Electrocatalysis of the four-electron
oxygen reduction reaction
(ORR) provides a promising approach for energy conversion, storage,
and oxygen monitoring. However, it is always accompanied by the reduction
of hydrogen peroxide (H2O2) on most employed
catalysts, which brings down the electrocatalytic selectivity. Here,
we report a single-atom Co–N4 electrocatalyst for
the four-electron ORR at an onset potential of 0.68 V (vs RHE) in
neutral media while with high H2O2 tolerance,
outperforming commercial Pt electrocatalysts. Electrochemical kinetic
analysis confirms that the Co–N4 catalytic sites
dominantly promote the direct four-electron pathway of the ORR rather
than the two sequential two-electron reduction pathways with H2O2 as the intermediate. Density functional theory
calculations reveal that H2O2 reduction is hampered
by the weak adsorption of H2O2 on the porphyrin-like
Co centers. This endows the electrocatalyst with improved resistance
to current interference from H2O2, enabling
highly selective O2 sensing as validated by the reliable
sensing performance in vivo. Our study demonstrates the intriguing
advantage of single-atom catalysts with high capacity for tailoring
metal–adsorbate interactions, broadening their applications
in environmental and life monitoring.
Various neuromodulation approaches have been employed to alter neuronal spiking activity and thus regulate brain functions and alleviate neurological disorders. Infrared neural stimulation (INS) could be a potential approach for neuromodulation because it requires no tissue contact and possesses a high spatial resolution. However, the risk of overheating and an unclear mechanism hamper its application. Here we show that midinfrared stimulation (MIRS) with a specific wavelength exerts nonthermal, long-distance, and reversible modulatory effects on ion channel activity, neuronal signaling, and sensorimotor behavior. Patch-clamp recording from mouse neocortical pyramidal cells revealed that MIRS readily provides gain control over spiking activities, inhibiting spiking responses to weak inputs but enhancing those to strong inputs. MIRS also shortens action potential (AP) waveforms by accelerating its repolarization, through an increase in voltage-gated K+ (but not Na+) currents. Molecular dynamics simulations further revealed that MIRS-induced resonance vibration of –C=O bonds at the K+ channel ion selectivity filter contributes to the K+ current increase. Importantly, these effects are readily reversible and independent of temperature increase. At the behavioral level in larval zebrafish, MIRS modulates startle responses by sharply increasing the slope of the sensorimotor input–output curve. Therefore, MIRS represents a promising neuromodulation approach suitable for clinical application.
Electrochemical sensing performance is often compromised by electrode biofouling (e.g., proteins nonspecific binding) in complex biological fluids; however, the design and construction of a robust biointerface remains a great challenge. Herein, inspired by nature, we demonstrate a robust polydopamine‐engineered biointerfacing, to tailing zwitterionic molecules (i.e., sulfobetaine methacrylate, SBMA) through Michael Addition. The SBMA‐PDA biointerface can resist proteins nonspecific binding in complex biological fluids while enhancing interfacial electron transfer and electrochemical stability of the electrode. In addition, this sensing interface can be integrated with tissue‐implantable electrode for in vivo analysis with improved sensing performance, preserving ca. 92.0% of the initial sensitivity after 2 h of implantation in brain tissue, showing low acute neuroinflammatory responses and good stability both in normal and in Parkinson′s disease (PD) rat brain tissue.
The selective sensing of neurochemicals is essential for understanding the chemical basis of brain function and pathology. Interfacing the excellent recognition features of aptamers with in vivo compatible carbon fiber microelectrode (CFE)-based electroanalytical systems offers a plausible means to achieve this end. However, this is challenging in terms of coupling chemistry, stability, and versatility. Here, we present a new interfacial functionalization strategy based on the assembly of aptamer cholesterol amphiphiles (aptCAs) on the alkyl chain-functionalized CFE. The noncovalent cholesterol-alkyl chain interactions effectively immobilize aptamers onto the CFE surface, allowing the generation of a highly selective system for probing neurochemical dynamics in living systems and opening up a vast array of new opportunities for designing in vivo sensors for exploring brain chemistry.
Single
particle collision is emerging as a powerful and sensitive
technique for analyzing small molecules, however, its application
in biomacromolecules detection, for example, protein, in complex biological
environments is still challenging. Here, we present the first demonstration
on the single particle collision that can be developed for the detection
of platelet-derived growth factor (PDGF), an important protein involved
in the central nervous system in living rat brain. The system features
Pt nanoparticles (PtNPs) conjugated with the PDGF recognition aptamer,
suppressing the electrocatalytic collision of PtNPs toward the oxidation
of hydrazine. In the presence of PDGF, the stronger binding between
targeted protein and the aptamer disrupts the aptamer/PtNPs conjugates,
recovering the electrocatalytic performance of PtNPs, and allowing
quantitative, selective, and highly sensitive detection of PDGF in
cerebrospinal fluid of rat brain.
In vivo electrochemistry with a carbon-fiber electrode (CFE) is the most useful method for tracking neurochemicals in specific brain regions due to its high spatiotemporal resolution. However, CFE is inevitably subject to surface biofouling that leads to a decrease in sensitivity.Here, we develop a polytannic acid (PTA)-doped nanoporous conductive polyaniline (PANI) membrane-coated CFE to minimize biofouling-induced negative effects for in vivo analysis. The as-prepared PTA−PANI-coated CFE shows excellent antifouling property and enrichment capacity toward electrochemical measurement of dopamine (DA) in physiological pH. The PTA−PANI-coated CFE can in vivo monitor the release of DA induced by electrical stimulation and exhibits almost the same sensitivity in the postcalibration (S post ) and the precalibration (S pre ; S post /S pre = 0.90). We believe this conductive nanoporous membrane-coated CFE offers a new platform for in vivo measurement, which would help probe brain chemistry.
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