Dorota Wencel scite author profile

There is increasing interest in the use of nanoparticles (NPs) for biomedical applications. In particular, nanobiophotonic approaches using fluorescence offers the potential of high sensitivity and selectivity in applications such as cell imaging and intracellular sensing. In this review, we focus primarily on the use of fluorescent silica NPs for these applications and, in so doing, aim to enhance and complement the key recent review articles on these topics. We summarize the main synthetic approaches, namely the Stöber and microemulsion processes, and, in this context, we deal with issues in relation to both covalent and physical incorporation of different types of dyes in the particles. The important issue of NP functionalization for conjugation to biomolecules is discussed and strategies published in the recent literature are highlighted and evaluated. We cite recent examples of the use of fluorescent silica NPs for cell imaging in the areas of cancer, stem cell and infectious disease research, and we review the current literature on the use of silica NPs for intracellular sensing of oxygen, pH and ionic species. We include a short final section which seeks to identify the main challenges and obstacles in relation to the potential widespread use of these particles for in vivo diagnostics and therapeutics.

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Optical Sensor for Real‐Time pH Monitoring in Human Tissue

Wencel

Kaworek²,

Abel

et al. 2018

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This article reports on a fiber‐based ratiometric optical pH sensor for use in real‐time and continuous in vivo pH monitoring in human tissue. Stable hybrid sol–gel‐based pH sensing material is deposited on a highly flexible plastic optical fiber tip and integrated with excitation and detection electronics. The sensor is extensively tested in a laboratory environment before it is applied in vivo in a human model. The pH sensor performance in the laboratory environment outperforms the state‐of‐the‐art reported in the current literature. It exhibits the highest sensitivity in the physiological pH range, resolution of 0.0013 pH units, excellent sensor to sensor reproducibility, long‐term stability, short response time of <2 min, and drift of 0.003 pH units per 22 h. The sensor also exhibits promising performance in in vitro whole blood samples. In addition, human evaluations conducted under this project demonstrate successful short‐term deployment of this sensor in vivo.

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Prussian blue-based optical glucose biosensor in flow-injection analysis

Lenarczuk

Wencel

Głąb

et al. 2001

Analytica Chimica Acta

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Dorota Wencel

Optical Chemical pH Sensors

High performance optical ratiometric sol–gel-based pH sensor

Silica nanoparticles for cell imaging and intracellular sensing

Optical Sensor for Real‐Time pH Monitoring in Human Tissue

Prussian blue-based optical glucose biosensor in flow-injection analysis

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