Infectious Disorders - Drug Targets (Formerly Current Drug Targets - Infectious Disorders) - Volume 25, Issue 4, 2025

Tuberculosis (TB) spreads through droplets that contain Mycobacterium tuberculosis (Mtb) and can infect susceptible people. Due to different risk factors, people have different susceptibility ranges towards TB. The risk factors are classified into three main groups, including bacterial, environmental, and host factors. Literature review reveals that the most important host risk factors are aging, male gender, genetics, epigenetics, having an impaired immune system, diabetes, malignancy, malnutrition, anemia, and pregnancy. The risk factors contribute to the increase in TB cases through inflammation, increased contact with TB patients, disruption of immune genes, changes in gene expression, increased activity of Mtb, damage to cellular immunity, reactivation of Latent TB Infection (LTBI), increased susceptibility to TB, compromised immunity, and changes in the proportion of T cell subgroups, respectively. Therefore, identification of the infection source and high-risk people and timely treatment of the patients can reduce TB mortality and help control the disease.

The increasing incidence of multidrug-resistant tuberculosis (MDR-TB) is one of the most challenging tasks in tuberculosis treatment. Conventional TB treatment regimens have proven ineffective in treating MDR-TB, thus demanding the development of new drugs followed by delivery systems. Bedaquiline, a novel anti-TB drug, has been reported to inhibit the ATP synthase required for the growth and replication of TB bacteria. Bedaquiline is able to target the persistent or latent form of TB, which remains difficult to treat with conventional drugs. This makes bedaquiline an important drug in the fight against MDR-TB. The drug has been approved by the US FDA as well as European Medicines Agency and is now widely used as part of combination therapy for the treatment of MDR-TB. Bedaquiline and its advanced drug delivery system play a key role in tackling MDR-TB, providing a much-needed boost to control and eventually eliminate the disease. However, the cost of the drug remains a concern, and efforts are underway to make bedaquiline more accessible and affordable to patients in resource-limited settings. Nevertheless, the development of bedaquiline nanoformulations represents a significant step forward in the fight against TB and offers hope to millions of patients across the globe.

A mystery pathogen that has not yet infected the entire world’s population is predicted to be the cause of Disease X, which will be contagious. According to WHO scientists, 50 million people are expected to die from Disease X, which would be 20 times deadlier than coronavirus disease 2019 (COVID-19). Many international initiatives are currently in motion to get ready for future pandemics. These include updating the International Health Regulation and the European Legislation, establishing the Health Emergency Preparedness and Response Authority (HERA), establishing international hubs, taking on the international challenge of developing a vaccine for Disease X within 100 days of recognition of emerging Pathogen X, and updating the preparedness plan of National Institute of Allergy and Infectious Diseases. Our current review’s main objective is to determine whether black seeds (Nigella Sativa) can manage Disease X. It has been established by several studies that black seeds (N. sativa) have antiviral, antibacterial, antimicrobial, immunomodulatory, anti-inflammatory, and antioxidant properties, which would be useful in the management of Disease X. Black seeds (N. sativa) may be utilized in conjunction with supportive care and symptomatic therapy to manage Disease X in early phases. Future randomized controlled clinical trials would further evaluate the safety and effectiveness of black seeds (N. sativa) in patients with Disease X.

This review explores various biliary tract diseases caused by different organisms, including cholelithiasis, hepatolithiasis, and choledocholithiasis. The biliary tract's primary functions include collecting, storing, concentrating, and delivering bile juice produced by the liver. Neurohormonal systems involving the vagus and splanchnic nerves, alongside cholecystokinin, regulate gallbladder movement during fasting and digestion. Under normal conditions, bile acids play a crucial role, with approximately 95% being reabsorbed by the intestinal epithelium and returned to the liver via the portal vein system. The liver, often hailed as a miracle worker, detoxifies, purifies, and regenerates, performi ng essential functions in the body. Recent research indicates that the gallbladder, akin to the intestine, harbors a diverse microbiota. Additionally, the biliary mucosa features chemical, mechanical, and immunological barriers that promote immunological tolerance. Hepatotoxicity remains a significant global health concern and a leading cause of mortality. Providing clear and accurate information on liver toxicity is critical, especially in the context of medication safety and public health. By refining these elements, this review can effectively convey the complexity and importance of biliary tract diseases and liver function in health and disease contexts.

Tea is obtained from the young leaves and shoots of the evergreen perennial plant Camellia sinensis (L.) Kuntze, the most popular and frequently consumed product using a natural beverage worldwide. Some kinds of tea products, such as green tea, black tea, and oolong tea, have assorted flavors depending on the manufacturing techniques. Green tea has been studied for many years for its important beneficial effects, including anticancer, anti-obesity, anti-diabetes, anti-inflammatory, neuroprotective, and cardiovascular effects. These effects are primarily associated with tea polyphenols, and regular consumption has been reported to decrease the incidence of some chronic diseases. Current studies support that green tea catechins play an important role in healing and improving the pathology of many diseases. Epigallocatechin-3-gallate (EGCG) is the most a highly found polyphenol in the leaves and is of great interest for its protective role in the prevention of diseases. Therefore, this review presents the efficacy and possible mechanisms of EGCG against sexually transmitted viruses. Moreover, EGCG and its derivatives are recognized as safe bioactive phytochemicals for external and internal use in preventing and treating viral STIs and other concurrent infections. Multidisciplinary studies are essential to discover cheaper, safer, and more effective treatments using EGCG and its derivatives to improve the toxicity and formulations of viral STI medications.

The healthcare system has been greatly affected by the COVID-19 pandemic, resulting in an increase in secondary and co-infections among patients. Factors like pulmonary damage and weakened immune systems make patients more susceptible to fungal infections. Mucormycosis, an opportunistic fungal infection, prospers in environments with limited oxygen, and elevated glucose levels due to conditions such as diabetes and steroid use, as well as in acidic environments from metabolic acidosis and diabetic ketoacidosis, where it demonstrates heightened germination ability. Recognizing these complications is critical to minimize harm to patients. The insights gained from this review can improve our understanding of how fungal infections develop in connection to COVID-19, leading to better predictive algorithms, tailored care plans, enhanced antifungal treatments, quicker diagnostics, and improved management strategies.

Non-coding RNAs (ncRNAs), specifically MicroRNAs or miRNAs, are now understood to be essential regulators in the complex field of gene expression. By selectively binding to certain mRNA targets, these tiny RNA molecules control the expression of genes, leading to mRNA degradation or translational repression. The discovery of miRNAs has significantly advanced biomedical research, particularly in elucidating the molecular mechanisms underlying various diseases and exploring innovative therapeutic approaches. Recent progress in miRNA research has provided insights into their biogenesis, functional roles, and potential clinical applications. Despite the absence of established methodologies for clinical implementation, miRNAs show great promise as diagnostic and therapeutic agents for a wide array of diseases. Their distinctive attributes, such as high specificity, sensitivity, and accessibility, position them as ideal candidates for biomarker development and targeted therapy. Achieving a comprehensive understanding of miRNA biology and functionality is crucial to fully harnessing their potential in medicine. Ongoing research efforts aim to unravel the intricate mechanisms of miRNA-mediated gene regulation and to develop novel approaches for utilizing miRNAs in disease diagnosis, prognosis, and treatment. This review provides a comprehensive analysis of current knowledge on miRNAs, focusing on their biogenesis, regulatory mechanisms, and potential clinical applications. By synthesizing existing evidence and highlighting key research findings, this review aims to inspire further exploration into the diverse roles of miRNAs in health and disease. Ultimately, this endeavour could result in the development of innovative miRNA-based diagnostic and therapeutic strategies.