Impairment of bacteriophage activity in blood: a case study revealing constraints in phage isolation and translation

BackgroundPhage therapy is increasingly considered a promising alternative for treating multidrug-resistant (MDR) infections. However, its clinical application remains limited by challenges in isolating effective phages against resistant clinical strains and by the limited ability of in vitro assays to predict performance in real biological environments. While biological matrices are known to influence phage activity, these effects are not well characterised. MethodsA phage-resistant Pseudomonas aeruginosa isolate from a patient with recurrent MDR urinary tract infection was used as the model organism. Conventional isolation methods failed to recover effective phages, leading to the development of TEASER-i (Transient EDTA- and Ion-Assisted Sequential Enrichment & Recovery). Recovered phages were characterised using adsorption assays, one-step growth kinetics, and time-kill experiments. Their antibacterial activity was evaluated both in vitro and in ex vivo human matrices (whole blood, serum, plasma, and urine). Phage efficacy was quantified using maximum log reduction (Emax), area under the curve (AUC), and phage-to-bacteria ratio (PBR). ResultsA novel TEASER-i method optimised for difficult-to-treat Gram-negative infections, enabled recovery of a functionally effective Osewage-derived P. aeruginosa phage, which outperformed a Ourine-derived P. aeruginosa phage that showed slower replication and lower burst size. Phage activity varied significantly in blood, serum, and plasma. Urine supported the most sustained antibacterial effect. In many cases, early bacterial reduction was followed by regrowth. Sustained activity was associated with maintenance of favourable PBR values, while negative PBR corresponded to treatment failure. At 96 h, only two conditions maintained favourable phage load (log 10 PBR > 0): the S. aureus phage in urine (+1.66) and the sewage-derived P. aeruginosa phage in serum (+1.32). ConclusionsPhage efficacy depends not only on intrinsic lytic capacity but also on the ability to persist and amplify within specific biological environments. Conventional isolation and in vitro screening may therefore overestimate therapeutic potential. Combining optimised isolation strategies with ex vivo evaluation provides a more realistic framework for phage selection and clinical translation.