We report a high-throughput platform for delivering large cargo into 100,000 cells in 1 min. An array of micro-cavitation bubbles explode in response to laser pulsing, forming pores in adjacent cell membranes, and immediately thereafter, pressurized flows drive slow diffusing cargo through these pores into cells. The platform delivers large cargo including bacteria, enzymes, antibodies, and nanoparticles into diverse cell types with high efficiency and cell viability. We used this platform to explore the intracellular lifestyle of Francisella novicida and discovered that the iglC gene is unexpectedly required for intracellular replication even after phagosome escape into the cell cytosol.
Modeling studies suggest that clustered structural plasticity of dendritic spines is an efficient mechanism of information storage in cortical circuits. However, why new clustered spines occur in specific locations and how their formation relates to learning and memory (L&M) remain unclear. Using in vivo two-photon microscopy, we track spine dynamics in retrosplenial cortex before, during, and after two forms of episodic-like learning and find that spine turnover before learning predicts future L&M performance, as well as the localization and rates of spine clustering. Consistent with the idea that these measures are causally related, a genetic manipulation that enhances spine turnover also enhances both L&M and spine clustering. Biophysically inspired modeling suggests turnover increases clustering, network sparsity, and memory capacity. These results support a hotspot model where spine turnover is the driver for localization of clustered spine formation, which serves to modulate network function, thus influencing storage capacity and L&M.
Flexible neural probes have been pursued previously to minimize the mechanical mismatch between soft neural tissues and implants and thereby improve long-term performance. However, difficulties with insertion of such probes deep into the brain severely restricts their utility. We describe a solution to this problem using gallium (Ga) in probe construction, taking advantage of the solid-to-liquid phase change of the metal at body temperature and probe shape deformation to provide temperature-dependent control of stiffness over 5 orders of magnitude. Probes in the stiff state were successfully inserted 2 cm-deep into agarose gel "brain phantoms" and into rat brains under cooled conditions where, upon Ga melting, they became ultra soft, flexible, and stretchable *
Efficient intracellular
delivery of biomolecules into cells that
grow in suspension is of great interest for biomedical research, such
as for applications in cancer immunotherapy. Although tremendous effort
has been expended, it remains challenging for existing transfer platforms
to deliver materials efficiently into suspension cells. Here, we demonstrate
a high-efficiency photothermal delivery approach for suspension cells
using sharp nanoscale metal-coated tips positioned at the edge of
microwells, which provide controllable membrane disruption for each
cell in an array. Self-aligned microfabrication generates a uniform
microwell array with three-dimensional nanoscale metallic sharp tip
structures. Suspension cells self-position by gravity within each
microwell in direct contact with eight sharp tips, where laser-induced
cavitation bubbles generate transient pores in the cell membrane to
facilitate intracellular delivery of extracellular cargo. A range
of cargo sizes were tested on this platform using Ramos suspension
B cells with an efficiency of >84% for Calcein green (0.6 kDa)
and
>45% for FITC-dextran (2000 kDa), with retained viability of >96%
and a throughput of >100 000 cells delivered per minute.
The
bacterial enzyme β-lactamase (29 kDa) was delivered into Ramos
B cells and retained its biological activity, whereas a green fluorescence
protein expression plasmid was delivered into Ramos B cells with a
transfection efficiency of >58%, and a viability of >89% achieved.
A novel manufacturing approach to fabricate liquid metal‐based, multifunctional microcapillary pipettes able to provide electrodes with high electrical conductivity for high‐frequency electrical stimulation and measurement is proposed. 4D single cell manipulation is realized by applying multifrequency, multiamplitude, and multiphase electrical signals to the microelectrodes near the pipette tip to create 3D dielectrophoretic trap and 1D electrorotation, simultaneously. Functions such as single cell trapping, patterning, transfer, and rotation are accomplished. Cell viability and multiday proliferation characterization has confirmed the biocompatibility of this approach. This is a simple, low‐cost, and fast fabrication process that requires no cleanroom and photolithography step to manufacture 3D microelectrodes and microchannels for easy access to a wide user base for broad applications.
We report a simple approach to the production of carbon fiber‐based amperometric microbiosensors for selective detection of hydrogen peroxide (H2O2), which was achieved by electrometallization of carbon fiber microelectrodes (CFMs) by electrodeposition of Pt nanoparticles. The Pt‐carbon hybrid sensing interface provided a sensitivity of 7711±587 μA ⋅ mM−1 ⋅ cm−2, a detection limit of 0.53±0.16 μM (S/N=3), a linear range of 0.8 μM–8.6 mM, and a response time of <2 sec. The morphologies of the Pt nanoparticle‐modified CFMs were characterized by scanning electron microscopy. To achieve selectivity, permseletive layers, polyphenylenediamine (PPD) and Nafion, were deposited resulting in exclusion of the anionic and cationic interferents, ascorbic acid and dopamine, respectively, at their physiologically relevant concentrations. The resultant sensors displayed a sensitivity to hydrogen peroxide of 1381±72 μA ⋅ mM−1 ⋅ cm−2, and a detection limit of 0.86±0.19 μM (S/N=3). This simple and rapid metallization method converts carbon fiber microelectrodes, which are readily accessible, to microscale Pt electrodes in 2 min, providing a platform for oxidase‐based amperometric biosensors with improved spatial resolution over more commonly used platinum electrode array microprobes.
A plasmonic micropillar platform with self-organized gold nanospheres is reported for the precision cell traction force measurement across a large field-of-view (FOV). Gold nanospheres were implanted into the tips of polymer micropillars by annealing gold microdisks with nanosecond laser pulses. Each gold nanosphere is physically anchored in the center of a pillar tip and serves as a strong, point-source-like light scattering center for each micropillar. This allows a micropillar to be clearly observed and precisely tracked even under a low magnification objective lens for the concurrent and precision measurement across a large FOV. A spatial resolution of 30 nm for the pillar deflection measurement has been accomplished on this platform with a 20× objective lens.
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