025.[63] These strains often stem from sequential acquisition of mutations under selective pressure from suboptimal therapy, with prevalence rising from near-zero pre-2018 to 2–5% in high-incidence areas by 2024; for instance, pretomanid resistance via clavulanate-sensitive mutations has been documented in South African trials, underscoring the need for real-time genomic surveillance to preempt pan-resistance.[64] While no fully untreatable strains dominate, these developments highlight causal drivers like monotherapy exposure and supply disruptions, with ongoing trials exploring cytochrome bc1 inhibitors as adjuncts against such variants.[65]Epidemiology
Global Burden and Trends (1990–2025)
The global incidence of multidrug-resistant or rifampicin-resistant tuberculosis (MDR/RR-TB) has increased substantially since 1990, driven by factors including inadequate treatment adherence, interrupted supply chains, and high-burden settings with limited diagnostics. Early estimates from Global Burden of Disease analyses indicate approximately 52,000 incident MDR-TB cases in 1990, rising to 136,000 by 2021, though uncertainty intervals reflect modeling challenges in underreported regions.[66] World Health Organization (WHO) estimates for MDR/RR-TB, which include rifampicin resistance as a proxy due to diagnostic priorities, place annual incident cases at around 450,000–500,000 from the mid-2010s, stabilizing at approximately 400,000 in 2023 after a gradual decline from 2015 to 2019.[4] [67] Mortality from MDR/RR-TB has followed a parallel upward trajectory, with WHO attributing about 150,000 deaths to the condition in 2023, representing a significant portion of total tuberculosis fatalities despite comprising only 3–4% of cases.[4] The proportion of new tuberculosis cases that are MDR/RR-TB decreased from 4.1% in 2015 to 3.2% in 2023, suggesting modest progress in preventing primary resistance, though rates remain higher (up to 18%) among previously treated cases due to acquired resistance from incomplete regimens.[4] Absolute numbers have persisted at high levels because overall tuberculosis incidence declines have been offset by population growth and persistent transmission in high-prevalence areas.[37] Projections for 2024–2025 indicate a continued stable or slightly increasing burden absent accelerated interventions, with some models forecasting growth in incidence and disability-adjusted life years through 2050 under current trends.[66] Detection gaps exacerbate the issue, as only about 40–50% of estimated cases are diagnosed annually, limiting response effectiveness.[4] Treatment success rates reached 68% for MDR/RR-TB in recent cohorts, improved by shorter regimens, but low enrollment and high loss-to-follow-up sustain the reservoir.[37]Regional and High-Risk Hotspots
In 2023, an estimated 400,000 people developed multidrug- or rifampicin-resistant tuberculosis (MDR/RR-TB) globally, with India accounting for 27% of cases, followed by the Russian Federation, Indonesia, China, and the Philippines at approximately 7% each.[4] Asia bears the largest absolute burden, driven by high population density, suboptimal treatment adherence, and historical underreporting in countries like India and Indonesia, where diagnostic delays exacerbate community transmission.[4] Eastern Europe and Central Asia represent critical hotspots for high resistance proportions, with the WHO European Region showing 24% of new TB cases as MDR/RR-TB in 2023—the highest regionally.[4] The Russian Federation reports elevated rates, linked to prison overcrowding and fragmented healthcare systems, while countries like Ukraine and Moldova exhibit particularly high extensively drug-resistant (XDR-TB) incidence, with age-standardized rates exceeding those in most other regions due to conflict-disrupted controls and nosocomial spread.[68] These areas sustain transmission through inadequate isolation and retreatment failures, with proportions among previously treated cases reaching 54% in parts of the European Region.[4] Sub-Saharan Africa faces compounded risks from HIV co-infection, with eight of the WHO's 30 high MDR/RR-TB burden countries in the region, including the Democratic Republic of Congo, Nigeria, Mozambique, and South Africa.[69] South Africa's KwaZulu-Natal province emerges as an XDR-TB epicenter, where nearly half of national cases cluster amid mining communities and poor ventilation in informal settlements, fostering airborne spread.[70] Incidence has stabilized or declined slightly since 2015 in African and Western Pacific regions, yet absolute numbers remain substantial due to diagnostic gaps and immune suppression.[4]| Top Countries by Estimated MDR/RR-TB Cases (2023) | Share of Global Total |
|---|---|
| India | 27% |
| Russian Federation | 7.4% |
| Indonesia | 7.4% |
| China | 7.3% |
| Philippines | 7.2% |
Demographic and Contributing Risk Factors
Multidrug-resistant tuberculosis (MDR-TB) disproportionately affects males, with global incidence consistently higher among men than women across age groups, as evidenced by patterns in incident cases peaking in males aged 35–39 years, accounting for up to 220,010 cases worldwide.[72] Age-specific trends show elevated risk in working-age adults, particularly those 25–45 years old, though burden increases with advancing age in lower socio-demographic index (SDI) regions, affecting middle-aged and older males most severely.[5] [68] Geographically, the highest burdens occur in low- and middle-income countries, with hotspots in regions like southern Africa (e.g., Eswatini, Namibia, Lesotho) and parts of Asia, where epidemiological factors drive 69% of the global MDR-TB load.[73] [74] Prior anti-TB treatment represents the strongest individual risk factor for developing MDR-TB, as incomplete or interrupted therapy fosters selection of resistant strains through Darwinian evolution under subtherapeutic drug pressure.[11] [75] HIV co-infection amplifies vulnerability by impairing immune clearance, with co-infected individuals facing 3–6 times higher odds of MDR-TB progression compared to those without HIV.[76] Diabetes similarly elevates risk via hyperglycemia-induced immune dysregulation and delayed bacterial clearance, with diabetic TB patients showing significantly higher MDR-TB incidence in cohort studies.[77] Socioeconomic and behavioral contributors include malnutrition, which compromises host immunity and increases susceptibility to resistant strains, alongside smoking (relative risk up to 1.8) and harmful alcohol use that exacerbate lung damage and adherence failures.[2] [78] Overcrowding and poor ventilation in low-income settings facilitate transmission of resistant variants, while low education and family income correlate with irregular treatment adherence, a proximal cause of acquired resistance.[79] [80] Contact with known MDR-TB cases or residence in high-prevalence areas further compounds these risks through airborne spread in resource-limited environments.[11]Transmission and Causes
Primary Modes of Spread
Multidrug-resistant tuberculosis (MDR-TB) is transmitted primarily through airborne routes, identical to drug-susceptible tuberculosis, via inhalation of aerosolized droplet nuclei containing Mycobacterium tuberculosis bacilli expelled from the respiratory tract of infectious individuals.[11] [1] Persons with active pulmonary or laryngeal MDR-TB generate these infectious particles during coughing, sneezing, speaking, or singing, with viability maintained in air for hours under conditions of low humidity and minimal sunlight.[81] Transmission requires only a few inhaled bacilli to establish infection in susceptible hosts, typically occurring in prolonged close-contact scenarios rather than brief outdoor exposures.[82] Infectiousness correlates with bacillary load, as measured by sputum smear positivity; smear-positive MDR-TB cases pose the highest risk, with untreated individuals remaining contagious for weeks to months until effective therapy reduces viable bacilli.[83] Unlike secondary resistance acquired during inadequate treatment, primary MDR-TB in new cases stems directly from community-acquired transmission of resistant strains, evidenced by genomic clustering in outbreaks.[11] [84] Delays in diagnosing resistance—often due to initial use of standard regimens—can extend the infectious period, amplifying spread compared to promptly treated susceptible TB.[11] Risk escalates in enclosed, poorly ventilated environments with high occupant density, such as households, prisons, mines, or healthcare facilities lacking isolation, where airflow stagnation allows droplet nuclei to accumulate.[85] [86] Household contacts of MDR-TB index cases exhibit infection rates up to 50% in high-burden settings, underscoring familial transmission dynamics.[87] MDR-TB does not spread via casual contact, fomites, shared utensils, or non-respiratory secretions, as the bacilli lack environmental persistence outside aerosols.[88] HIV co-infection in contacts heightens susceptibility, but MDR-TB strains show no inherent increased transmissibility over susceptible variants absent treatment failure.[83]Human and Systemic Drivers of Emergence
The emergence of multidrug-resistant tuberculosis (MDR-TB), defined as resistance to at least isoniazid and rifampicin, primarily arises from acquired resistance in patients undergoing inadequate treatment, where selective pressure favors the survival and proliferation of resistant Mycobacterium tuberculosis mutants.[3] Incomplete or interrupted therapy, often due to patient non-adherence stemming from treatment side effects, long durations (typically 6-9 months for drug-susceptible TB), or socioeconomic barriers like inability to access care, amplifies this resistance by allowing partially treated infections to persist and mutate.[89] Peer-reviewed analyses indicate that prior TB treatment history correlates strongly with MDR-TB development, with retreatment cases showing odds ratios up to 10-fold higher than new cases, as erratic drug exposure disrupts bacterial populations unevenly.[7] Human behavioral factors exacerbate this process, including smoking and alcohol use, which impair immune responses and treatment adherence; studies report relative risks of MDR-TB up to 1.8 for smokers and elevated odds for heavy drinkers, independent of other confounders.[90] [5] Diabetes mellitus further compounds vulnerability by altering host immunity, with meta-analyses linking it to 2-3 times higher MDR-TB prevalence through delayed diagnosis and poor glycemic control hindering drug efficacy.[91] Direct contact with index cases, particularly in households or communities with delayed case detection, facilitates primary transmission of resistant strains, underscoring patient-level transmission chains as a secondary but critical driver.[89] Systemic drivers rooted in healthcare infrastructure deficiencies propel MDR-TB amplification and dissemination, including irregular drug supply chains leading to stockouts or substandard/counterfeit medications, which undermine regimen reliability in low-resource settings.[89] Weak infection control in congregate settings like prisons—where overcrowding and poor ventilation foster airborne spread—has been identified as a key transmission amplifier, with genomic studies tracing recent MDR-TB clusters to incarceration histories in high-prevalence regions.[92] [93] Broader social determinants, such as poverty and under-resourced national TB programs failing to implement directly observed treatment short-course (DOTS) universally, perpetuate cycles of default and resistance; in emerging economies, these intersect with low health literacy and gender disparities, delaying care-seeking and enabling community-level emergence.[94] Unemployment and rural residence correlate with higher MDR-TB incidence through reduced access to diagnostics and therapy, as evidenced by cohort data showing 1.5-2-fold increased risks in affected demographics.[95] Co-epidemics like HIV, prevalent in sub-Saharan Africa and Eastern Europe, intensify systemic burdens by necessitating complex polypharmacy that heightens resistance selection if adherence falters.[96] Overall, these intertwined factors highlight that MDR-TB emergence reflects not innate bacterial evolution alone but failures in human-systemic interfaces, with global estimates indicating 410,000 incident MDR/RR-TB cases annually as of 2023, stable post-2020 disruptions.Diagnosis
Conventional Testing Approaches
Conventional testing for multidrug-resistant tuberculosis (MDR-TB) primarily involves microscopy, mycobacterial culture, and phenotypic drug susceptibility testing (DST), which serve as foundational methods for detecting Mycobacterium tuberculosis and assessing resistance to key drugs like isoniazid and rifampicin.[12] These approaches, while established as the reference standards, are limited by their time requirements and inability to rapidly identify resistance patterns.[11] Sputum smear microscopy using Ziehl-Neelsen staining detects acid-fast bacilli (AFB), indicating possible TB infection, but lacks specificity for M. tuberculosis species and cannot identify drug resistance.[97] Sensitivity is low, particularly in paucibacillary cases common in MDR-TB or HIV-co-infected patients, with detection rates often below 50% compared to culture.[98] Fluorochrome staining variants like auramine improve visibility but still require confirmation via culture for definitive diagnosis.[97] Mycobacterial culture remains the gold standard for confirming M. tuberculosis growth and viability, using solid media such as Löwenstein-Jensen or liquid systems like mycobacteria growth indicator tube (MGIT).[99] Solid media cultures take 3–8 weeks for growth, while automated liquid systems reduce this to 1–2 weeks, enabling subsequent DST.[100] However, contamination risks and biosafety requirements in BSL-3 labs complicate implementation in resource-limited settings.[11] Phenotypic DST on cultured isolates determines resistance by exposing bacteria to critical concentrations of anti-TB drugs, using methods like the indirect proportion method on solid media or broth-based assays in MGIT.[12] For MDR-TB detection, testing focuses on isoniazid and rifampicin, with resistance defined by growth exceeding 1% of the control at critical concentrations (e.g., 0.2 μg/ml for rifampicin on Löwenstein-Jensen).[100] Total turnaround time from specimen to DST results can exceed 8 weeks, delaying MDR-TB confirmation and treatment initiation.[101] Discordance between phenotypic and genotypic results occurs in up to 10% of cases due to heteroresistance or non-standardized breakpoints.[102]Advanced Molecular and Rapid Detection Methods
Advanced molecular detection methods have revolutionized the diagnosis of multidrug-resistant tuberculosis (MDR-TB) by targeting genetic mutations associated with drug resistance, enabling results within hours to days compared to weeks for phenotypic culture-based tests.[103] The World Health Organization (WHO) recommends nucleic acid amplification tests (NAATs) as initial diagnostics over smear microscopy due to their higher sensitivity for detecting Mycobacterium tuberculosis complex (MTBC) and key resistance markers, particularly rifampicin resistance, which serves as a proxy for MDR-TB.[103] These methods amplify and probe specific genomic regions, such as the rpoB gene for rifampicin resistance, reducing diagnostic delays that contribute to transmission.[104] The Xpert MTB/RIF assay, a cartridge-based NAAT, detects MTBC DNA and rifampicin resistance mutations via real-time PCR and melt curve analysis, yielding results in under two hours.[105] Its pooled sensitivity for MTBC detection ranges from 69.4% to 84.7% in high-prevalence settings, with specificity of 98.4% to 98.8%; for rifampicin resistance, sensitivity exceeds 95% and specificity nears 98%.[106] An upgraded version, Xpert MTB/RIF Ultra, enhances sensitivity to 88% for both pulmonary and extrapulmonary TB, addressing limitations in smear-negative cases.[107] The U.S. Centers for Disease Control and Prevention (CDC) endorses such assays through its Molecular Detection of Drug Resistance (MDDR) service, which identifies MDR-TB mutations rapidly for public health response.[108] However, Xpert primarily screens for rifampicin and limited fluoroquinolone resistance, necessitating confirmatory testing for full MDR profiles.[11] Line probe assays (LPAs), such as GenoType MTBDRplus, use PCR amplification followed by reverse hybridization to detect mutations in genes like rpoB, katG, and inhA for rifampicin and isoniazid resistance, with extensions to second-line drugs like fluoroquinolones.[109] WHO-endorsed since 2008, LPAs offer sensitivity and specificity above 95% for detecting MDR-TB in smear-positive specimens, with turnaround times of 1-2 days.[110] They excel in resource-limited settings for batch processing but require skilled technicians and cannot detect low bacterial loads as effectively as NAATs.[111] Comparative studies show LPAs comparable to Xpert for first-line resistance but superior for isoniazid-specific mutations.[112] Whole-genome sequencing (WGS) provides comprehensive profiling by sequencing the entire MTBC genome to predict resistance to multiple drugs via known mutation catalogs, achieving over 90% concordance with phenotypic testing for key agents like isoniazid and rifampicin.[113] CDC employs WGS for surveillance, detecting resistance mutations and transmission clusters, with implementation accelerating post-2020 due to bioinformatics advances.[114] As of 2023-2024, WGS sensitivity for predicting resistance reaches 92-96% across drugs, though gaps persist for novel mutations and ethambutol.[115] Challenges include high costs, computational needs, and validation in diverse strains, limiting routine use outside reference labs, yet it informs personalized regimens and outbreak control.[116] Integration of these methods has increased MDR-TB detection rates by 20-30% in implemented programs, underscoring their role in curbing spread.[117]Prevention
Core TB Control Frameworks
The Directly Observed Treatment, Short-course (DOTS) strategy, introduced by the World Health Organization (WHO) in 1994, established the foundational framework for TB control worldwide.[118] Its five core components include sustained government commitment with dedicated funding and political prioritization; case detection via quality-assured sputum smear microscopy; standardized six-month short-course chemotherapy regimens administered under direct observation to ensure adherence; reliable supply chains for essential anti-TB drugs; and robust systems for monitoring treatment outcomes and program performance.[119] By 2009, DOTS implementation had cured approximately 36 million people with TB and averted up to 8 million deaths, demonstrating its efficacy in reducing transmission through high cure rates exceeding 85% for smear-positive cases when fully applied.[120] However, DOTS primarily targeted drug-susceptible TB, revealing gaps in addressing emerging resistance without integrated drug susceptibility testing (DST). The Stop TB Strategy, launched by WHO on World TB Day in 2006, expanded DOTS to confront limitations in multidrug-resistant TB (MDR-TB) management, TB-HIV coinfection, and health system constraints.[121] It comprises six interconnected components: high-quality DOTS expansion; targeted interventions for MDR-TB, including scaled-up access to second-line drugs and DST; health systems strengthening to support integrated care; engagement of all healthcare providers, including private sectors; community empowerment through patient support and stigma reduction; and accelerated research for new tools.[122] A key MDR-TB element aimed to diagnose and treat 1.5 million cases by 2015 via DOTS-Plus initiatives, emphasizing quality-assured second-line regimens to achieve cure rates above 70% in programmatic settings.[121] This strategy aligned with Millennium Development Goals, prioritizing empirical case detection and treatment success metrics to halve TB prevalence and deaths between 1990 and 2015, though MDR-TB control lagged due to diagnostic delays and drug shortages in high-burden regions. The End TB Strategy, endorsed by the WHO World Health Assembly in May 2014 for implementation from 2015 to 2035, represents the current overarching framework, building on prior strategies with ambitious, evidence-based targets to end the TB epidemic.[123] It sets milestones to reduce TB incidence by 80% (from 171 per 100,000 in 2015 to 34 per 100,000) and deaths by 90% (to 10 per 100,000) by 2030, alongside zero catastrophic costs for affected households.[123] Three pillars underpin it: integrated patient-centered care and prevention, mandating universal DST at diagnosis and prompt MDR-TB treatment coverage exceeding 90% by 2025; bold policies enabling multisectoral accountability, financing, and regulatory support for drug access; and intensified research to develop shorter regimens and vaccines.[124] For MDR-TB, the strategy causalizes resistance emergence to incomplete treatment and poor diagnostics, advocating rapid molecular tests like Xpert MTB/RIF to detect rifampicin resistance (a proxy for MDR) within hours, integrated into national programs to curb amplification of resistance.[123] Progress tracking relies on annual WHO reports, revealing persistent gaps in low-resource settings where only 62% of estimated MDR-TB cases received treatment in 2022, underscoring the need for causal interventions like enhanced surveillance over reliance on expanded access alone.[123]MDR-Specific Preventive Measures
Preventing the emergence of multidrug-resistant tuberculosis (MDR-TB) primarily involves ensuring adherence to effective first-line treatment regimens for drug-susceptible TB to avoid the selection of resistant strains. The Centers for Disease Control and Prevention (CDC) emphasize that all patients with TB disease must complete prescribed medications exactly as directed, without missing doses, as incomplete treatment is a leading cause of acquired resistance to isoniazid and rifampicin.[85] Similarly, proper initial drug susceptibility testing and avoidance of monotherapy or suboptimal regimens are critical to minimize resistance amplification during therapy.[125] For confirmed or suspected MDR-TB cases, enhanced infection control measures are essential to curb transmission, particularly in healthcare facilities and congregate settings. These include airborne infection isolation with negative-pressure rooms, use of N95 respirators or equivalent by healthcare workers, and rapid triage to isolate patients pending drug susceptibility results, as outlined in CDC guidelines updated to reflect evolving epidemiology.[126] Community-based strategies, such as supervised treatment and reduced inpatient stays, further limit nosocomial spread by facilitating outpatient management under directly observed therapy.[127] Preventive therapy for household contacts of MDR-TB patients represents a targeted intervention to avert disease progression in exposed individuals. The World Health Organization (WHO) strongly recommends a 6-month regimen of daily levofloxacin for adults and children (using pediatric formulations where needed), based on evidence demonstrating substantial risk reduction.[128] A 2024 meta-analysis of cohort studies reported that such MDR-TB preventive treatment lowers incidence by approximately 66%, with levofloxacin showing favorable safety and cost-effectiveness profiles.[129] Regimens should be tailored to the source case's resistance profile; for strains with fluoroquinolone resistance, alternative combinations may be considered, though evidence remains limited.[130] Close monitoring for adverse effects and follow-up screening with interferon-gamma release assays or chest radiographs are advised to assess efficacy.[131] Surveillance and rapid diagnostics also play a pivotal role in MDR-specific prevention by enabling early detection and interruption of transmission chains. WHO prioritizes scaling up molecular tests like Xpert MTB/RIF to identify rifampicin resistance promptly, allowing isolation and treatment initiation before widespread dissemination.[132] At a programmatic level, integrating these measures with broader TB control—while addressing gaps in high-burden settings—has shown potential to contain MDR-TB epidemics, though implementation barriers persist in resource-limited areas.[133]Contact Tracing and Prophylaxis Advances
Contact tracing for multidrug-resistant tuberculosis (MDR-TB) has advanced through intensified household and community-based screening protocols, often led by community health workers (CHWs), achieving high coverage rates such as 99.4% initial screening among 347 contacts in a Peruvian study of 99 index cases.[134] Active tracing extends beyond households to include serial screenings over at least six months, identifying subclinical infections in contacts of MDR-TB patients, as demonstrated in South African cohorts where repeated evaluations uncovered additional cases missed by initial assessments.[135] Whole-genome sequencing (WGS) of Mycobacterium tuberculosis isolates has enabled precise mapping of transmission clusters and resistance patterns, distinguishing recent from remote transmission in MDR-TB outbreaks and informing targeted interventions, with studies showing its utility in low-burden settings for resolving cryptic chains.[136] [137] Prophylaxis for MDR-TB contacts has shifted from uncertain or absent regimens to evidence-based options, particularly fluoroquinolones like levofloxacin, following randomized trials in the 2020s. Combined analysis of two multicenter trials involving household contacts exposed to MDR-TB index cases found that six months of daily levofloxacin reduced incident TB by 62% compared to placebo, with no significant safety concerns beyond mild adverse events.[138] [139] A meta-analysis of cohort studies corroborated this, estimating 66% reduction in progression to active disease among treated contacts, supporting tailored regimens based on index case susceptibility profiles to avoid ineffective monotherapy.[129] World Health Organization guidelines now endorse levofloxacin for six months in child contacts, potentially combined with ethambutol or ethionamide, prioritizing close contacts under age five or with HIV, while emphasizing baseline screening to rule out active disease before initiation.[128] These advances underscore the causal role of early intervention in breaking transmission chains, though implementation gaps persist in resource-limited settings due to drug access and adherence challenges.[140]Treatment
Traditional Second-Line Regimens
Traditional second-line regimens for multidrug-resistant tuberculosis (MDR-TB) typically comprised combinations of drugs active against Mycobacterium tuberculosis strains resistant to isoniazid and rifampicin, administered over 18 to 24 months to achieve cure rates of approximately 50-70% in optimal settings.[3] These regimens were structured in two phases: an intensive phase lasting 6 to 8 months, incorporating at least four to five likely effective agents including an injectable aminoglycoside or polypeptide, followed by a continuation phase with oral agents until treatment completion.[141] Regimen design relied on drug susceptibility testing and WHO-recommended hierarchical grouping, prioritizing group A drugs (levofloxacin or moxifloxacin, bedaquiline if available pre-2010s, linezolid), group B (cycloserine or terizidone, clofazimine), and group C (other fluoroquinolones, ethambutol, delamanid if applicable, pyrazinamide, imipenem-cilastatin or meropenem, amikacin or streptomycin, ethionamide or prothionamide, para-aminosalicylic acid).[1] Key components included second-line injectables such as amikacin, kanamycin, or capreomycin, administered daily or thrice weekly during the intensive phase to provide bactericidal activity, though their use was limited to 4-6 months to mitigate risks of ototoxicity, nephrotoxicity, and hypokalemia.[142] Oral backbone drugs encompassed fluoroquinolones like levofloxacin or moxifloxacin for their potent activity against replicating bacilli, alongside bacteriostatic agents such as ethionamide/prothionamide, cycloserine, and para-aminosalicylic acid, which targeted persistent organisms but often induced severe adverse effects including psychiatric disturbances, gastrointestinal intolerance, and hypothyroidism.[141] Earlier formulations sometimes incorporated pyrazinamide and ethambutol if susceptibility permitted, extending the total drug count to five or more to overcome resistance barriers.[143] Efficacy hinged on adherence under directly observed therapy, with success defined as sputum culture conversion by month 6 and sustained negative cultures; however, global treatment outcomes averaged below 60% due to high pill burden (up to 15,000 doses over the course), toxicity-driven discontinuations (affecting 20-30% of patients), and emergence of additional resistances.[3] In resource-limited settings, injectable requirements posed logistical challenges, contributing to default rates exceeding 20%, while the regimens' reliance on weaker sterilizing agents compared to first-line drugs prolonged exposure and amplified selection pressure for extensively drug-resistant (XDR-TB) strains.[141] By the late 2000s, meta-analyses reported pooled success rates of 62% for MDR-TB under programmatic conditions, underscoring the need for individualized susceptibility-guided adjustments to avoid ineffective combinations.[142]Shorter All-Oral Regimens and 2020s Innovations
In response to the limitations of longer, injectable-inclusive regimens for multidrug-resistant tuberculosis (MDR-TB), which often spanned 18-24 months and carried high risks of ototoxicity and nephrotoxicity, the World Health Organization (WHO) endorsed shorter all-oral regimens starting in 2020, prioritizing bedaquiline-containing combinations to improve patient adherence and outcomes.[8] These regimens eliminate injectables like kanamycin or capreomycin, reducing treatment burden while maintaining or exceeding efficacy, with success rates reported at 85-95% in clinical trials compared to 50-70% for traditional approaches.[144] The transition reflects empirical evidence from phase 3 trials demonstrating noninferiority of 6-9 month durations against historical standards, driven by causal factors such as drug synergy and reduced acquired resistance from shorter exposure.[40] A cornerstone innovation is the 6-month BPaLM regimen—comprising bedaquiline, pretomanid, linezolid (600 mg), and moxifloxacin—for rifampicin-resistant TB without additional fluoroquinolone resistance, validated in the ZeNix trial (NCT03056623) where 89% of participants achieved favorable outcomes at 24 weeks post-treatment.[145] Pretomanid, approved by the FDA in 2019 for this use, targets mycolic acid biosynthesis in Mycobacterium tuberculosis, synergizing with bedaquiline's ATP synthase inhibition to accelerate bacterial clearance.[146] WHO incorporated BPaLM into guidelines in January 2022 as a preferred option for eligible MDR-TB cases, replacing longer individualized therapy, with real-world data from 2023-2025 confirming 90-95% success rates and lower adverse events like peripheral neuropathy from optimized linezolid dosing.[147] For fluoroquinolone-resistant cases, the BPaL variant (omitting moxifloxacin) extends to 6 months with comparable efficacy, as evidenced by 91% success in Nix-TB trial extensions.[148] The 2020s have seen further refinements through multinational trials like endTB (2017-2023), which tested three 9-month all-oral regimens incorporating bedaquiline, linezolid, levofloxacin, and clofazimine or delamanid, achieving 85-90% success rates noninferior to 18-month controls across seven countries.[40] In April 2025, WHO updated recommendations to include a novel 6-month BDLLfxC regimen (bedaquiline, delamanid, linezolid, levofloxacin, clofazimine) for multidrug- and pre-extensively drug-resistant TB, based on interim data showing reduced relapse risks via dual beta-lactamase inhibition.[39] These innovations stem from pharmacokinetic modeling and genomic surveillance, prioritizing regimens with low cross-resistance potential, though challenges persist in resource-limited settings where pretomanid access remains uneven despite global tenders.[149] Ongoing studies, such as TRUST (NCT03867136), validate 6-9 month oral protocols in diverse populations, with 2025 reports indicating 92% adherence versus 60-70% for legacy treatments.[150]| Regimen | Duration | Key Components | Target Population | Success Rate (Trials) | WHO Endorsement |
|---|---|---|---|---|---|
| BPaLM | 6 months | Bedaquiline, pretomanid, linezolid, moxifloxacin | MDR/RR-TB, fluoroquinolone-susceptible | 89% | 2022 |
| BPaL | 6 months | Bedaquiline, pretomanid, linezolid | MDR/RR-TB, fluoroquinolone-resistant | 91% | 2022 |
| endTB options (e.g., B-Lfx-C) | 9 months | Bedaquiline, linezolid, levofloxacin, clofazimine | Rifampin-resistant, variable resistance | 85-90% | 2024 |
| BDLLfxC | 6 months | Bedaquiline, delamanid, linezolid, levofloxacin, clofazimine | Pre-XDR-TB | ~90% (interim) | 2025 |