Integration of Micro and Nanotechnologies for Multiplexed High-Throughput Infectious Disease Detection

Klostranec, Jesse

19 January 2009

This thesis presents the development and optimization of a high-throughput fluorescence microbead based approach for multiplexed, large scale medical diagnostics of biological fluids. Specifically, different sizes of semiconductor nanocrystals, called quantum dots, are infused into polystyrene microspheres, yielding a set of spectrally unique optical barcodes. The surface of these barcodes are then used for sandwich assays with target molecules and fluorophore-conjugated detection antibodies, changing the optical spectra of beads that have associated with (or captured) biomolecular targets. These assayed microbeads are analyzed at a single bead level in a high-throughput manner using an electrokinetic microfluidic system and laser induced fluorescence. Optical signals collected by solid state photodetectors are then processed using novel signal processing algorithms. This document will discuss developments made in each area of the platform as well as optimization of the platform for improved future performance.

Nanotechnology

Infectious Disease Diagnostics

Microfluidics

Multiplexed Detection

0541

Integration of Micro and Nanotechnologies for Multiplexed High-Throughput Infectious Disease Detection

Klostranec, Jesse

19 January 2009

This thesis presents the development and optimization of a high-throughput fluorescence microbead based approach for multiplexed, large scale medical diagnostics of biological fluids. Specifically, different sizes of semiconductor nanocrystals, called quantum dots, are infused into polystyrene microspheres, yielding a set of spectrally unique optical barcodes. The surface of these barcodes are then used for sandwich assays with target molecules and fluorophore-conjugated detection antibodies, changing the optical spectra of beads that have associated with (or captured) biomolecular targets. These assayed microbeads are analyzed at a single bead level in a high-throughput manner using an electrokinetic microfluidic system and laser induced fluorescence. Optical signals collected by solid state photodetectors are then processed using novel signal processing algorithms. This document will discuss developments made in each area of the platform as well as optimization of the platform for improved future performance.

Nanotechnology

Infectious Disease Diagnostics

Microfluidics

Multiplexed Detection

0541

Isoniazid resistance levels of Mycobacterium tuberculosis can largely be predicted by high-confidence resistance-conferring mutations.

Lempens, P., Meehan, Conor J., Vandelannoote, K., Fissette, K., de Rijk, P., Van Deun, A., Rigouts, L., de Jong, B.C.

16 September 2019

Yes / The majority of Mycobacterium tuberculosis isolates resistant to isoniazid harbour a mutation in katG. Since these mutations cause a wide range of minimum inhibitory concentrations (MICs), largely below the serum level reached with higher dosing (15 mg/L upon 15–20 mg/kg), the drug might still remain partly active in presence of a katG mutation. We therefore investigated which genetic mutations predict the level of phenotypic isoniazid resistance in clinical M. tuberculosis isolates. To this end, the association between known and unknown isoniazid resistance-conferring mutations in whole genome sequences, and the isoniazid MICs of 176 isolates was examined. We found mostly moderate-level resistance characterized by a mode of 6.4 mg/L for the very common katG Ser315Thr mutation, and always very high MICs (≥19.2 mg/L) for the combination of katG Ser315Thr and inhA c-15t. Contrary to common belief, isolates harbouring inhA c-15t alone, partly also showed moderate-level resistance, particularly when combined with inhA Ser94Ala. No overt association between low-confidence or unknown mutations, except in katG, and isoniazid resistance (level) was found. Except for the rare katG deletion, line probe assay is thus not sufficiently accurate to predict the level of isoniazid resistance for a single mutation in katG or inhA. / European Research Council (Starting Grant INTERRUPTB 311725 to CM, LR and BdJ), The Damien Foundation

Antimicrobial resistance

Bacterial genomics

Genetic association study

Infectious-disease diagnostics

Pathogens

Whole genome sequencing of Mycobacterium tuberculosis: current standards and open issues

Meehan, Conor J., Goig, G.A., Kohl, T.A., Verboven, L., Dippenaar, A., Ezewudo, M., Farhat, M.R., Guthrie, J.L., Laukens, K., Miotto, P., Ofori-Anyinam, B., Dreyer, V., Supply, P., Suresh, A., Utpatel, C., van Soolingen, D., Zhou, Y., Ashton, P.M., Brites, D., Cabibbe, A.M., de Jong, B.C., de Vos, M., Menardo, F., Gagneux, S., Gao, Q., Heupink, T.H., Liu, Q., Loiseau, C., Rigouts, L., Rodwell, T.C., Tagliani, E., Walker, T.M., Warren, R.M., Zhao, Y., Zignol, M., Schito, M., Gardy, J., Cirillo, D.M., Niemann, S., Comas, I., Van Rie, A.

16 September 2019

No / Whole genome sequencing (WGS) of Mycobacterium tuberculosis has rapidly progressed from a research tool to a clinical application for the diagnosis and management of tuberculosis and in public health surveillance. This development has been facilitated by drastic drops in cost, advances in technology and concerted efforts to translate sequencing data into actionable information. There is, however, a risk that, in the absence of a consensus and international standards, the widespread use of WGS technology may result in data and processes that lack harmonization, comparability and validation. In this Review, we outline the current landscape of WGS pipelines and applications, and set out best practices for M. tuberculosis WGS, including standards for bioinformatics pipelines, curated repositories of resistance-causing variants, phylogenetic analyses, quality control and standardized reporting. / European Research Council grant (INTERRUPTB; no. 311725), European Research Council grant (TB-ACCELERATE; no. 638553), Foundation for Innovative New Diagnostics, German Center for Infection Research (DZIF), Deutsche Forschungsgemeinschaft (German Research Foundation) under Germany’s Excellence Strategy (EXC 22167–390884018), FWO Odysseus G0F8316N, US National Institutes of Health BD2K K01 (MRF ES026835), Agence Nationale de la Recherche (ANR-16-CD35-0009)

Antimicrobial resistance

Bacteria

Bacterial genetics

Clinical microbiology

Communication and replication

Clinical microbiology

Infectious-disease diagnostics

Pathogens

Policy and public health in microbiology

Standards

Tuberculosis

Whole genome amplification