A review of the recent advances in antimicrobial coatings for urinary catheters

[Display omitted] More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the treatment of 15–25% of hospitalized patients. Among other purposes, urinary catheters are primarily used for draining urine after surgeries and fo...

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Published in	Acta biomaterialia Vol. 50; pp. 20 - 40
Main Authors	Singha, Priyadarshini, Locklin, Jason, Handa, Hitesh
Format	Journal Article
Language	English
Published	England Elsevier Ltd 01.03.2017 Elsevier BV
Subjects	Abundance Animals Anti-Bacterial Agents - chemistry Anti-Bacterial Agents - therapeutic use Antifouling Antifouling coatings Antifouling substances Antiinfectives and antibacterials Antimicrobial agents Antimicrobial coatings Bacteria Bacteriuria Berries Biocides Biocompatibility Biomaterials Bladder Catheter-associated urinary tract infections Catheterization Catheters Coated Materials, Biocompatible - therapeutic use Coating Coatings Colonization Fabrication Hospitals Humans Intubation Materials selection Medical instruments Microorganisms Nosocomial infection Patients Urinary bladder Urinary catheter coatings Urinary Catheters Urinary incontinence Urinary Incontinence - surgery Urinary tract Urinary tract diseases Urinary tract infections Urinary Tract Infections - etiology Urinary Tract Infections - prevention & control Urine Urogenital system food and drug administration serial plate transfer test extracellular polymeric substances Biocides Catheter-associated urinary tract infections 4-amide-piperidine-C12 catheter-associated urinary tract infection(s) 5,5-dimethylhydantoin S-nitroso-N-acetyl-dl-penicillamine polyurethane allyl glycidyl ether Healthcare Infection Control Practices Advisory Committee fluorescein isothiocyanate X-ray photoelectron spectroscopy scanning electron microscopy polyethylene glycol nitric oxide enoyl-acyl carrier protein reductase polydimethylsiloxane Antifouling coatings ethylene vinyl acetate atomic force microscopy Urinary catheters attenuated total reflectance-Fourier transform infrared spectroscopy Antimicrobial coatings colony forming unit trimethoprim sulfamethoxazole polyvinyl chlorine polytetrafluoroethylene Urinary catheter coatings S-nitrosoglutathione urinary tract infection antimicrobial peptides bovine serum albumin
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Abstract	[Display omitted] More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the treatment of 15–25% of hospitalized patients. Among other purposes, urinary catheters are primarily used for draining urine after surgeries and for urinary incontinence. During catheter-associated urinary tract infections, bacteria travel up to the bladder and cause infection. A major cause of catheter-associated urinary tract infection is attributed to the use of non-ideal materials in the fabrication of urinary catheters. Such materials allow for the colonization of microorganisms, leading to bacteriuria and infection, depending on the severity of symptoms. The ideal urinary catheter is made out of materials that are biocompatible, antimicrobial, and antifouling. Although an abundance of research has been conducted over the last forty-five years on the subject, the ideal biomaterial, especially for long-term catheterization of more than a month, has yet to be developed. The aim of this review is to highlight the recent advances (over the past 10years) in developing antimicrobial materials for urinary catheters and to outline future requirements and prospects that guide catheter materials selection and design. This review article intends to provide an expansive insight into the various antimicrobial agents currently being researched for urinary catheter coatings. According to CDC, approximately 75% of urinary tract infections are caused by urinary catheters and 15–25% of hospitalized patients undergo catheterization. In addition to these alarming statistics, the increasing cost and health related complications associated with catheter associated UTIs make the research for antimicrobial urinary catheter coatings even more pertinent. This review provides a comprehensive summary of the history, the latest progress in development of the coatings and a brief conjecture on what the future entails for each of the antimicrobial agents discussed.
AbstractList	More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the treatment of 15-25% of hospitalized patients. Among other purposes, urinary catheters are primarily used for draining urine after surgeries and for urinary incontinence. During catheter-associated urinary tract infections, bacteria travel up to the bladder and cause infection. A major cause of catheter-associated urinary tract infection is attributed to the use of non-ideal materials in the fabrication of urinary catheters. Such materials allow for the colonization of microorganisms, leading to bacteriuria and infection, depending on the severity of symptoms. The ideal urinary catheter is made out of materials that are biocompatible, antimicrobial, and antifouling. Although an abundance of research has been conducted over the last forty-five years on the subject, the ideal biomaterial, especially for long-term catheterization of more than a month, has yet to be developed. The aim of this review is to highlight the recent advances (over the past 10years) in developing antimicrobial materials for urinary catheters and to outline future requirements and prospects that guide catheter materials selection and design.More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the treatment of 15-25% of hospitalized patients. Among other purposes, urinary catheters are primarily used for draining urine after surgeries and for urinary incontinence. During catheter-associated urinary tract infections, bacteria travel up to the bladder and cause infection. A major cause of catheter-associated urinary tract infection is attributed to the use of non-ideal materials in the fabrication of urinary catheters. Such materials allow for the colonization of microorganisms, leading to bacteriuria and infection, depending on the severity of symptoms. The ideal urinary catheter is made out of materials that are biocompatible, antimicrobial, and antifouling. Although an abundance of research has been conducted over the last forty-five years on the subject, the ideal biomaterial, especially for long-term catheterization of more than a month, has yet to be developed. The aim of this review is to highlight the recent advances (over the past 10years) in developing antimicrobial materials for urinary catheters and to outline future requirements and prospects that guide catheter materials selection and design.This review article intends to provide an expansive insight into the various antimicrobial agents currently being researched for urinary catheter coatings. According to CDC, approximately 75% of urinary tract infections are caused by urinary catheters and 15-25% of hospitalized patients undergo catheterization. In addition to these alarming statistics, the increasing cost and health related complications associated with catheter associated UTIs make the research for antimicrobial urinary catheter coatings even more pertinent. This review provides a comprehensive summary of the history, the latest progress in development of the coatings and a brief conjecture on what the future entails for each of the antimicrobial agents discussed.STATEMENT OF SIGNIFICANCEThis review article intends to provide an expansive insight into the various antimicrobial agents currently being researched for urinary catheter coatings. According to CDC, approximately 75% of urinary tract infections are caused by urinary catheters and 15-25% of hospitalized patients undergo catheterization. In addition to these alarming statistics, the increasing cost and health related complications associated with catheter associated UTIs make the research for antimicrobial urinary catheter coatings even more pertinent. This review provides a comprehensive summary of the history, the latest progress in development of the coatings and a brief conjecture on what the future entails for each of the antimicrobial agents discussed. More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the treatment of 15-25% of hospitalized patients. Among other purposes, urinary catheters are primarily used for draining urine after surgeries and for urinary incontinence. During catheter-associated urinary tract infections, bacteria travel up to the bladder and cause infection. A major cause of catheter-associated urinary tract infection is attributed to the use of non-ideal materials in the fabrication of urinary catheters. Such materials allow for the colonization of microorganisms, leading to bacteriuria and infection, depending on the severity of symptoms. The ideal urinary catheter is made out of materials that are biocompatible, antimicrobial, and antifouling. Although an abundance of research has been conducted over the last forty-five years on the subject, the ideal biomaterial, especially for long-term catheterization of more than a month, has yet to be developed. The aim of this review is to highlight the recent advances (over the past 10years) in developing antimicrobial materials for urinary catheters and to outline future requirements and prospects that guide catheter materials selection and design. This review article intends to provide an expansive insight into the various antimicrobial agents currently being researched for urinary catheter coatings. According to CDC, approximately 75% of urinary tract infections are caused by urinary catheters and 15-25% of hospitalized patients undergo catheterization. In addition to these alarming statistics, the increasing cost and health related complications associated with catheter associated UTIs make the research for antimicrobial urinary catheter coatings even more pertinent. This review provides a comprehensive summary of the history, the latest progress in development of the coatings and a brief conjecture on what the future entails for each of the antimicrobial agents discussed. [Display omitted] More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the treatment of 15–25% of hospitalized patients. Among other purposes, urinary catheters are primarily used for draining urine after surgeries and for urinary incontinence. During catheter-associated urinary tract infections, bacteria travel up to the bladder and cause infection. A major cause of catheter-associated urinary tract infection is attributed to the use of non-ideal materials in the fabrication of urinary catheters. Such materials allow for the colonization of microorganisms, leading to bacteriuria and infection, depending on the severity of symptoms. The ideal urinary catheter is made out of materials that are biocompatible, antimicrobial, and antifouling. Although an abundance of research has been conducted over the last forty-five years on the subject, the ideal biomaterial, especially for long-term catheterization of more than a month, has yet to be developed. The aim of this review is to highlight the recent advances (over the past 10years) in developing antimicrobial materials for urinary catheters and to outline future requirements and prospects that guide catheter materials selection and design. This review article intends to provide an expansive insight into the various antimicrobial agents currently being researched for urinary catheter coatings. According to CDC, approximately 75% of urinary tract infections are caused by urinary catheters and 15–25% of hospitalized patients undergo catheterization. In addition to these alarming statistics, the increasing cost and health related complications associated with catheter associated UTIs make the research for antimicrobial urinary catheter coatings even more pertinent. This review provides a comprehensive summary of the history, the latest progress in development of the coatings and a brief conjecture on what the future entails for each of the antimicrobial agents discussed. More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the treatment of 15-25% of hospitalized patients. Among other purposes, urinary catheters are primarily used for draining urine after surgeries and for urinary incontinence. During catheter-associated urinary tract infections, bacteria travel up to the bladder and cause infection. A major cause of catheter-associated urinary tract infection is attributed to the use of non-ideal materials in the fabrication of urinary catheters. Such materials allow for the colonization of microorganisms, leading to bacteriuria and infection, depending on the severity of symptoms. The ideal urinary catheter is made out of materials that are biocompatible, antimicrobial, and antifouling. Although an abundance of research has been conducted over the last forty-five years on the subject, the ideal biomaterial, especially for long-term catheterization of more than a month, has yet to be developed. The aim of this review is to highlight the recent advances (over the past 10 years) in developing antimicrobial materials for urinary catheters and to outline future requirements and prospects that guide catheter materials selection and design. This review article intends to provide an expansive insight into the various antimicrobial agents currently being researched for urinary catheter coatings. According to CDC, approximately 75% of urinary tract infections are caused by urinary catheters and 15-25% of hospitalized patients undergo catheterization. In addition to these alarming statistics, the increasing cost and health related complications associated with catheter associated UTIs make the research for antimicrobial urinary catheter coatings even more pertinent. This review provides a comprehensive summary of the history, the latest progress in development of the coatings and a brief conjecture on what the future entails for each of the antimicrobial agents discussed. More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the treatment of 15–25% of hospitalized patients. Among other purposes, urinary catheters are primarily used for draining urine after surgeries and for urinary incontinence. During catheter-associated urinary tract infections, bacteria travel up to the bladder and cause infection. A major cause of catheter-associated urinary tract infection is attributed to the use of non-ideal materials in the fabrication of urinary catheters. Such materials allow for the colonization of microorganisms, leading to bacteriuria and infection, depending on the severity of symptoms. The ideal urinary catheter is made out of materials that are biocompatible, antimicrobial, and antifouling. Although an abundance of research has been conducted over the last forty-five years on the subject, the ideal biomaterial, especially for long-term catheterization of more than a month, has yet to be developed. The aim of this review is to highlight the recent advances (over the past 10 years) in developing antimicrobial materials for urinary catheters and to outline future requirements and prospects that guide catheter materials selection and design.
Author	Locklin, Jason Singha, Priyadarshini Handa, Hitesh
AuthorAffiliation	b Department of Chemistry, University of Georgia, Athens, GA USA a College of Engineering, University of Georgia, Athens, GA USA
AuthorAffiliation_xml	– name: b Department of Chemistry, University of Georgia, Athens, GA USA – name: a College of Engineering, University of Georgia, Athens, GA USA
Author_xml	– sequence: 1 givenname: Priyadarshini surname: Singha fullname: Singha, Priyadarshini organization: School of Materials, Chemical and Biomedical Engineering, College of Engineering, University of Georgia, Athens, GA, USA – sequence: 2 givenname: Jason surname: Locklin fullname: Locklin, Jason email: jlocklin@uga.edu organization: School of Materials, Chemical and Biomedical Engineering, College of Engineering, University of Georgia, Athens, GA, USA – sequence: 3 givenname: Hitesh surname: Handa fullname: Handa, Hitesh email: hhanda@uga.edu organization: School of Materials, Chemical and Biomedical Engineering, College of Engineering, University of Georgia, Athens, GA, USA
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/27916738$$D View this record in MEDLINE/PubMed
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Snippet	[Display omitted] More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the... More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the treatment of 15-25% of... More than 75% of hospital-acquired or nosocomial urinary tract infections are initiated by urinary catheters, which are used during the treatment of 15–25% of...
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SubjectTerms	Abundance Animals Anti-Bacterial Agents - chemistry Anti-Bacterial Agents - therapeutic use Antifouling Antifouling coatings Antifouling substances Antiinfectives and antibacterials Antimicrobial agents Antimicrobial coatings Bacteria Bacteriuria Berries Biocides Biocompatibility Biomaterials Bladder Catheter-associated urinary tract infections Catheterization Catheters Coated Materials, Biocompatible - therapeutic use Coating Coatings Colonization Fabrication Hospitals Humans Intubation Materials selection Medical instruments Microorganisms Nosocomial infection Patients Urinary bladder Urinary catheter coatings Urinary Catheters Urinary incontinence Urinary Incontinence - surgery Urinary tract Urinary tract diseases Urinary tract infections Urinary Tract Infections - etiology Urinary Tract Infections - prevention & control Urine Urogenital system
Title	A review of the recent advances in antimicrobial coatings for urinary catheters
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