Abstract
The emergence of antibiotic-resistant pathogens is becoming increasingly problematic in the treatment of bacterial diseases. This has led to bacteriophages receiving increased attention as an alternative form of treatment. Phages are effective at targeting and killing bacterial strains of interest and have yielded encouraging results when administered as part of a tailored treatment to severely ill patients as a last resort. Despite this, success in clinical trials has not always been as forthcoming, with several high-profile trials failing to demonstrate the efficacy of phage preparations in curing diseases of interest. Whilst this may be in part due to reasons surrounding poor phage selection and a lack of understanding of the underlying disease, there is growing consensus that future success in clinical trials will depend on effective delivery of phage therapeutics to the area of infection. This can be achieved using bacteriophage formulations instead of purely liquid preparations. Several encapsulation-based strategies can be applied to produce phage formulations and encouraging results have been observed with respect to efficacy as well as long term phage stability. Immobilization-based approaches have generally been neglected for the production of phage therapeutics but could also offer a viable alternative.
Highlights
IntroductionIt is estimated that antibiotic-resistant bacterial strains account for approximately
The emergence of antibiotic-resistant pathogens is becoming increasingly problematic in the treatment of bacterial diseases
Bacteriophages represent a viable treatment alternative for bacterial-borne diseases. Their application in clinical settings as a last resort treatment has demonstrated their potential in individual patients but for the widespread therapeutic use of licensed phage products to be achieved in the future, two conditions will need to be satisfied: the successful completion of clinical trials proving their efficacy in a significant portion of cases, and an economically and qualitatively viable means of mass production
Summary
It is estimated that antibiotic-resistant bacterial strains account for approximately. The incorporation of bacteriophages into therapeutic formulations typically involves encapsulating them within a stabilizing substance [23,24] Through such an approach, various antimicrobial materials such as powders, semisolids and nanofibers can be produced, providing more options for effective delivery at the site of infection and, improved patient outcomes. Whilst more commonly applied to the incorporation of bacteriophages into pathogen biosensors, immobilization represents a broad array of techniques which could potentially be applied in this area These are discussed in detail in this review, in addition to an overview of the formulation approaches carried out with respect to phage therapeutics far
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
