Modelling the effectiveness of surveillance based on metagenomics in detecting, monitoring, and forecasting antimicrobial resistance in livestock production under economic constraints

Department of Veterinary and Animal Sciences

Modelling the effectiveness of surveillance based on metagenomics in detecting, monitoring, and forecasting antimicrobial resistance in livestock production under economic constraints

Research output: Contribution to journal › Journal article › Research › peer-review

Standard

Modelling the effectiveness of surveillance based on metagenomics in detecting, monitoring, and forecasting antimicrobial resistance in livestock production under economic constraints. / Apenteng, Ofosuhene O.; Aarestrup, Frank M.; Vigre, Håkan.

In: Scientific Reports, Vol. 13, 20410, 2023.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Apenteng, OO, Aarestrup, FM & Vigre, H 2023, 'Modelling the effectiveness of surveillance based on metagenomics in detecting, monitoring, and forecasting antimicrobial resistance in livestock production under economic constraints', Scientific Reports, vol. 13, 20410. https://doi.org/10.1038/s41598-023-47754-w

APA

Apenteng, O. O., Aarestrup, F. M., & Vigre, H. (2023). Modelling the effectiveness of surveillance based on metagenomics in detecting, monitoring, and forecasting antimicrobial resistance in livestock production under economic constraints. Scientific Reports, 13, [20410]. https://doi.org/10.1038/s41598-023-47754-w

Vancouver

Apenteng OO, Aarestrup FM, Vigre H. Modelling the effectiveness of surveillance based on metagenomics in detecting, monitoring, and forecasting antimicrobial resistance in livestock production under economic constraints. Scientific Reports. 2023;13. 20410. https://doi.org/10.1038/s41598-023-47754-w

Author

Apenteng, Ofosuhene O. ; Aarestrup, Frank M. ; Vigre, Håkan. / Modelling the effectiveness of surveillance based on metagenomics in detecting, monitoring, and forecasting antimicrobial resistance in livestock production under economic constraints. In: Scientific Reports. 2023 ; Vol. 13.

Bibtex

@article{05a75795f15d40c08cd80029606f9bda,

title = "Modelling the effectiveness of surveillance based on metagenomics in detecting, monitoring, and forecasting antimicrobial resistance in livestock production under economic constraints",

abstract = "Current surveillance of antimicrobial resistance (AMR) is mostly based on testing indicator bacteria using minimum inhibitory concentration (MIC) panels. Metagenomics has the potential to identify all known antimicrobial resistant genes (ARGs) in complex samples and thereby detect changes in the occurrence earlier. Here, we simulate the results of an AMR surveillance program based on metagenomics in the Danish pig population. We modelled both an increase in the occurrence of ARGs and an introduction of a new ARG in a few farms and the subsequent spread to the entire population. To make the simulation realistic, the total cost of the surveillance was constrained, and the sampling schedule was set at one pool per month with 5, 20, 50, or 100 samples. Our simulations demonstrate that a pool of 20-50 samples and a sequencing depth of 250 million fragments resulted in the shortest time to detection in both scenarios, with a time delay to detection of change of [Formula: see text]15 months in all scenarios. Compared with culture-based surveillance, our simulation indicates that there are neither significant reductions nor increases in time to detect a change using metagenomics. The benefit of metagenomics is that it is possible to monitor all known resistance in one sampling and laboratory procedure in contrast to the current monitoring that is based on the phenotypic characterisation of selected indicator bacterial species. Therefore, overall changes in AMR in a population will be detected earlier using metagenomics due to the fact that the resistance gene does not have to be transferred to and expressed by an indicator bacteria before it is possible to detect.",

keywords = "Animals, Swine, Anti-Bacterial Agents/pharmacology, Livestock, Drug Resistance, Bacterial/genetics, Bacteria/genetics, Microbial Sensitivity Tests, Metagenomics/methods",

author = "Apenteng, {Ofosuhene O.} and Aarestrup, {Frank M.} and H{\aa}kan Vigre",

note = "{\textcopyright} 2023. The Author(s).",

year = "2023",

doi = "10.1038/s41598-023-47754-w",

language = "English",

volume = "13",

journal = "Scientific Reports",

issn = "2045-2322",

publisher = "nature publishing group",

}

RIS

TY - JOUR

T1 - Modelling the effectiveness of surveillance based on metagenomics in detecting, monitoring, and forecasting antimicrobial resistance in livestock production under economic constraints

AU - Apenteng, Ofosuhene O.

AU - Aarestrup, Frank M.

AU - Vigre, Håkan

PY - 2023

Y1 - 2023

N2 - Current surveillance of antimicrobial resistance (AMR) is mostly based on testing indicator bacteria using minimum inhibitory concentration (MIC) panels. Metagenomics has the potential to identify all known antimicrobial resistant genes (ARGs) in complex samples and thereby detect changes in the occurrence earlier. Here, we simulate the results of an AMR surveillance program based on metagenomics in the Danish pig population. We modelled both an increase in the occurrence of ARGs and an introduction of a new ARG in a few farms and the subsequent spread to the entire population. To make the simulation realistic, the total cost of the surveillance was constrained, and the sampling schedule was set at one pool per month with 5, 20, 50, or 100 samples. Our simulations demonstrate that a pool of 20-50 samples and a sequencing depth of 250 million fragments resulted in the shortest time to detection in both scenarios, with a time delay to detection of change of [Formula: see text]15 months in all scenarios. Compared with culture-based surveillance, our simulation indicates that there are neither significant reductions nor increases in time to detect a change using metagenomics. The benefit of metagenomics is that it is possible to monitor all known resistance in one sampling and laboratory procedure in contrast to the current monitoring that is based on the phenotypic characterisation of selected indicator bacterial species. Therefore, overall changes in AMR in a population will be detected earlier using metagenomics due to the fact that the resistance gene does not have to be transferred to and expressed by an indicator bacteria before it is possible to detect.

AB - Current surveillance of antimicrobial resistance (AMR) is mostly based on testing indicator bacteria using minimum inhibitory concentration (MIC) panels. Metagenomics has the potential to identify all known antimicrobial resistant genes (ARGs) in complex samples and thereby detect changes in the occurrence earlier. Here, we simulate the results of an AMR surveillance program based on metagenomics in the Danish pig population. We modelled both an increase in the occurrence of ARGs and an introduction of a new ARG in a few farms and the subsequent spread to the entire population. To make the simulation realistic, the total cost of the surveillance was constrained, and the sampling schedule was set at one pool per month with 5, 20, 50, or 100 samples. Our simulations demonstrate that a pool of 20-50 samples and a sequencing depth of 250 million fragments resulted in the shortest time to detection in both scenarios, with a time delay to detection of change of [Formula: see text]15 months in all scenarios. Compared with culture-based surveillance, our simulation indicates that there are neither significant reductions nor increases in time to detect a change using metagenomics. The benefit of metagenomics is that it is possible to monitor all known resistance in one sampling and laboratory procedure in contrast to the current monitoring that is based on the phenotypic characterisation of selected indicator bacterial species. Therefore, overall changes in AMR in a population will be detected earlier using metagenomics due to the fact that the resistance gene does not have to be transferred to and expressed by an indicator bacteria before it is possible to detect.

KW - Animals

KW - Swine

KW - Anti-Bacterial Agents/pharmacology

KW - Livestock

KW - Drug Resistance, Bacterial/genetics

KW - Bacteria/genetics

KW - Microbial Sensitivity Tests

KW - Metagenomics/methods

U2 - 10.1038/s41598-023-47754-w

DO - 10.1038/s41598-023-47754-w

M3 - Journal article

C2 - 37990114

VL - 13

JO - Scientific Reports

JF - Scientific Reports

SN - 2045-2322

M1 - 20410

ER -

ID: 374054526