# | Title | Journal | Year | Citations |
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1 | INfrastructure for a PHAge REference Database: Identification of Large-Scale Biases in the Current Collection of Cultured Phage Genomes | Phage | 2021 | 121 |
2 | The Virulence Index: A Metric for Quantitative Analysis of Phage Virulence | Phage | 2020 | 49 |
3 | Isolation and Characterization of Klebsiella Phages for Phage Therapy | Phage | 2021 | 36 |
4 | A New High-Throughput Screening Method for Phages: Enabling Crude Isolation and Fast Identification of Diverse Phages with Therapeutic Potential | Phage | 2020 | 28 |
5 | Bacteriophages Could Be a Potential Game Changer in the Trajectory of Coronavirus Disease (COVID-19) | Phage | 2020 | 25 |
6 | Phage Annotation Guide: Guidelines for Assembly and High-Quality Annotation | Phage | 2021 | 24 |
7 | Host Range Expansion of Pseudomonas Virus LUZ7 Is Driven by a Conserved Tail Fiber Mutation | Phage | 2020 | 17 |
8 | Tailored Antibacterials and Innovative Laboratories for Phage (Φ) Research: Personalized Infectious Disease Medicine for the Most Vulnerable At-Risk Patients | Phage | 2020 | 17 |
9 | Phage Genome Annotation: Where to Begin and End | Phage | 2021 | 17 |
10 | From Trees to Clouds: PhageClouds for Fast Comparison of ∼640,000 Phage Genomic Sequences and Host-Centric Visualization Using Genomic Network Graphs | Phage | 2021 | 14 |
11 | Natural and Induced Antibodies Against Phages in Humans: Induction Kinetics and Immunogenicity for Structural Proteins of PB1-Related Phages | Phage | 2020 | 12 |
12 | How Broad Is Enough: The Host Range of Bacteriophages and Its Impact on the Agri-Food Sector | Phage | 2021 | 12 |
13 | Bacteriophage Therapy as a Potential Management Option for Surgical Wound Infections | Phage | 2020 | 11 |
14 | Phage Commander, an Application for Rapid Gene Identification in Bacteriophage Genomes Using Multiple Programs | Phage | 2021 | 11 |
15 | Presentation of Three Novel Tailed Phages Targeting Multiple Strains of Pseudomonas syringae | Phage | 2020 | 11 |
16 | The Application of Bacteriophage Diagnostics for Bacterial Pathogens in the Agricultural Supply Chain: From Farm-to-Fork | Phage | 2020 | 11 |
17 | A Dynamic Method for Broad-Spectrum Bacteriophage Cocktail Formulation Against Poultry-AssociatedSalmonella enterica | Phage | 2020 | 9 |
18 | Bacteriophages: Emerging Applications in Medicine, Food, and Biotechnology | Phage | 2020 | 9 |
19 | Building Better Bacteriophage with Biofoundries to Combat Antibiotic-Resistant Bacteria | Phage | 2020 | 8 |
20 | Rethinking Phage Ecology by Rooting it Within an Established Plant Framework | Phage | 2020 | 8 |
21 | Methods for Extraction and Detection of Pf Bacteriophage DNA from the Sputum of Patients with Cystic Fibrosis | Phage | 2020 | 8 |
22 | OnePetri: Accelerating Common Bacteriophage Petri Dish Assays with Computer Vision | Phage | 2021 | 8 |
23 | Isolation and Characterization of vB_PagP-SK1, a T7-Like Phage InfectingPantoea agglomerans | Phage | 2020 | 7 |
24 | Lytic Bacteriophages Against Bacterial Biofilms Formed by Multidrug-Resistant Pseudomonas aeruginosa, Escherichia coli, Klebsiella pneumoniae, and Staphylococcus aureus Isolated from Burn Wounds | Phage | 2021 | 7 |
25 | Pectobacterium Phage Jarilo Displays Broad Host Range and Represents a Novel Genus of Bacteriophages Within the Family Autographiviridae | Phage | 2020 | 7 |
26 | Virus-Like Particle: Evolving Meanings in Different Disciplines | Phage | 2021 | 6 |
27 | Further Considerations on How to Improve Phage Therapy Experimentation, Practice, and Reporting: Pharmacodynamics Perspectives | Phage | 2022 | 6 |
28 | Bacteriophages as Biocontrol Agents for Flavobacterium psychrophilum Biofilms and Rainbow Trout Infections | Phage | 2020 | 5 |
29 | Pathways to Phage Therapy Enlightenment, or Why I Have Become a Scientific Curmudgeon | Phage | 2022 | 5 |
30 | vHULK, a New Tool for Bacteriophage Host Prediction Based on Annotated Genomic Features and Neural Networks | Phage | 2022 | 5 |
31 | Bacteriophage-Mediated Reduction of Bacterial Speck on Tomato Seedlings | Phage | 2020 | 4 |
32 | Phage Therapies: Lessons (Not) Learned from the “Antibiotic Era” | Phage | 2022 | 4 |
33 | A Representative Collection of Commensal Extended-Spectrum- and AmpC-β-Lactamase-Producing Escherichia coli of Animal Origin for Phage Sensitivity Studies | Phage | 2023 | 4 |
34 | In Vitro Evolution to Increase the Titers of Difficult Bacteriophages: RAMP-UP Protocol | Phage | 2023 | 4 |
35 | Phage Therapy in the Management of Urinary Tract Infections: A Comprehensive Systematic Review | Phage | 2023 | 4 |
36 | Neat Science in a Messy World: The Global Impact of Human Behavior on Phage Therapy, Past and Present | Phage | 2020 | 3 |
37 | Set Phages to Kill: An Interview with Graham Hatfull, PhD | Phage | 2020 | 3 |
38 | Genome Sequence and Characterization of Coliphage vB_Eco_SLUR29 | Phage | 2020 | 3 |
39 | Analysis of Four New Enterococcus faecalis Phages and Modeling of a Hyaluronidase Catalytic Domain from Saphexavirus | Phage | 2021 | 3 |
40 | Evaluation of Phage Delivery Systems on Induced MotileAeromonasSepticemia inOreochromis niloticus | Phage | 2020 | 3 |
41 | Two New Dickeya dadantii Phages with Odd Growth Patterns Expand the Diversity of Phages Infecting Soft Rot Pectobacteriaceae | Phage | 2020 | 3 |
42 | Effectiveness of Bacteriophages Against Biofilm-Forming Shiga-ToxigenicEscherichia colion Leafy Greens and Cucumbers | Phage | 2020 | 3 |
43 | Using Phages to Reduce Salmonella Prevalence in Chicken Meat: A Systematic Review | Phage | 2022 | 3 |
44 | Activity of a Bacteriophage Cocktail to Control Salmonella Growth Ex Vivo in Avian, Porcine, and Human Epithelial Cell Cultures | Phage | 2023 | 3 |
45 | “Two Is Better Than One”: The Multifactorial Nature of Phage-Antibiotic Combinatorial Treatments Against ESKAPE-Induced Infections | Phage | 2023 | 3 |
46 | The Effect of Oxygen Availability on Bacteriophage Infection: A Review | Phage | 2021 | 2 |
47 | Genome Sequence and Characterization ofAcinetobacterPhage DMU1 | Phage | 2021 | 2 |
48 | Genome Sequence and Characterization of Lactobacillus casei Phage, vB_LcaM_Lbab1 Isolated from Raw Milk | Phage | 2021 | 2 |
49 | Isolation and Characterization of Novel Phages Targeting Xanthomonas oryzae: Culprit of Bacterial Leaf Blight Disease in Rice | Phage | 2021 | 2 |
50 | inPhocus: A Local Perspective on Phage-Based Biocontrol in Agriculture and Aquaculture in India | Phage | 2020 | 2 |