101. Rapid detection of mobilized colistin resistance using a nucleic acid based lab-on-a-chip diagnostic system
- Author
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Nicolas Moser, Lenka Fisarova, Ivana Pennisi, Kenny Malpartida-Cardenas, Elita Jauneikaite, Alireza Abdolrasouli, Xavier Didelot, Frances Davies, A Boonyasiri, Alison Holmes, Ahmad Moniri, Frances Bolt, Jesus Rodriguez-Manzano, Pantelis Georgiou, Jonathan A. Otter, Imperial College Healthcare NHS Trust- BRC Funding, and National Institute for Health Research
- Subjects
0301 basic medicine ,Nucleic acid quantitation ,Science ,030106 microbiology ,Loop-mediated isothermal amplification ,Drug resistance ,Computational biology ,Article ,law.invention ,03 medical and health sciences ,Antibiotic resistance ,Bacterial Proteins ,law ,Lab-On-A-Chip Devices ,Nucleic Acids ,Drug Resistance, Bacterial ,Diagnosis ,medicine ,Humans ,Whole genome sequencing ,Multidisciplinary ,Bacteria ,Lab-on-a-chip ,Colistin ,Bacterial Infections ,QP ,Anti-Bacterial Agents ,QR ,030104 developmental biology ,Nucleic acid ,Medicine ,Infectious diseases ,Microbiology techniques ,medicine.drug - Abstract
The increasing prevalence of antimicrobial resistance is a serious threat to global public health. One of the most concerning trends is the rapid spread of Carbapenemase-Producing Organisms (CPO), where colistin has become the last-resort antibiotic treatment. The emergence of colistin resistance, including the spread of mobilized colistin resistance (mcr) genes, raises the possibility of untreatable bacterial infections and motivates the development of improved diagnostics for the detection of colistin-resistant organisms. This work demonstrates a rapid response for detecting the most recently reported mcr gene, mcr−9, using a portable and affordable lab-on-a-chip (LoC) platform, offering a promising alternative to conventional laboratory-based instruments such as real-time PCR (qPCR). The platform combines semiconductor technology, for non-optical real-time DNA sensing, with a smartphone application for data acquisition, visualization and cloud connectivity. This technology is enabled by using loop-mediated isothermal amplification (LAMP) as the chemistry for targeted DNA detection, by virtue of its high sensitivity, specificity, yield, and manageable temperature requirements. Here, we have developed the first LAMP assay for mcr−9 - showing high sensitivity (down to 100 genomic copies/reaction) and high specificity (no cross-reactivity with other mcr variants). This assay is demonstrated through supporting a hospital investigation where we analyzed nucleic acids extracted from 128 carbapenemase-producing bacteria isolated from clinical and screening samples and found that 41 carried mcr−9 (validated using whole genome sequencing). Average positive detection times were 6.58 ± 0.42 min when performing the experiments on a conventional qPCR instrument (n = 41). For validating the translation of the LAMP assay onto a LoC platform, a subset of the samples were tested (n = 20), showing average detection times of 6.83 ± 0.92 min for positive isolates (n = 14). All experiments detected mcr−9 in under 10 min, and both platforms showed no statistically significant difference (p-value > 0.05). When sample preparation and throughput capabilities are integrated within this LoC platform, the adoption of this technology for the rapid detection and surveillance of antimicrobial resistance genes will decrease the turnaround time for DNA detection and resistotyping, improving diagnostic capabilities, patient outcomes, and the management of infectious diseases.