Bacteriophages are the most abundant organisms on Earth. As there are few effective treatment options against some pathogens, the interest in the bacteriophage control of multi-drug-resistant bacterial pathogens is escalating, especially for
Klebsiella pneumoniae
. This study aimed to develop a phage-based solution to the rising incidence of extensively drug-resistant clinical
Klebsiella pneumoniae
sequence type (ST16) infections starting from a set of phages recently characterized against this lineage. A phage-cocktail (Katrice-16) composed of eight lytic phages was characterized for potential use in humans.
In vitro
and
in vivo
broth inhibition and
Galleria mellonella
rescue assays were used to demonstrate the efficacy of this approach using a collection of 56 strains of
K. pneumoniae
ST16, with distinct genetic backgrounds that were collected from clinical infections from four disparate nations. Additionally, Katrice-16 anti-biofilm activity, synergism with meropenem, and activity in human body fluids were also assessed. Katrice-16 was highly active
in vitro
against our
K. pneumoniae
ST16 collection (AUC% median = 86.48%; Q1 = 83.8%; Q2 = 96.85%; Q3 = 98.85%). It additionally demonstrated excellent
in vivo
activity in
G. mellonella
rescue assays, even with larvae infected by isolates that exhibited moderate
in vitro
inhibition. We measured significant anti-biofilm activity over 12 h (
p
= .0113) and synergic activity with meropenem. In addition, we also demonstrate that Katrice-16 maintained high activity in human body fluids. Our results indicate that our cocktail will likely be an effective solution for human infections with this increasingly prevalent and often highly resistant bacterial clone.