Antibiotic resistance represents a global challenge that increasingly directs the scientific community toward the exploration of alternative methods for treating bacterial infections. One potential approach to addressing this issue is the development and application of therapeutic systems based on bacteriophages. Given that the therapeutic potential of bacteriophages has been recognized for nearly a century, and considering the numerous reports and studies confirming their effectiveness in treating bacterial infections, the aim of this review thesis is to investigate the reasons for the limited clinical implementation of phage therapy. According to available data, there are currently 23 clinical trials investigating the application of bacteriophages, either ongoing or in the process of patient recruitment. These studies are being conducted in the United States, Canada, France, Belgium, Denmark, the Czech Republic, Georgia, Iran, Uzbekistan, and China, targeting ESKAPE pathogens: Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa, and Enterobacter species. The main challenges in the development of bacteriophage-based therapeutic systems include: 1) the pharmacokinetic properties of bacteriophages, which, due to their complex structure, provoke immune responses and exhibit variable stability under different physiological conditions; 2) the limited efficacy of oral administration due to the acidic pH of the stomach, whereas parenteral administration, particularly intraperitoneal, is more effective as it allows for faster absorption and higher bacteriophage titers in circulation; 3) rare but potential side effects that may result from endotoxin release during bacterial lysis; 4) the possibility of bacteria developing resistance to bacteriophages through mechanisms such as biofilm formation, surface receptor modification, superinfection inhibition, restriction-modification systems, cell autodestruction, and the CRISPR-Cas adaptive immunity system. Additionally, the use of bacteriophages in therapeutic applications is constrained by the lack of adequate regulatory frameworks in many countries, complicating international collaboration and standardization. The production of bacteriophages according to Good Manufacturing Practice (GMP) standards presents a significant challenge due to their propensity for evolutionary changes and the difficulties in achieving reproducibility in manufacturing processes. Although bacteriophages have certain limitations, such as the potential for resistance development and patenting issues, genetically modified bacteriophages offer opportunities to enhance their efficacy and overcome bacterial resistance. However, their application faces additional regulatory hurdles due to the use of genetically modified organisms, further complicating their broader implementation in clinical practice.