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Abstract As antibiotic resistance poses a major threat to global health, phage therapy offers an alternative to antibiotic treatments in the face of multidrug-resistant bacteria. However, host resistance to phages is also well-documented. Current computational tools for phage cocktail design do not explicitly address the evolution of phage resistance, let alone through the profiling of bacterial receptors whose variability drives much of phage resistance. We introduce PhagePickr , a computational pipeline for the automated design of phage cocktails that minimize host resistance. Unlike other tools, PhagePickr selects phages based on bacterial surface receptor similarity and prioritizes phage diversity to prevent cross-resistance. The tool uses NCBI datasets, a Nearest Neighbors algorithm, and Multiple Sequence Alignment to identify phenotypically similar hosts and ensure phylogenetic diversity in the final cocktail. We evaluated the utility of PhagePickr on ESKAPE pathogens and two understudied bacteria species. The cocktails included candidate phages predicted to target diverse receptors, comprising both lytic phages with confirmed therapeutic potential and novel candidates from similar species. We demonstrate the tool’s utility in generating cocktails and its capacity to scale as current databases are updated. PhagePickr provides a novel bacteria-centric framework for designing resistance-proof cocktails by exploring shared phenotypes. Author Summary We present PhagePickr, a novel computational tool to design bacteriophage cocktails against pathogenic bacteria. Antibiotic resistance poses a major threat to global health, and phage therapy, the use of viruses that kill bacteria, is a promising alternative treatment. However, bacteria are also under immense selective pressure to develop resistance to phages, and existing tools for automated cocktail design have yet to address this challenge. Our tool is designed to circumvent resistance through two steps: it uses bacterial receptor configurations as predictors of phage infection and constructs a cocktail that maximizes phage diversity to target multiple receptors, making it harder for bacteria to evolve simultaneous resistance. We demonstrated the utility of PhagePickr on two understudied species and the ESKAPE pathogens, a group of multidrug-resistant bacteria responsible for the majority of deaths associated with antibiotic resistance worldwide. The tool identified both well-characterized therapeutic phages and novel candidates, and is designed to scale as databases expand. Our approach represents a key step toward the rational design of evolution-proof phage cocktails for clinical use.