| Autor: |
Nightingale, Adrian M., Leong, Chi Leng, Burnish, Rachel A., Hassan, Sammer-ul, Zhang, Yu, Clough, Geraldine F., Boutelle, Martyn G., Voegeli, David, Niu, Xize |
| Zdroj: |
Nature Communications; 6/21/2019, Vol. 10 Issue 1, pN.PAG-N.PAG, 1p |
| Abstrakt: |
Knowing how biomarker levels vary within biological fluids over time can produce valuable insight into tissue physiology and pathology, and could inform personalised clinical treatment. We describe here a wearable sensor for monitoring biomolecule levels that combines continuous fluid sampling with in situ analysis using wet-chemical assays (with the specific assay interchangeable depending on the target biomolecule). The microfluidic device employs a droplet flow regime to maximise the temporal response of the device, using a screw-driven push-pull peristaltic micropump to robustly produce nanolitre-sized droplets. The fully integrated sensor is contained within a small (palm-sized) footprint, is fully autonomous, and features high measurement frequency (a measurement every few seconds) meaning deviations from steady-state levels are quickly detected. We demonstrate how the sensor can track perturbed glucose and lactate levels in dermal tissue with results in close agreement with standard off-line analysis and consistent with changes in peripheral blood levels. Continuous real-time measurement of biomarker levels in body fluids offers many exciting possibilities. Here, the authors develop an integrated wearable droplet microfluidic sensor that combines continuous sampling of tissue fluid with in situ analysis using wet-chemical assays. [ABSTRACT FROM AUTHOR] |
| Databáze: |
Complementary Index |
| Externí odkaz: |
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