Journal
NATURE REVIEWS MATERIALS
Volume 7, Issue 12, Pages 953-973Publisher
NATURE PORTFOLIO
DOI: 10.1038/s41578-022-00464-7
Keywords
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Funding
- Australian government (ARC DECRA) [DE170100021]
- Melbourne Centre for Nanofabrication (MCN) in the Victorian Node of the Australian National Fabrication Facility (ANFF)
- ANFF-Vic Tech Ambassador Program for Deakin University
- National Natural Science Foundation of China [32171399]
- National Key R&D Program of China [2021YFF1200700, 2021YFA0911100]
- Hong Kong Centre for Cerebro-cardiovascular Health Engineering - Innovation and Technology Commission of Hong Kong
- European Research Council starting grant BRAIN-ACT [949478]
- European Research Council starting grant ENBION [759577]
- UK Department for Business, Energy, and Industrial Strategy through the National Measurement System (NMS project, Bioelectronics integrated multifunctional physiological measurement platform)
- EPSRC Industrial CASE 2020 [20000128]
- Singapore Ministry of Education (MOE) [RG112/20, NGF-2021-10-026, MOET32020-0001]
- Singapore National Research Foundation [NRF2019-NRF-ISF003-3292]
- Human Frontier Science Program [RGY0088/2021]
- NTU start-up grant
- Australian Research Council [IC170100016, IC190100026]
- Deakin's School of Medicine
- Deakin's Institute of Frontier Materials
- European Research Council (ERC) [759577, 949478] Funding Source: European Research Council (ERC)
- Australian Research Council [IC190100026, IC170100016] Funding Source: Australian Research Council
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The design of a vertical nanoprobe biointerface determines its ability to interrogate and control cells, enabling advances in drug delivery, intracellular sampling and sensing, biophysical interaction, and bioelectronics.
Biointerfaces mediate safe and efficient cell manipulation, which is essential for biomedical innovations in advanced therapies and diagnostics. The biointerface established by vertical nanoprobes - arrays of vertical high-aspect-ratio nanostructures - has emerged as a simple, controllable and powerful tool for interrogating and manipulating cells. Vertical nanoprobes have substantially improved our ability to control and characterize the intracellular environment, guide biophysical stimuli with nanoscale precision to defined cell compartments, stimulate and record the electrical activity of cells, and transport hard-to-deliver drugs. These capabilities are enabling substantial advances in bioelectronics, spatiotemporally resolved molecular diagnostics, and cell and gene therapy - all underpinned by the design versatility of the nanoprobe biointerface. This Review discusses how the design of a vertical nanoprobe biointerface determines its ability to interrogate and control a cell. Vertical nanoprobes are high-aspect-ratio nanomaterials used to manipulate and interrogate cells with high spatiotemporal resolution and limited perturbation. This Review discusses the design principles to establish effective nanoprobe biointerfaces for drug delivery, intracellular sampling and sensing, biophysical interaction and bioelectronics.
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