Emerging drugs and alternative possibilities in the treatment of tuberculosis

Introduction: Tuberculosis (TB) remains a global health problem. Drug resistance, treatment duration, complexity, and adverse drug reactions associated with anti-TB regimens are associated with treatment failure, prolonged infectiousness and relapse. With the current set of anti-TB drugs the goal to end TB has not been met. New drugs and new treatment regimens are needed to eradicate TB.

Areas covered: Literature was explored to select publications on drugs currently in phase II and phase III trials. These include new chemical entities, immunotherapy, established drugs in new treatment regimens and vaccines for the prophylaxis of TB.

Expert opinion: Well designed trials, with detailed pharmacokinetic/pharmacodynamic analysis, in which information on drug exposure and drug susceptibility of the entire anti-TB regimen is included, in combination with long-term follow-up will provide relevant data to optimize TB treatment.

The new multi arm multistage trial design could be used to test new combinations of compounds, immunotherapy and therapeutic vaccines. This new approach will both reduce the number of patients exposed to inferior treatment and the financial burden. Moreover, it will speed up drug evaluation.

Considering the investments involved in development of new drugs it is worthwhile to thoroughly investigate existing, non-TB drugs in new regimens.     

Synthetic investigational new drugs for the treatment of tuberculosis

Introduction: Tuberculosis (TB) is a major global health concern. And while there are treatments already on the market, there is a demand for new drugs that are effective and safe against Mycobacterium tuberculosis, which reduce the number of drugs and the duration of treatment in both drug-susceptible TB and multidrug-resistant TB (MDR-TB).

Area covered: This review covers promising novel investigational TB drugs that are currently under development. Specifically, the authors review the efficacy of novel agents for the treatment of TB in preclinical, phase I and phase II clinical trials. The authors also review the safety and tolerability profiles of these drugs.

Expert opinion: Bedaquiline and delamanid are the most promising novel drugs for the treatment of MDR-TB, each having high efficacy and tolerability. However, the best regimen for achieving better outcomes and reducing adverse drug reactions remains to be determined, with safety concerns regarding cardiac events due to QT prolongation still to be addressed. Pretomanid is a novel drug that potentially shortens the duration of treatment in both drug-susceptible and drug-resistant TB in combination with moxifloxacin and pyrazinamide. Linezolid shows marked efficacy in the treatment of MDR-TB and extensively drug-resistant TB (XDR-TB), but the drug is known to cause significant adverse drug reactions, including peripheral neuropathy, optic neuropathy and myelosuppression. These adverse reactions must be considered prior to prescribing long-term usage of this drug.     

Selective drug deposition in lungs through pulmonary drug delivery system for effective management of drug-resistant TB

Introduction: The emergence of multidrug-resistant tuberculosis (MDR-TB) and extensively drug-resistant tuberculosis (XDR-TB) is a major health issue and continues to be a global health concern. Despite significant advancements in treatment modalities, ~1.6 million deaths worldwide occur due to TB infection. This is because of tuberculosis reservoirs in the alveoli making it a challenge for the formulation scientist to target this.

Area covered: This review recent investigations on the forefront of pulmonary drug delivery for managing MDR-TB and XDR-TB. Novel delivery systems like liposomes, niosomes, employing carbohydrate, and -coated molecules via conjugation to selectively deliver the drugs to the lung TB reservoir via pulmonary administration are discussed.

Expert opinion: Poor patient adherence to treatment due to side effects and extended therapeutic regimen leads to drug-resistant TB. Thus, it is essential to design novel strategies this issue by developing new chemical entities and/or new delivery systems for delivery to the lungs, consequently reducing the side effects, the frequency and the duration of treatment. Delivery of drugs to enhance the efficacy of new/existing anti-TB drugs to overcome the resistance and enhance patient compliance is underway.     

Microparticles of rifampicin: comparison of pulmonary route with oral route for drug uptake by alveolar macrophages,phagocytosis activity and toxicity study in albino rats

Abstract

Context: Tuberculosis (TB) is a chronic infectious disease with increasing incidence of drug resistance. Oral treatment for TB and multidrug resistance (MDR)-TB can have serious side effects. The causative agent of TB, Mycobacterium tuberculosis, resides in alveolar macrophages (AM). Pulmonary administration of anti-TB drugs can help in delivery of high concentration to AM. The ability of AM to phagocytose can also be utilized to generate mycobactericidal nitric oxide (NO) to improve efficacy of anti-TB drugs.

Objective: To compare the uptake of rifampicin (RIF) by AM post oral and pulmonary administration of RIF microparticles (RM) and to compare hepatotoxicity and phagocytosis activity.

Materials and Methods: RM were produced by spray drying process. RM were administered to rats through oral as well as intratracheal route. The uptake of RIF by AM and liver was measured. NO was measured in bronchoalveolar lavage (BAL) fluid. SGOT and SGPT levels were measured in serum.

Results: Significantly higher (p?<?0.05) concentration of RIF was found in AM post intratracheal administration. NO production was also significantly higher but less than toxic level. SGOT and SGPT levels as well as uptake of RIF by liver were indicative of no hepatotoxicity post intratracheal administration.

Discussion: Phagocytosis of RM post intratracheal administration leads to significantly higher drug level in AM as well as production of significantly higher levels of NO.

Conclusion: The administration of RM as dry powder inhalation (DPI) formulation may reduce treatment time of TB and chances of drug resistance TB.     

The challenges of pharmacokinetic variability of first-line anti-TB drugs

Introduction: Inter-individual variations in the pharmacokinetics (PK) of anti-TB drugs are known to occur, which could have important therapeutic implications in patient management.

Areas covered: We compiled factors responsible for PK variability of anti-TB drugs reported from different settings that would give a better understanding about the challenges of PK variability of anti-TB medications. We searched PubMed data base and Google scholar from 1976 to the present using the key words ‘Pharmacokinetics’, ‘pharmacokinetic variability’, ‘first-line anti-TB therapy’, ‘Rifampicin’, ‘Isoniazid’, ‘Ethambutol’, ‘Pyrazinamide’, ‘food’, ‘nutritional status’, ‘HIV’, ‘diabetes’, ‘genetic polymorphisms’ and ‘pharmacokinetic interactions’. We also included abstracts from scientific meetings and review articles.

Expert commentary: A variety of host and genetic factors can cause inter-individual variations in the PK of anti-TB drugs. PK studies conducted in various settings have adopted different designs, PK sampling time points, drug estimation methodologies. Hence comparison and interpretation of these results should be done with caution More phamacogenomic studies in different patient populations are needed for further understanding.     

环孢素A与抗结核药物合用患者的药学监护

摘 要 目的： 参与使用环孢素A患者的抗结核治疗实践,探讨临床药师针对药物治疗决策及药物相互作用的药学监护模式。方法: 提出并细化临床问题,通过检索文献证据,对各问题进行解答并建立同类临床问题药学监护流程及模式。结果:对于使用环孢素A患者的抗结核方案应选择强有力的药物及避免药物相互作用,同时注重环孢素A血浓度监测。结论: 临床药师可从治疗方案选择、药物相互作用及安全性等方面对免疫抑制患者抗结核治疗进行药学监护。     

Current and developing therapies for the treatment of multi drug resistant tuberculosis (MDR-TB) in India

Introduction: India accounts for 25% of the global burden of MDR-TB. In 2016, the India’s Revised National TB Control Programme reported a success rate of 46% among 19,298 MDR-TB patients treated under the programme. This suboptimal treatment outcome warrants an urgent need for newer drugs and newer regimens in the treatment of MDR-TB. India requires new shorter, cheap, safe and effective anti-TB regimen to treat MDR-TB.

Areas covered: We used different search strategies to obtain relevant literature from PubMed, on Indian experiences of developing therapies for the treatment of MDR-TB. Further information from the Central TB Division Government of India on programmatic management of resistant TB was collected.

Expert opinion: In 2016 WHO recommended a shorter MDR-TB regimen of 9–12 months (4–6 Km-Mfx-Pto-Cfz-Z-Hhigh-dose-E /5 Mfx-Cfz-Z-E) may be used instead of longer regimens. Currently, conducting trials involving newer drugs such as bedaquiline, have been proposed. The regimen will be of a shorter duration containing isoniazid, prothionamide, bedaquiline, levofloxacin, ciprofloxacin, ethambutol and pyrazinamide (STREAM regimen). To successfully treat MDR-TB one requires new classes of antibiotic and newer diagnostic tests. This represents an enormous financial and technical challenge to the programme managers and policy makers.     

An update on repurposed medications for the treatment of drug-resistant tuberculosis

Introduction: Drug-resistant forms of tuberculosis are a major public health problem with a serious global impact. Although there have recently been two new drugs introduced for the treatment of drug-resistant TB (bedaquiline and delamanid), the current therapeutic armamentarium is limited. Because treatment of drug-resistant TB requires the use of a multidrug-regimen, there has been growing interest in the use of antibiotics developed for other infectious pathogens but that have shown efficacy in the treatment of TB.

Areas covered: This paper will review these ‘re-purposed’ agents – including the beta-lactams, clarithromycin, clofazimine, the fluoroquinolones, and linezolid – with a focus on their efficacy, safety, and pharmacokinetic properties.

Expert commentary: There is growing evidence on the efficacy and safety of repurposed drugs for the treatment of drug-resistant TB, supporting their program-wide inclusion in treatment regimens as recommended in revised WHO guidelines. However, additional work is needed to define optimum dosing as well as describe their role in regimen optimization.     

Rifampin vs. rifapentine: what is the preferred rifamycin for tuberculosis?

Introduction: One-third of the world’s population is infected with Mycobacterium tuberculosis (M.tb.). Latent tuberculosis infection (LTBI) can progress to tuberculosis disease, the leading cause of death by infection. Rifamycin antibiotics, like rifampin and rifapentine, have unique sterilizing activity against M.tb. What are the advantages of each for LTBI or tuberculosis treatment?

Areas covered: We review studies assessing the pharmacokinetics (PK), pharmacodynamics (PD), drug interaction risk, safety, and efficacy of rifampin and rifapentine and provide basis for comparing them.

Expert commentary: Rifampin has shorter half-life, higher MIC against M.tb, lower protein binding, and better distribution into cavitary contents than rifapentine. Drug interactions for the two drugs maybe similar in magnitude. For LTBI, rifapentine is effective as convenient, once-weekly, 12-week course of treatment. Rifampin is also effective for LTBI, but must be given daily for four months, therefore, drug interactions are more problematic. For drug-sensitive tuberculosis disease, rifampin remains the standard of care. Safety profile of rifampin is better-described; adverse events differ somewhat for the two drugs. The registered once-weekly rifapentine regimen is inadequate, but higher doses of either drugs may shorten the treatment duration required for effective management of TB. Results of clinical trials evaluating high-dose rifamycin regimens are eagerly awaited.     

Delamanid when other anti-tuberculosis-treatment regimens failed due to resistance or tolerability

Introduction: The limited availability of effective drugs causes difficulties in the management of multidrug-resistant tuberculosis (MDR-TB) and novel therapeutic agents are needed. Delamanid, a new nitro-hydro-imidazooxazole derivative, inhibits mycolic acid synthesis. This review covers the efficacy and safety of delamanid for MDR-TB.

Area covered: This paper reviews the pharmacological profile of delamanid and the results of clinical trials evaluating its efficacy for treating MDR-TB in combination with other anti-TB drugs. The drug’s safety and tolerability profiles are also considered.

Expert opinion: Delamanid showed potent activity against drug-susceptible and -resistant Mycobacterium tuberculosis in both in vitro and in vivo studies. In clinical trials, the drug showed significant early bactericidal activity in pulmonary TB patients, and increased culture conversion after 2 months of treatment in combination with an optimized background regimen in MDR-TB patients. In addition, decreased mortality was observed in MDR-TB patients who received > 6 months of delamanid treatment. The drug was generally tolerable, but QT prolongation should be monitored carefully using electrocardiograms and potassium levels. Therefore, delamanid could be used as part of an appropriate combination regimen for pulmonary MDR-TB in adult patients when an effective treatment regimen cannot otherwise be composed for reasons of resistance or tolerability.     

Novel insights into the pharmacometabonomics of first-line tuberculosis drugs relating to metabolism,mechanism of action and drug-resistance

Abstract

The World Health Organization recommends the directly observed therapy short-course (DOTS) regimen, a combination of four first-line antibiotics (isoniazid, rifampicin, pyrazinamide and ethambutol), for the treatment of active pulmonary tuberculosis (TB). However, despite the fact that this treatment regimen is commonly used worldwide, the metabolism and anti-bacterial mechanisms of these drugs are not yet fully understood. This lack of information ultimately contributes to the poor patient compliance and the subsequent treatment failure and post treatment relapse seen in some TB patients. Pharmacometabonomics, the latest addition to the omics research domain, focuses on the identification of drug-induced metabolome variations. The observed metabolite changes can be used to better understand drug metabolism, drug action and drug-resistance mechanisms. In this review, we summarize the generally known biological mechanisms of the first-line TB drugs included in the DOTS program, and we additionally elaborate on the contribution that pharmacometabonomics has made to the expansion of this knowledge.     

Drug-resistant tuberculosis: what are the treatment options?

Drug-resistant tuberculosis (DR-TB) is an emerging global health threat as treatment involves complex multiple drug regimens, which are longer and more toxic than standard therapy and yet have worse outcomes. In the presence of resistance to one or more first-line drugs, an alternative regimen should be designed. A major problem is the almost complete lack of published evidence regarding the optimal drug combinations and duration of treatment for the different types of DR-TB. Current principles, some of which are based on expert opinion, are that at least three new anti-TB agents should be added to a failing regimen and four agents when multidrug resistance is suspected. All first-line oral anti-TB agents to which the Mycobacterium tuberculosis strains are susceptible should be used, plus one fluoroquinolone. In addition, one injectable anti-TB agent and one or more second-line oral anti-TB agents should be added to the regimen until the target number of drugs is reached. The duration of treatment depends on the type of drug resistance, the type and number of drugs used in the regimen, and the extent of the disease. All forms of DR-TB should receive daily, not intermittent, therapy and all doses should be directly observed. Because of the high rate of adverse drug effects, careful monitoring and appropriate management of these adverse reactions are important to achieve successful treatment. Supportive measures, such as adequate nutrition along with emotional and social supports, are an important part of the treatment. Careful consideration is required when dealing with pregnant or lactating women and HIV co-infected patients, as well as in treatment of extrapulmonary DR-TB.     

Mechanistic investigation of resistance via drug-inactivating enzymes in Mycobacterium tuberculosis

Abstract

Tuberculosis (TB) is a serious major health concern that has existed from millennia. According to annual WHO report 2016, it is considered as world’s ninth highest killer disease by single infectious agent, ranking above HIV/AIDS. To worsen the scenario the development of multi-drug resistant tuberculosis (MDR-TB) and extremely drug-resistant tuberculosis (XDR-TB) have significantly reduced the success rate of TB treatment. Several efforts are being made to handle pharmacodynamic resistance (MDR and XDR-TB) involving designing of new inhibitors, targeting mutated target or by multi-targeting agents. However, the issue of pharmacokinetic resistance in TB is not being addressed appropriately till date. Pharmacokinetic mode of resistance involves an intrinsic mechanism of bacterial drug resistance via expression of various enzymes and efflux pumps that are responsible for the loss of activity of the therapeutic agents. Mycobacterium tuberculosis is also intrinsically resistant to various approved agents via pharmacokinetic mechanism of resistance. Several bacterial enzymes are encoded that either degrade or modifies the drugs and renders them ineffective. Targeting such inactivating bacterial enzymes provides a novel approach to make the current therapy effective and combat the problem of resistance. This review provides an insight into different bacterial enzymes which are responsible for pharmacokinetic drug resistance in TB. The structure attributes and mechanism of catalysis employed by these enzymes to inactivate drug have also been discussed which may provide basis for developing novel therapeutic agents for resistant TB.     

Myoinositol and methyl stearate increases rifampicin susceptibility among drug-resistant Mycobacterium tuberculosis expressing Rv1819c

The alarming increase in multidrug resistance, which includes Bedaquiline and Delamanid, stumbles success in Tuberculosis treatment outcome. Mycobacterium tuberculosis gains resistance to rifampicin, which is one of the less toxic and potent anti-TB drugs, through genetic mutations predominantly besides efflux pump mediated drug resistance. In recent decades, scientific interventions are being carried out to overcome this hurdle using novel approaches to save this drug by combining it with other drugs/molecules or by use of high dose rifampicin. This study reports five small molecules namely Ellagic acid, Methyl Stearate, Myoinositol, Rutin, and Shikimic acid that exhibit synergistic inhibitory activity with rifampicin against resistant TB isolates. In-silico examinations revealed possible blocking of Rv1819c—an ABC transporter efflux pump that was known to confer resistance in M. tuberculosis to rifampicin. The synergistic anti-TB activity was assessed using a drug combination checkerboard assay. Efflux pump inhibition activity of ellagic acid, myoinositol, and methyl stearate was observed through ethidium bromide accumulation assay in the drug-resistant M. tuberculosis clinical strains and recombinant Mycobacterium smegmatis expressing Rv1819c in coherence with the significant reduction in the minimum inhibitory concentration of rifampicin. Cytotoxicity of the active efflux inhibitors was tested using in silico and ex vivo methods. Myoinositol and methyl stearate were completely non-toxic to the hematological and epithelial cells of different organs under ex vivo conditions. Based on these findings, these molecules can be considered for adjunct TB therapy; however, their impact on other drugs of anti-TB regimen needs to be tested.     

Drug interactions between buprenorphine,methadone and hepatitis C therapeutics

Introduction: People who inject drugs (PWID) and other individuals with opioid use disorders have a dramatically higher prevalence of hepatitis C virus (HCV) infection than the general population. The availability of novel direct acting antivirals (DAAs) for the treatment of HCV infection with very high efficacy, improved tolerability and shortened treatment durations have led to global efforts to ramp up treatment for all HCV-infected individuals to prevent or delay complications of the disease. Individuals with opioid use disorders, including those on medication-assisted therapy such as methadone or buprenorphine, are a key demographic group that can benefit from HCV treatment given their high HCV prevalence; however, pharmacokinetic and pharmacodynamic drug interactions could blunt their utility.

Areas covered: We performed a comprehensive literature review of published and unpublished data from PubMed database, relevant conference abstracts/proceedings and FDA approved drug package inserts, to review the pharmacokinetic (PK) profile and drug interactions between currently approved HCV DAAs and methadone and buprenorphine.

Expert opinion: The paper highlights specific drug combinations which result in altered opioid drug levels including telaprevir/methadone, daclatasvir/buprenorphine, and Abbvie 3D combination regimen (paritaprevir, ritonavir, ombitasvir and dasabuvir)/buprenorphine. However, concurrent pharmacodynamics assessments did not reveal significant signs and symptoms of opioid withdrawal or toxicity that would preclude concurrent administration.     

State of the art and future directions in nanomedicine for tuberculosis

Introduction: Tuberculosis (TB) ranks the second leading cause of death from an infectious disease worldwide. However, treatment of TB is affected by poor patient compliance due to the requirement for daily drug administration, for lengthy periods of time, often with severe drug-induced side effects. Nanomedicines have the potential to improve treatment outcomes by providing therapies with reduced drug doses, administered less frequently, under shortened treatment durations.

Areas covered: In this article, we present the pathophysiology of the disease, focusing on pulmonary TB and the characteristics of drugs used in treatment and discuss the application of nanomedicines within this scope. We also discuss new formulation approaches for TB nanomedicines and directions for future research.

Expert opinion: Nanomedicines have the potential to improve TB treatment outcomes. New approaches such as nanoparticle systems able to impact the immune response of macrophages and deliver drug intracellularly, as well as the use of polymer–drug conjugates for drug delivery, are likely to play an important role in TB nanomedicines in future. However, further research is required before TB nanomedicines can be translated to the clinic.     

Stereochemistry at the forefront in the design and discovery of novel anti-tuberculosis agents

Today, 75% of new drugs introduced to the market are single enantiomers and new techniques in asymmetric synthesis and chiral separation expedites chiral drug discovery and development worldwide. The enantiomers of a chiral drug present unique chemical and pharmacological behaviors in a chiral environment, such as the human body, in which the stereochemistry of chiral drugs determines their pharmacokinetic, pharmacodynamic, and toxicological actions. Thus, it is imperative that only the pure and therapeutically active isomer be prepared and marketed. Tuberculosis (TB), a highly contagious and airborne disease that is caused by infection with Mycobacterium tuberculosis (Mtb), currently represents one of the most threatening health problems globally. The emergence of multidrug-resistant TB (MDR-TB) and extensively drug-resistant TB (XDR-TB), as well as HIV co-infection along with a lengthy treatment regimen, highlights an urgent need for the development of new anti-TB agents. Currently, new chiral anti-TB agents are being developed from some well-known anti-TB agents, high throughput screening (HTS) hits, and natural products. This review will focus on the reported chiral anti-TB agents together with the clinical importance of their chirality and stereochemistry.