TY - JOUR
T1 - Antibacterial action of visible 405-nm light for bacterial reduction in blood plasma
AU - Stewart, Caitlin Fiona
AU - Ralston, Heather
AU - MacPherson, Ruairidh
AU - Wilson, Mark
AU - MacGregor, Scott
AU - Atreya, Chintamani
AU - Maclean, Michelle
PY - 2022/5/27
Y1 - 2022/5/27
N2 - The introduction of risk prevention measures, such as blood screening and donor deferrals have dramatically reduced the incidence of transfusion-transmitted viral infections. Nevertheless, bacterial contamination of blood transfusion products remains a concern to patient health, and a range of pathogen reduction technologies have been developed to reduce this risk. Visible violet-blue light, in the region of 405-nm, has recently demonstrated potential for in situ treatment of ex vivo stored plasma and platelet products, without the need for additional photosensitizers. This study assessed the broad-spectrum efficacy of 405-nm light against a range of bacteria implicated in transfusion-transmitted infections: Staphylococcus aureus, Staphylococcus epidermidis, Bacillus cereus, Escherichia coli, Pseudomonas aeruginosa, Acinetobacter baumannii, Klebsiella pneumoniaeandYersinia enterocolitica. Plasma was seeded with clinically-relevant low-level bacterial contamination (102-103CFUmL-1) and exposed to a 405-nm light dose of 360 Jcm-2 (1-hr at 100mWcm-2) using a small-scale exposure system. Broad spectrum antibacterial efficacy was observed, with 99.0 – 100% inactivation achieved for all bacterial species tested. Bacterial inactivation tests were then scaled-up to expose large volumes of prebagged plasma seeded with S. aureusat ~103 CFUmL-1, to 22mWcm-2 405-nm light, under agitation, (≤396 Jcm-2). Successful bacterial inactivation was observed using the large-scale exposure system, with a dose of 238 Jcm-2 (3-hr at ~22mWcm-2) achieving complete (3.5-log10) reductions in prebagged bacterial-seeded plasma (P=0.001). Results from this study support further development of visible 405-nm light technology as a bactericidal tool for application in transfusion medicine. This abstract reflects the views of the author and should not be construed to represent FDA’s views or policies.
AB - The introduction of risk prevention measures, such as blood screening and donor deferrals have dramatically reduced the incidence of transfusion-transmitted viral infections. Nevertheless, bacterial contamination of blood transfusion products remains a concern to patient health, and a range of pathogen reduction technologies have been developed to reduce this risk. Visible violet-blue light, in the region of 405-nm, has recently demonstrated potential for in situ treatment of ex vivo stored plasma and platelet products, without the need for additional photosensitizers. This study assessed the broad-spectrum efficacy of 405-nm light against a range of bacteria implicated in transfusion-transmitted infections: Staphylococcus aureus, Staphylococcus epidermidis, Bacillus cereus, Escherichia coli, Pseudomonas aeruginosa, Acinetobacter baumannii, Klebsiella pneumoniaeandYersinia enterocolitica. Plasma was seeded with clinically-relevant low-level bacterial contamination (102-103CFUmL-1) and exposed to a 405-nm light dose of 360 Jcm-2 (1-hr at 100mWcm-2) using a small-scale exposure system. Broad spectrum antibacterial efficacy was observed, with 99.0 – 100% inactivation achieved for all bacterial species tested. Bacterial inactivation tests were then scaled-up to expose large volumes of prebagged plasma seeded with S. aureusat ~103 CFUmL-1, to 22mWcm-2 405-nm light, under agitation, (≤396 Jcm-2). Successful bacterial inactivation was observed using the large-scale exposure system, with a dose of 238 Jcm-2 (3-hr at ~22mWcm-2) achieving complete (3.5-log10) reductions in prebagged bacterial-seeded plasma (P=0.001). Results from this study support further development of visible 405-nm light technology as a bactericidal tool for application in transfusion medicine. This abstract reflects the views of the author and should not be construed to represent FDA’s views or policies.
KW - bacterial reduction
KW - blood plasma
KW - visible violet-blue light
U2 - 10.1099/acmi.ac2021.po0227
DO - 10.1099/acmi.ac2021.po0227
M3 - Conference Contribution
SN - 2516-8290
VL - 4
JO - Access Microbiology
JF - Access Microbiology
IS - 5
T2 - Microbiology Society Annual Conference 2021
Y2 - 26 April 2021 through 30 April 2021
ER -