Chemical fingerprint of bacteriophages by infrared nano-spectroscopy

Bacteriophage (phages) are naturally occurring nanoscale antimicrobial agents that can self-replicate at infection sites and selectively eliminate pathogenic bacteria. Significant heterogeneity exists in phage properties such as morphology, protein and nucleic acid composition, subject to the strain...

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Published inAnalytica chimica acta Vol. 1355; p. 344026
Main Authors Cao, Yue, Khanal, Dipesh, Cernescu, Adrian, Chan, Hak Kim
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier B.V 15.06.2025
Subjects
AFM
Bacteriophage (phage)
Bacteriophages - chemistry
Nano-chemical mapping
Nanotechnology
Phage formulation
Phage stability
Pseudomonas aeruginosa
Spectrophotometry, Infrared - methods
Spectroscopy
Nano-chemical mapping
Spectroscopy
Bacteriophage (phage)
AFM
Pseudomonas aeruginosa
Phage stability
Phage formulation
Online AccessGet full text
ISSN0003-2670
1873-4324
1873-4324
DOI10.1016/j.aca.2025.344026

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Abstract Bacteriophage (phages) are naturally occurring nanoscale antimicrobial agents that can self-replicate at infection sites and selectively eliminate pathogenic bacteria. Significant heterogeneity exists in phage properties such as morphology, protein and nucleic acid composition, subject to the strain, state, and environment of the phage source. However, current techniques fall short in accurately mapping the chemical compositions of individual phages. A thorough understanding of this heterogeneity is essential to elucidate the difference between phage types and their stability, which may impact phages as effective therapeutic agents. We propose using scattering scanning near-field optical microscopy (s-SNOM) as an innovative method to map the chemical composition of phages at the nanoscale. The strength of this method lies in its label-free, ultra-high sensitivity that measures individual phage chemical heterogeneity. Additionally, s-SNOM is ideal for thermally sensitive phages, as it detects light scattered by nanoscale specimens without relying on thermal expansion. New insights from this method into phage chemical composition will profoundly impact our understanding of phage biology and optimise phage formulation for therapeutic use. [Display omitted] •Bacteriophages are nanoscale antimicrobial agents with selective bacterial targeting.•Significant heterogeneity exists in phage morphology and chemical composition.•s-SNOM provides a label-free mapping of phage chemical composition at the nanoscale.•Contributes to building a comprehensive reference library of phage chemical and morphological composition profiles.•Enable optimization of phage formulations, improving their stability and effectiveness as therapeutic agents.
AbstractList Bacteriophage (phages) are naturally occurring nanoscale antimicrobial agents that can self-replicate at infection sites and selectively eliminate pathogenic bacteria. Significant heterogeneity exists in phage properties such as morphology, protein and nucleic acid composition, subject to the strain, state, and environment of the phage source. However, current techniques fall short in accurately mapping the chemical compositions of individual phages. A thorough understanding of this heterogeneity is essential to elucidate the difference between phage types and their stability, which may impact phages as effective therapeutic agents. We propose using scattering scanning near-field optical microscopy (s-SNOM) as an innovative method to map the chemical composition of phages at the nanoscale. The strength of this method lies in its label-free, ultra-high sensitivity that measures individual phage chemical heterogeneity. Additionally, s-SNOM is ideal for thermally sensitive phages, as it detects light scattered by nanoscale specimens without relying on thermal expansion. New insights from this method into phage chemical composition will profoundly impact our understanding of phage biology and optimise phage formulation for therapeutic use.
Bacteriophage (phages) are naturally occurring nanoscale antimicrobial agents that can self-replicate at infection sites and selectively eliminate pathogenic bacteria. Significant heterogeneity exists in phage properties such as morphology, protein and nucleic acid composition, subject to the strain, state, and environment of the phage source. However, current techniques fall short in accurately mapping the chemical compositions of individual phages. A thorough understanding of this heterogeneity is essential to elucidate the difference between phage types and their stability, which may impact phages as effective therapeutic agents. We propose using scattering scanning near-field optical microscopy (s-SNOM) as an innovative method to map the chemical composition of phages at the nanoscale. The strength of this method lies in its label-free, ultra-high sensitivity that measures individual phage chemical heterogeneity. Additionally, s-SNOM is ideal for thermally sensitive phages, as it detects light scattered by nanoscale specimens without relying on thermal expansion. New insights from this method into phage chemical composition will profoundly impact our understanding of phage biology and optimise phage formulation for therapeutic use. [Display omitted] •Bacteriophages are nanoscale antimicrobial agents with selective bacterial targeting.•Significant heterogeneity exists in phage morphology and chemical composition.•s-SNOM provides a label-free mapping of phage chemical composition at the nanoscale.•Contributes to building a comprehensive reference library of phage chemical and morphological composition profiles.•Enable optimization of phage formulations, improving their stability and effectiveness as therapeutic agents.
Bacteriophage (phages) are naturally occurring nanoscale antimicrobial agents that can self-replicate at infection sites and selectively eliminate pathogenic bacteria. Significant heterogeneity exists in phage properties such as morphology, protein and nucleic acid composition, subject to the strain, state, and environment of the phage source. However, current techniques fall short in accurately mapping the chemical compositions of individual phages. A thorough understanding of this heterogeneity is essential to elucidate the difference between phage types and their stability, which may impact phages as effective therapeutic agents. We propose using scattering scanning near-field optical microscopy (s-SNOM) as an innovative method to map the chemical composition of phages at the nanoscale. The strength of this method lies in its label-free, ultra-high sensitivity that measures individual phage chemical heterogeneity. Additionally, s-SNOM is ideal for thermally sensitive phages, as it detects light scattered by nanoscale specimens without relying on thermal expansion. New insights from this method into phage chemical composition will profoundly impact our understanding of phage biology and optimise phage formulation for therapeutic use.Bacteriophage (phages) are naturally occurring nanoscale antimicrobial agents that can self-replicate at infection sites and selectively eliminate pathogenic bacteria. Significant heterogeneity exists in phage properties such as morphology, protein and nucleic acid composition, subject to the strain, state, and environment of the phage source. However, current techniques fall short in accurately mapping the chemical compositions of individual phages. A thorough understanding of this heterogeneity is essential to elucidate the difference between phage types and their stability, which may impact phages as effective therapeutic agents. We propose using scattering scanning near-field optical microscopy (s-SNOM) as an innovative method to map the chemical composition of phages at the nanoscale. The strength of this method lies in its label-free, ultra-high sensitivity that measures individual phage chemical heterogeneity. Additionally, s-SNOM is ideal for thermally sensitive phages, as it detects light scattered by nanoscale specimens without relying on thermal expansion. New insights from this method into phage chemical composition will profoundly impact our understanding of phage biology and optimise phage formulation for therapeutic use.
ArticleNumber 344026
Author Cernescu, Adrian
Khanal, Dipesh
Chan, Hak Kim
Cao, Yue
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  givenname: Hak Kim
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Keywords Nano-chemical mapping
Spectroscopy
Bacteriophage (phage)
AFM
Pseudomonas aeruginosa
Phage stability
Phage formulation
Language English
License This is an open access article under the CC BY license.
Copyright © 2025 The Authors. Published by Elsevier B.V. All rights reserved.
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Snippet Bacteriophage (phages) are naturally occurring nanoscale antimicrobial agents that can self-replicate at infection sites and selectively eliminate pathogenic...
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SubjectTerms AFM
Bacteriophage (phage)
Bacteriophages - chemistry
Nano-chemical mapping
Nanotechnology
Phage formulation
Phage stability
Pseudomonas aeruginosa
Spectrophotometry, Infrared - methods
Spectroscopy
Title Chemical fingerprint of bacteriophages by infrared nano-spectroscopy
URI https://dx.doi.org/10.1016/j.aca.2025.344026
https://www.ncbi.nlm.nih.gov/pubmed/40274323
https://www.proquest.com/docview/3194651412
Volume 1355
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