Tim J Sloan1,2,3, James C Turton2,1, Jess Tyson2, Alison Musgrove4, Vicki M Fleming1, Michelle M Lister1, Matthew W Loose2, R Elizabeth Sockett2, Mathew Diggle1, Frances L Game4,5, William Jeffcoate4. 1. 2Department of Clinical Microbiology, Queen's Medical Centre, Nottingham University Hospitals NHS Trust, Nottingham, UK. 2. 1School of Life Sciences, University of Nottingham, Nottingham, UK. 3. 3Path Links Pathology, Northern Lincolnshire and Goole NHS Foundation Trust, Lincolnshire, UK. 4. 4Foot Ulcer Trials Unit, Department of Diabetes and Endocrinology, Nottingham University Hospitals NHS Trust, Nottingham, UK. 5. 5Department of Diabetes and Endocrinology, Derby Teaching Hospitals NHS Foundation Trust, Derby, UK.
Abstract
PURPOSE: While some micro-organisms, such as Staphylococcus aureus, are clearly implicated in causing tissue damage in diabetic foot ulcers (DFUs), our knowledge of the contribution of the entire microbiome to clinical outcomes is limited. We profiled the microbiome of a longitudinal sample series of 28 people with diabetes and DFUs of the heel in an attempt to better characterize the relationship between healing, infection and the microbiome. METHODOLOGY: In total, 237 samples were analysed from 28 DFUs, collected at fortnightly intervals for 6 months or until healing. Microbiome profiles were generated by 16S rRNA gene sequence analysis, supplemented by targeted nanopore sequencing.Result/Key findings. DFUs which failed to heal during the study period (20/28, 71.4 %) were more likely to be persistently colonized with a heterogeneous community of micro-organisms including anaerobes and Enterobacteriaceae (log-likelihood ratio 9.56, P=0.008). During clinically apparent infection, a reduction in the diversity of micro-organisms in a DFU was often observed due to expansion of one or two taxa, with recovery in diversity at resolution. Modelling of the predicted species interactions in a single DFU with high diversity indicated that networks of metabolic interactions may exist that contribute to the formation of stable communities. CONCLUSION: Longitudinal profiling is an essential tool for improving our understanding of the microbiology of chronic wounds, as community dynamics associated with clinical events can only be identified by examining changes over multiple time points. The development of complex communities, particularly involving Enterobacteriaceae and strict anaerobes, may be contributing to poor outcomes in DFUs and requires further investigation.
RCT Entities:
PURPOSE: While some micro-organisms, such as Staphylococcus aureus, are clearly implicated in causing tissue damage in diabetic foot ulcers (DFUs), our knowledge of the contribution of the entire microbiome to clinical outcomes is limited. We profiled the microbiome of a longitudinal sample series of 28 people with diabetes and DFUs of the heel in an attempt to better characterize the relationship between healing, infection and the microbiome. METHODOLOGY: In total, 237 samples were analysed from 28 DFUs, collected at fortnightly intervals for 6 months or until healing. Microbiome profiles were generated by 16S rRNA gene sequence analysis, supplemented by targeted nanopore sequencing.Result/Key findings. DFUs which failed to heal during the study period (20/28, 71.4 %) were more likely to be persistently colonized with a heterogeneous community of micro-organisms including anaerobes and Enterobacteriaceae (log-likelihood ratio 9.56, P=0.008). During clinically apparent infection, a reduction in the diversity of micro-organisms in a DFU was often observed due to expansion of one or two taxa, with recovery in diversity at resolution. Modelling of the predicted species interactions in a single DFU with high diversity indicated that networks of metabolic interactions may exist that contribute to the formation of stable communities. CONCLUSION: Longitudinal profiling is an essential tool for improving our understanding of the microbiology of chronic wounds, as community dynamics associated with clinical events can only be identified by examining changes over multiple time points. The development of complex communities, particularly involving Enterobacteriaceae and strict anaerobes, may be contributing to poor outcomes in DFUs and requires further investigation.
Authors: Neal R Barshes; Nicholas J Clark; Deeksha Bidare; J H Dudenhoeffer; Cezarina Mindru; Maria C Rodriguez-Barradas Journal: Open Forum Infect Dis Date: 2022-09-15 Impact factor: 4.423
Authors: Craig D Tipton; Randall D Wolcott; Nicholas E Sanford; Clint Miller; Gita Pathak; Talisa K Silzer; Jie Sun; Derek Fleming; Kendra P Rumbaugh; Todd D Little; Nicole Phillips; Caleb D Phillips Journal: PLoS Pathog Date: 2020-06-18 Impact factor: 6.823
Authors: Jun Jie Wong; Foo Kiong Ho; Pei Yi Choo; Kelvin K L Chong; Chee Meng Benjamin Ho; Ramesh Neelakandan; Damien Keogh; Timothy Barkham; John Chen; Chuan Fa Liu; Kimberly A Kline Journal: PLoS Pathog Date: 2022-09-06 Impact factor: 7.464
Authors: J Z Alex Cheong; Chad J Johnson; Hanxiao Wan; Aiping Liu; John F Kernien; Angela L F Gibson; Jeniel E Nett; Lindsay R Kalan Journal: ISME J Date: 2021-02-08 Impact factor: 10.302
Authors: Kyung R Min; Adriana Galvis; Katherine L Baquerizo Nole; Rohita Sinha; Jennifer Clarke; Robert S Kirsner; Dragana Ajdic Journal: PLoS One Date: 2020-01-24 Impact factor: 3.240