Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-10T10:47:13.322Z Has data issue: false hasContentIssue false
  • English
  • Français

Personalized infection prevention and control: a concept whose time has arrived

Published online by Cambridge University Press:  08 September 2023

Alessia Savoldi Open the ORCID record for Alessia Savoldi [Opens in a new window] ,
Nico T. Mutters Open the ORCID record for Nico T. Mutters [Opens in a new window]  and
Evelina Tacconelli Open the ORCID record for Evelina Tacconelli [Opens in a new window]
Alessia Savoldi
Affiliation:
Division of Infectious Diseases, Department of Diagnostics and Public Health, University of Verona, Verona, Italy
Nico T. Mutters
Affiliation:
Institute for Hygiene and Public Health, University Hospital Bonn, Bonn, Germany
Evelina Tacconelli*
Affiliation:
Division of Infectious Diseases, Department of Diagnostics and Public Health, University of Verona, Verona, Italy ESCMID European Committee on Infection Prevention and Control (EUCIC), Basel, Switzerland
*
Corresponding author: Evelina Tacconelli; Email: evelina.tacconelli@univr.it

Abstract

Personalized medicine has been progressively implemented in several diagnostic and therapeutic patients’ algorithms, based on the common assumption that tailoring interventions, practices, and/or therapies to individual patients’ clinical, biological, epidemiological, and genetic characteristics would optimize their effectiveness and reduce adverse effects. The potential benefit of the precision medicine approach has been recently considered for possible implementation in the field of infection prevention and control. The commentary explores available evidence and assesses possible future scenarios where, through advanced modeling approaches, we would be able to provide personalized prediction algorithms identifying at-risk patients who deserve the implementation of tailored preventive measures.

Keywords

hospital transmissioninfection preventionpersonalized medicine
Type
Commentary
Information
Antimicrobial Stewardship & Healthcare Epidemiology , Volume 3 , Issue 1 , 2023 , e151
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Society for Healthcare Epidemiology of America

Introduction

Personalized medicine, also referred to as precision medicine, has been progressively implemented in several diagnostic and therapeutic patients’ algorithms for noncommunicable diseases, based on the common assumption that tailoring interventions, practices, and/or therapies to individual patients’ clinical, biological, epidemiological, and genetic characteristics would optimize their effectiveness. Reference Denny and Collins1,Reference Hampel, Gao and Cummings2 Oncology represents the medical area where this concept has been incorporated on a wide scale into treatment and prevention programs in the context of primarily three determinants: lifestyle, comorbidities, and genomic and epigenomic profiling. Reference Moran, Martinez-Cardús, Boussios and Esteller3 In the area of infectious diseases, a recent example of personalized medicine application emerged during the Coronavirus Disease 19 pandemic, where clinical data coupled with genomics and molecular technologies were utilized for identifying etiologic agents, developing diagnostics and treatments, and creating vaccine candidates. Reference Denny and Collins1

The potential benefit of the precision approach has been recently considered for possible implementation in the field of infection prevention and control (IPC). Reference Gonzalo, Harris and Tacconelli4,Reference Gastmeier5 The ideal goal of precision IPC would be to implement a measure, or a bundle of measures, specifically in selected individuals considered at-risk on the basis of patient-related (epidemiology, comorbidities, omics profile) and pathogen-related (molecular resistance mechanism and/or virulence factors) determinants (Figure 1). The ability to precisely quantify the risk of horizontal transmission at individual-level in colonized and/or infected patients would lead not only to an optimized effectiveness of the implemented measure but possibly also to a decrease of adverse effects (such as reduced contact with healthcare workers, organizational constraints due to single room isolation) of hospital personnel’s workload, and of hospital costs. In parallel, the reduced workload could lead to an improvement in adherence to interventions and, therefore, a potential further reduction in horizontal transmission among patients and/or healthcare workers.

Figure 1. Integration of multiple data sources to personalize the implementation of infection prevention and control measures.

Current applications of personalized IPC

The process toward personalization of IPC is, nevertheless, extremely challenging in terms of feasibility, sustainability, transferability, and quality of the available evidence. The issue of how to properly apply precision medicine to IPC has recently arisen from new evidence, which questions and reconsiders the universal use of contact precautions (CP) for inpatients with multi-drug resistant microorganisms (MDROs) outside the outbreak context. Reference Rump, Timen, Verweij and Hulscher6 The most advanced discussion focuses on patients colonized or infected by extended β lactamase-producing Enterobacterales (ESBL-E). The currently available IPC guidelines strongly recommend the implementation of CP in endemic settings for inpatients colonized or infected with ESBL-E, Reference Tacconelli, Cataldo and Dancer7,8 except for Escherichia coli because of insufficient data allowing to draw evidence-based conclusions in high-risk patients. Reference Tacconelli, Cataldo and Dancer7 More recently, a 2023 scoping review of nine studies (one of them with randomized design Reference Maechler, Schwab and Hansen9 ) confirmed no benefit in implementing contact over standard precautions in hospital transmission of ESBL-E. Reference Hagiya and Otsuka10 These results should, however, be cautiously interpreted in terms of generalizability due to high heterogeneity of colonization pressure among wards, healthcare workload organization, hospital structure, IPC compliance, and population type. For example, no studies targeted high-risk settings, while almost all studies were conducted in endemic areas where the community reservoir, especially for E. coli, was probably the primary driver for transmission. Reference Tschudin-Sutter, Lucet, Mutters, Tacconelli, Zahar and Harbarth11

The availability of information related to the colonization status and, therefore, the decision as to whether to apply IPC strategies or not is strictly connected to the screening policies (e.g., timing, and universal vs targeted populations). The topic is not straightforward considering that the screening has not only an IPC value but also a clinical relevance providing essential information to drive, for example, the empiric antibiotic therapy in high-risk populations Reference Micozzi, Gentile and Santilli12 or surgical peri-operative antibiotic prophylaxis (PAP). The majority of post-operative surgical site infections (SSIs) are indeed caused by endogenous flora and several observational studies confirmed a link between infection and patients’ own microbiota. Reference Filson, Gaskins and Martin13 The 2023 ESCMID/EUCIC guidelines indicate to implement rectal screening for identifying ESBL-E carriers before colorectal and liver transplant surgery to adapt PAP accordingly. Reference Righi, Mutters and Guirao14 The recommendation is conditional and the evidence supporting its benefit in reducing post-operative SSIs is represented by few studies with several inherent limitations such as non-randomized design, sample size, and selection and ascertainment biases. Reference Apisarnthanarak, Kondo and Mingmalairak15Reference Hoffman, Lellouche and Nutman19 However, the translation of this recommendation on personalized PAP into clinical practice raises several difficult IPC questions related to pre-surgical workload organization, laboratory capability, and related costs. In this case, PAP personalization at patient-level should possibly consider the intestinal microbiome composition, which, in the case of patients undergoing colorectal surgery, has been shown to be extremely dynamic over time. Reference Koliarakis, Athanasakis and Sgantzos20 The gut microbiome can mediate colonization resistance against several enteric pathogens through several mechanisms such as nutrient competition, production of antimicrobial compounds, support of gut barrier integrity, bacteriophage deployment, and interaction with the immune system. Reference Ducarmon, Zwittink, Hornung, van Schaik, Young and Kuijper21 According to recent multi-omics microbiome analyses, asymptomatic gut microbiome-mediated colonization resistance is less relevant for ESBL E.coli compared to other MDROs and, therefore, microbiome-based interventions might not be the way forward to prevent intestinal colonization of ESBL E.coli. Reference Ducarmon, Zwittink and Willems22

The future state

A futuristic personalized implementation of IPC measures might be based on longitudinal sampling of a patient’s evolving microbiome to capture pathogens likely to be transmitted and enables for a dynamic modulation of IPC across the whole hospital stay, with possible positive consequences also from an antimicrobial stewardship perspective. The evaluation of the microbiome might be of particular importance for decision-making in case of hematological patients and those undergoing colorectal or transplant surgery, in which the colonization with ESBL-E usually precedes the infection.

As stated above, the precision approach at a microbiological level should also consider if the presence of specific resistance mechanisms such as AmpC β lactamase vs OXA-48 carbapenemase would have a role in IPC measure selection, and the evidence here is extremely poor. From a microbiological point of view, resistance mechanisms such as OXA-48-like carbapenemases are often found on the same plasmid that can also be transferred to other bacterial species, although there are multiple plasmids able to carry these mechanisms of resistance. For example, OXA-181 and OXA-232 are associated with ISEcp1, Tn2013 on ColE2, and IncX3 types of plasmids; therefore, the clonal dissemination plays a minor role in the spread of OXA-48-like carbapenemases. Reference Pitout, Peirano, Kock, Strydom and Matsumura23,Reference Hamprecht, Sommer and Willmann24 Furthermore, the virulence properties implicated in the effectiveness of transmission are not necessarily associated with the plasmid carrying the resistance gene. Reference Hamprecht, Sommer and Willmann24 On the basis of these considerations, several factors may impact the risk of transmission and infection and the identification of the resistance mechanism alone cannot be currently considered as sufficient to drive IPC selection.

With increasing genetic data about resistance and virulence genes that are detected in certain endemically found plasmids or associated with certain high-risk clones (e.g., Klebsiella pneumoniae sequence type 147 [ST147], ST307, ST15, and ST14 and E. coli ST38 and ST410), it can be hypothesized that personalized IPC based on molecular identification of high-risk plasmids or clones will be possible in the future. To achieve this goal, sequencing data should be made publicly and freely available within datasets to ensure continuing identification of newly appearing clones and plasmids. Reference Galata, Fehlmann, Backes and Keller25

If we could improve the identification of patients’ and pathogens’ genomic characteristics associated with increased transmission risk in the presence of specific comorbidities and/or treatments, such as chemotherapy in hematological diseases, we would probably start building a completely different approach to IPC. Although patient-level risk factors, in particular for acquiring an MDRO colonization, have been clearly identified in literature (e.g., previous antibiotic treatment, indwelling devices, international travel), if considered individually, these show suboptimal accuracy in identifying patients at higher risk for transmitting or acquiring bacteria colonization during hospitalization. In a Dutch tertiary hospital, a universal risk assessment based on the use of a six-item questionnaire upon hospital admission underestimated the number of MDROs carriers deserving pre-emptive isolation, leading to a total of 1436 days of unjustified isolation in case of false positive assessment. Reference Van Hout, Bruijning-Verhagen, Blok, Troelstra and Bonten26 An increase in prediction accuracy might be pursueded by applying new complex analyses such as machine learning, which may allow the quantification of the impact of each contributing factor within the whole patient risk profile. A multidimensional model, including patient-level data (number of antibiotics, combinations, and sequential usage), was translated into a simple ranking of antibiotics associated with ESBL-E colonization in 12 mixed wards across three European hospitals. The study found that monotherapy with a cephalosporin ranked first in promoting carriage, but the ranking strongly changed in accordance with the sequential usage of antibiotics in the previous 30 days. Reference Tacconelli, Górska and De Angelis27

Data driven predictive models or algorithms for risk assessment developed using machine learning or similar analytic approaches, which integrate both evidence-based, patient-, pathogen-, and facility-level data might increase the prediction accuracy and help clinicians’ decision-making in identifying which patient is at-risk and deserves, therefore, tailored IPC (isolation, screening) or antibiotic treatment or prophylaxis. At same time, omic-based techniques may be employed, in a context of translational medicine, in defining the individual microbiota composition and targeting personalized IPC measures accordingly. To maximize its performance, the individualized approach would require to combine outputs from clinical studies, modeling statistics, cost analysis, and basic research.

We urgently need the implementation of patient-centered IPC measures based on a precision approach; we are definitely not there yet but supporting translation research in the IPC field and integration with machine learning data-driven models could bring us closer to this objective than expected.

Acknowledgments

We acknowledge Anna Gorska and Ruth Joanna Davis for editorial support.

Financial support

The commentary is not financially supported.

Competing interests

All authors report no conflicts of interest relevant to this article.

References

Denny, JC, Collins, FS. Precision medicine in 2030— seven ways to transform healthcare. Cell 2021;184:14151419.CrossRefGoogle ScholarPubMed
Hampel, H, Gao, P, Cummings, J, et al. The foundation and architecture of precision medicine in neurology and psychiatry. Trends Neurosci 2023;46:176198.CrossRefGoogle ScholarPubMed
Moran, S, Martinez-Cardús, A, Boussios, S, Esteller, M. Precision medicine based on epigenomics: the paradigm of carcinoma of unknown primary. Nat Rev Clin Oncol 2017;14:682694 CrossRefGoogle ScholarPubMed
Gonzalo, B, Harris, AD, Tacconelli, E. Contact precautions for the control of epidemic pathogens: finding the middle path. Antimicrob Steward Healthc Epidemiol 2023;3:e57.Google Scholar
Gastmeier, P. From ‘one size fits all’ to personalized infection prevention. J Hosp Infect 2020;104:256260.CrossRefGoogle ScholarPubMed
Rump, B, Timen, A, Verweij, M, Hulscher, M. Experiences of carriers of multidrug-resistant organisms: a systematic review. Clin Microbiol Infect 2019;25:274279.CrossRefGoogle ScholarPubMed
Tacconelli, E, Cataldo, MA, Dancer, SJ, et al. ESCMID guidelines for the management of the infection control measures to reduce transmission of multidrug-resistant Gram-negative bacteria in hospitalized patients. Clin Microbiol Infect 2014;20:155.CrossRefGoogle ScholarPubMed
European Centre for Disease Prevention and Control (ECDC). Systematic review of the effectiveness of infection control measures to prevent the transmission of extended-spectrum beta-lactamase-producing Enterobacteriaceae through cross-border transfer of patients. https://www.ecdc.europa.eu/en/publications-data/systematic-review-effectiveness-infection-control-measures-prevent-transmission-0. Published December 2014. Accessed June 10, 2023.Google Scholar
Maechler, F, Schwab, F, Hansen, S, et al. Contact isolation vs standard precautions to decrease acquisition of extended-spectrum β-lactamase-producing Enterobacterales in non-critical care wards: a cluster-randomised crossover trial. Lancet Infect Dis 2020;20:575584.CrossRefGoogle Scholar
Hagiya, H, Otsuka, F. Increased evidence for no benefit of contact precautions in preventing extended-spectrum β-lactamases-producing Enterobacteriaceae: systematic scoping review. Am J Infect Control 2023;S0196-6553(23)00054-8.Google Scholar
Tschudin-Sutter, S, Lucet, JC, Mutters, NT, Tacconelli, E, Zahar, JR, Harbarth, S. Contact precautions for preventing nosocomial transmission of extended spectrum β lactamase-producing Escherichia Coli: a point/counterpoint review. Clin Infect Dis 2017;65:342347.CrossRefGoogle ScholarPubMed
Micozzi, A, Gentile, G, Santilli, S, et al. Reduced mortality from KPC-K. pneumoniae bloodstream infection in high-risk patients with hematological malignancies colonized by KPC-K.pneumoniae. BMC Infect Dis 2021;21:1079.Google ScholarPubMed
Filson, A, Gaskins, JT, Martin, RCG. A meta-analysis and systematic review of intraoperative bile cultures association with postoperative complications in pancreaticoduodenectomy. Surg 2023;173:12311239.CrossRefGoogle ScholarPubMed
Righi, E, Mutters, NT, Guirao, X, et al. ESCMID/EUCIC clinical practice guidelines on perioperative antibiotic prophylaxis in patients colonized by multidrug-resistant gram-negative bacteria before surgery. Clin Microbiol Infect 2023;29:463479.CrossRefGoogle ScholarPubMed
Apisarnthanarak, A, Kondo, S, Mingmalairak, C, et al. Outcomes of extended-spectrum beta-lactamases producing Enterobacteriaceae colonization among patients abdominal surgery patients. Infect Control Hosp Epidemiol 2019;40:1290e3.CrossRefGoogle Scholar
De Pastena, M, Paiella, S, Azzini, AM, et al. Antibiotic prophylaxis with piperacillin-tazobactam reduces postoperative infectious complication after pancreatic surgery: an interventional, non-randomized study. Surg Infect (Larchmt) 2021;22:536e42.CrossRefGoogle Scholar
Logre, E, Bert, F, Khoy-Ear, L, et al. Risk factors and impact of perioperative prophylaxis on the risk of extended spectrum beta-lactamase-producing Enterobacteriaceae-related infection among carriers following liver transplantation. Transplantation 2021;105:338e45.CrossRefGoogle Scholar
Nutman, A, Temkin, E, Harbarth, S, et al. Personalized ertapenem prophylaxis for carriers of extended-spectrum beta-lactamase-producing Enterobacteriaceae undergoing colorectal surgery. Clin Infect Dis 2020;70:1891e7.CrossRefGoogle Scholar
Hoffman, T, Lellouche, J, Nutman, A, et al. The effect of prophylaxis with ertapenem vs cefuroxime/metronidazole on intestinal carriage of carbapenem-resistant or third-generation cephalosporin-resistant Enterobacterales after colorectal surgery. Clin Microbiol Infect 2021;27:1481e7.CrossRefGoogle Scholar
Koliarakis, I, Athanasakis, E, Sgantzos, M, et al. Intestinal microbiota in colorectal cancer surgery. Cancers (Basel) 2020;12:3011.CrossRefGoogle Scholar
Ducarmon, QR, Zwittink, RD, Hornung, BVH, van Schaik, W, Young, VB, Kuijper, EJ. Gut microbiota and colonization resistance against bacterial enteric infection. Microbiol Mol Biol Rev 2019;83:e0000719 CrossRefGoogle ScholarPubMed
Ducarmon, QR, Zwittink, RD, Willems, RPJ, et al. Gut colonisation by extended-spectrum β-lactamase producing Escherichia coli and its association with the gut microbiome and metabolome in Dutch adults: a matched case-control study. Lancet Microbe 2022;3:e443e451 CrossRefGoogle ScholarPubMed
Pitout, JDD, Peirano, G, Kock, MM, Strydom, KA, Matsumura, Y. The global ascendency of OXA-48-type carbapenemases. Clin Microbiol Rev 2019;33:e0010219.CrossRefGoogle ScholarPubMed
Hamprecht, A, Sommer, J, Willmann, M, et al. Pathogenicity of clinical OXA-48 isolates and impact of the OXA-48 IncL plasmid on virulence and bacterial fitness. Front Microbiol 2019;10:2509.CrossRefGoogle ScholarPubMed
Galata, V, Fehlmann, T, Backes, C, Keller, A. PLSDB: a resource of complete bacterial plasmids. Nucleic Acids Res 2019;47:D195D202.CrossRefGoogle ScholarPubMed
Van Hout, D, Bruijning-Verhagen, PCJ, Blok, HEM, Troelstra, A, Bonten, MJM. Universal risk assessment upon hospital admission for screening of carriage with multidrug-resistant micro-organisms in a Dutch tertiary care centre. J Hosp Infect 2021;109:3239.CrossRefGoogle Scholar
Tacconelli, E, Górska, A, De Angelis, G, et al. Estimating the association between antibiotic exposure and colonization with extended-spectrum β-lactamase-producing Gram-negative bacteria using machine learning methods: a multicentre, prospective cohort study. Clin Microbiol Infect 2020;26:8794.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Integration of multiple data sources to personalize the implementation of infection prevention and control measures.