Photoelectrocatalysis: Principles, nanoemitter applications and routes to bio-inspired systems
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2010-06-11
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An overview on processes that are relevant in light-induced fuel generation, such as water photoelectrolysis or carbon dioxide reduction, is given. Considered processes encompass the photophysics of light absorption, excitation energy transfer to catalytically active sites and interfacial reactions at the catalyst/solution phase boundary. The two major routes envisaged for realization of photoelectrocatalytic systems, e.g. bio-inspired single photon catalysis and multiple photon inorganic or hybrid tandem cells, are outlined. For development of efficient tandem cell structures that are based on non-oxidic semiconductors, stabilization strategies are presented. Physical surface passivation is described using the recently introduced nanoemitter concept which is also applicable in photovoltaic (solid state or electrochemical) solar cells and first results with p-Si and p-InP thin films are presented. Solar-to-hydrogen efficiencies reach 12.1% for homoepitaxial InP thin films covered with Rh nanoislands. In the pursuit to develop biologically inspired systems, enzyme adsorption onto electrochemically nanostructured silicon surfaces is presented and tapping mode atomic force microscopy images of heterodimeric enzymes are shown. An outlook towards future envisaged systems is given. © 2010 The Royal Society of Chemistry.
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Lewerenz, HJ, C Heine, K Skorupska, N Szabo, T Hannappel, T Vo-Dinh, SA Campbell, HW Klemm, et al. (2010). Photoelectrocatalysis: Principles, nanoemitter applications and routes to bio-inspired systems. Energy and Environmental Science, 3(6). pp. 748–760. 10.1039/b915922n Retrieved from https://hdl.handle.net/10161/4115.
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Tuan Vo-Dinh
Dr. Tuan Vo-Dinh is R. Eugene and Susie E. Goodson Distinguished Professor of Biomedical Engineering, Professor of Chemistry, and Director of The Fitzpatrick Institute for Photonics.
Dr. Vo-Dinh’s research activities and interests involve biophotonics, nanophotonics, plasmonics, laser-excited luminescence spectroscopy, room temperature phosphorimetry, synchronous luminescence spectroscopy, and surface-enhanced Raman spectroscopy for multi-modality bioimaging, and theranostics (diagnostics and therapy) of diseases such as cancer and infectious diseases.
We have pioneered the development of a new generation of gene biosensing probes using surface-enhanced Raman scattering (SERS) detection with “Molecular Sentinels” and Plasmonic Coupling Interference (PCI) molecular probes for multiplex and label-free detection of nucleic acid biomarkers (DNA, mRNA, microRNA) in early detection of a wide variety of diseases.
In genomic and precision medicine, nucleic acid-based molecular diagnosis is of paramount importance with many advantages such as high specificity, high sensitivity, serotyping capability, and mutation detection. Using SERS-based plasmonic nanobiosensors and nanochips, we are developing novel nucleic acid detection methods that can be integrated into lab-on-a-chip systems for point-of-care diagnosis (e.g., breast, GI cancer) and global health applications (e.g., detection of malaria and dengue).
In bioimaging, we are developing a novel multifunctional gold nanostar (GNS) probe for use in multi-modality bioimaging in pre-operative scans with PET, MRI and CT, intraoperative margin delineation with optical imaging, SERS and two-photon luminescence (TPL). The GNS can be used also for cancer treatment with plasmonics enhanced photothermal therapy (PTT), thus providing an excellent platform for seamless diagnostics and therapy (i.e., theranostics). Preclinical studies have shown its great potential for cancer diagnostics and therapeutics for future clinical translation.
For fundamental studies, various nanobiosensors are being developed for monitoring intracellular parameters (e.g., pH) and biomolecular processes (e.g., apoptosis, caspases), opening the possibility for fundamental molecular biological research as well as biomedical applications (e.g., drug discovery) at the single cell level in a systems biology approach. For point of care diagnostics, nanoprobes and nanochips with highly multiplex SERS detection and imaging use artificial intelligence and machine learning for data analysis.
Our research activities in immunotherapy involve unique plasmonics-active gold “nanostars.” These star-shaped nanobodies made of gold work like “lightning rods,” concentrating the electromagnetic energy at their tips and allowing them to capture photon energy more efficiently when irradiated by laser light. Teaming with medical collaborators, we have developed a novel cancer treatment modality, called synergistic immuno photothermal nanotherapy (SYMPHONY), which combines immune-checkpoint inhibition and gold nanostar–mediated photothermal immunotherapy that can unleash the immunotherapeutic efficacy of checkpoint inhibitors. This combination treatment can eradicate the primary tumors as well as distant “untreated” tumors, and induce immunologic memory like a “anti-cancer vaccine” effect in murine model.
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