Your search keyword '"Cui, Bianxiao"' showing total 12 results

1. A tissue-like neurotransmitter sensor for the brain and gut.

Author

Li, Jinxing, Li, Jinxing, Liu, Yuxin, Yuan, Lei, Zhang, Baibing, Bishop, Estelle Spear, Wang, Kecheng, Tang, Jing, Zheng, Yu-Qing, Xu, Wenhui, Niu, Simiao, Beker, Levent, Li, Thomas L, Chen, Gan, Diyaolu, Modupeola, Thomas, Anne-Laure, Mottini, Vittorio, Tok, Jeffrey B-H, Dunn, James CY, Cui, Bianxiao, Pașca, Sergiu P, Cui, Yi, Habtezion, Aida, Chen, Xiaoke, Bao, Zhenan, Li, Jinxing, Li, Jinxing, Liu, Yuxin, Yuan, Lei, Zhang, Baibing, Bishop, Estelle Spear, Wang, Kecheng, Tang, Jing, Zheng, Yu-Qing, Xu, Wenhui, Niu, Simiao, Beker, Levent, Li, Thomas L, Chen, Gan, Diyaolu, Modupeola, Thomas, Anne-Laure, Mottini, Vittorio, Tok, Jeffrey B-H, Dunn, James CY, Cui, Bianxiao, Pașca, Sergiu P, Cui, Yi, Habtezion, Aida, Chen, Xiaoke, and Bao, Zhenan

Abstract

Neurotransmitters play essential roles in regulating neural circuit dynamics both in the central nervous system as well as at the peripheral, including the gastrointestinal tract1-3. Their real-time monitoring will offer critical information for understanding neural function and diagnosing disease1-3. However, bioelectronic tools to monitor the dynamics of neurotransmitters in vivo, especially in the enteric nervous systems, are underdeveloped. This is mainly owing to the limited availability of biosensing tools that are capable of examining soft, complex and actively moving organs. Here we introduce a tissue-mimicking, stretchable, neurochemical biological interface termed NeuroString, which is prepared by laser patterning of a metal-complexed polyimide into an interconnected graphene/nanoparticle network embedded in an elastomer. NeuroString sensors allow chronic in vivo real-time, multichannel and multiplexed monoamine sensing in the brain of behaving mouse, as well as measuring serotonin dynamics in the gut without undesired stimulations and perturbing peristaltic movements. The described elastic and conformable biosensing interface has broad potential for studying the impact of neurotransmitters on gut microbes, brain-gut communication and may ultimately be extended to biomolecular sensing in other soft organs across the body.

Published

2022

2. Graphene Electric Field Sensor Enables Single Shot Label-Free Imaging of Bioelectric Potentials.

Author

Balch, Halleh B, Balch, Halleh B, McGuire, Allister F, Horng, Jason, Tsai, Hsin-Zon, Qi, Kevin K, Duh, Yi-Shiou, Forrester, Patrick R, Crommie, Michael F, Cui, Bianxiao, Wang, Feng, Balch, Halleh B, Balch, Halleh B, McGuire, Allister F, Horng, Jason, Tsai, Hsin-Zon, Qi, Kevin K, Duh, Yi-Shiou, Forrester, Patrick R, Crommie, Michael F, Cui, Bianxiao, and Wang, Feng

Abstract

The measurement of electrical activity across systems of excitable cells underlies current progress in neuroscience, cardiac pharmacology, and neurotechnology. However, bioelectricity spans orders of magnitude in intensity, space, and time, posing substantial technological challenges. The development of methods permitting network-scale recordings with high spatial resolution remains key to studies of electrogenic cells, emergent networks, and bioelectric computation. Here, we demonstrate single-shot and label-free imaging of extracellular potentials with high resolution across a wide field-of-view. The critically coupled waveguide-amplified graphene electric field (CAGE) sensor leverages the field-sensitive optical transitions in graphene to convert electric potentials into the optical regime. As a proof-of-concept, we use the CAGE sensor to detect native electrical activity from cardiac action potentials with tens-of-microns resolution, simultaneously map the propagation of these potentials at tissue-scale, and monitor their modification by pharmacological agents. This platform is robust, scalable, and compatible with existing microscopy techniques for multimodal correlative imaging.

Published

2021

3. Membrane curvature underlies actin reorganization in response to nanoscale surface topography.

Author

Lou, Hsin-Ya, Lou, Hsin-Ya, Zhao, Wenting, Li, Xiao, Duan, Liting, Powers, Alexander, Akamatsu, Matthew, Santoro, Francesca, McGuire, Allister F, Cui, Yi, Drubin, David G, Cui, Bianxiao, Lou, Hsin-Ya, Lou, Hsin-Ya, Zhao, Wenting, Li, Xiao, Duan, Liting, Powers, Alexander, Akamatsu, Matthew, Santoro, Francesca, McGuire, Allister F, Cui, Yi, Drubin, David G, and Cui, Bianxiao

Abstract

Surface topography profoundly influences cell adhesion, differentiation, and stem cell fate control. Numerous studies using a variety of materials demonstrate that nanoscale topographies change the intracellular organization of actin cytoskeleton and therefore a broad range of cellular dynamics in live cells. However, the underlying molecular mechanism is not well understood, leaving why actin cytoskeleton responds to topographical features unexplained and therefore preventing researchers from predicting optimal topographic features for desired cell behavior. Here we demonstrate that topography-induced membrane curvature plays a crucial role in modulating intracellular actin organization. By inducing precisely controlled membrane curvatures using engineered vertical nanostructures as topographies, we find that actin fibers form at the sites of nanostructures in a curvature-dependent manner with an upper limit for the diameter of curvature at ∼400 nm. Nanotopography-induced actin fibers are branched actin nucleated by the Arp2/3 complex and are mediated by a curvature-sensing protein FBP17. Our study reveals that the formation of nanotopography-induced actin fibers drastically reduces the amount of stress fibers and mature focal adhesions to result in the reorganization of actin cytoskeleton in the entire cell. These findings establish the membrane curvature as a key linkage between surface topography and topography-induced cell signaling and behavior.

Published

2019

4. Nanoscale manipulation of membrane curvature for probing endocytosis in live cells.

Author

Zhao, Wenting, Zhao, Wenting, Hanson, Lindsey, Lou, Hsin-Ya, Akamatsu, Matthew, Chowdary, Praveen D, Santoro, Francesca, Marks, Jessica R, Grassart, Alexandre, Drubin, David G, Cui, Yi, Cui, Bianxiao, Zhao, Wenting, Zhao, Wenting, Hanson, Lindsey, Lou, Hsin-Ya, Akamatsu, Matthew, Chowdary, Praveen D, Santoro, Francesca, Marks, Jessica R, Grassart, Alexandre, Drubin, David G, Cui, Yi, and Cui, Bianxiao

Abstract

Clathrin-mediated endocytosis (CME) involves nanoscale bending and inward budding of the plasma membrane, by which cells regulate both the distribution of membrane proteins and the entry of extracellular species. Extensive studies have shown that CME proteins actively modulate the plasma membrane curvature. However, the reciprocal regulation of how the plasma membrane curvature affects the activities of endocytic proteins is much less explored, despite studies suggesting that membrane curvature itself can trigger biochemical reactions. This gap in our understanding is largely due to technical challenges in precisely controlling the membrane curvature in live cells. In this work, we use patterned nanostructures to generate well-defined membrane curvatures ranging from +50 nm to -500 nm radius of curvature. We find that the positively curved membranes are CME hotspots, and that key CME proteins, clathrin and dynamin, show a strong preference towards positive membrane curvatures with a radius <200 nm. Of ten CME-related proteins we examined, all show preferences for positively curved membrane. In contrast, other membrane-associated proteins and non-CME endocytic protein caveolin1 show no such curvature preference. Therefore, nanostructured substrates constitute a novel tool for investigating curvature-dependent processes in live cells.

Published

2017

5. Imaging electric field dynamics with graphene optoelectronics.

Author

Horng, Jason, Horng, Jason, Balch, Halleh B, McGuire, Allister F, Tsai, Hsin-Zon, Forrester, Patrick R, Crommie, Michael F, Cui, Bianxiao, Wang, Feng, Horng, Jason, Horng, Jason, Balch, Halleh B, McGuire, Allister F, Tsai, Hsin-Zon, Forrester, Patrick R, Crommie, Michael F, Cui, Bianxiao, and Wang, Feng

Abstract

The use of electric fields for signalling and control in liquids is widespread, spanning bioelectric activity in cells to electrical manipulation of microstructures in lab-on-a-chip devices. However, an appropriate tool to resolve the spatio-temporal distribution of electric fields over a large dynamic range has yet to be developed. Here we present a label-free method to image local electric fields in real time and under ambient conditions. Our technique combines the unique gate-variable optical transitions of graphene with a critically coupled planar waveguide platform that enables highly sensitive detection of local electric fields with a voltage sensitivity of a few microvolts, a spatial resolution of tens of micrometres and a frequency response over tens of kilohertz. Our imaging platform enables parallel detection of electric fields over a large field of view and can be tailored to broad applications spanning lab-on-a-chip device engineering to analysis of bioelectric phenomena.

Published

2016

6. Imaging electric field dynamics with graphene optoelectronics.

Author

Horng, Jason, Horng, Jason, Balch, Halleh B, McGuire, Allister F, Tsai, Hsin-Zon, Forrester, Patrick R, Crommie, Michael F, Cui, Bianxiao, Wang, Feng, Horng, Jason, Horng, Jason, Balch, Halleh B, McGuire, Allister F, Tsai, Hsin-Zon, Forrester, Patrick R, Crommie, Michael F, Cui, Bianxiao, and Wang, Feng

Abstract

The use of electric fields for signalling and control in liquids is widespread, spanning bioelectric activity in cells to electrical manipulation of microstructures in lab-on-a-chip devices. However, an appropriate tool to resolve the spatio-temporal distribution of electric fields over a large dynamic range has yet to be developed. Here we present a label-free method to image local electric fields in real time and under ambient conditions. Our technique combines the unique gate-variable optical transitions of graphene with a critically coupled planar waveguide platform that enables highly sensitive detection of local electric fields with a voltage sensitivity of a few microvolts, a spatial resolution of tens of micrometres and a frequency response over tens of kilohertz. Our imaging platform enables parallel detection of electric fields over a large field of view and can be tailored to broad applications spanning lab-on-a-chip device engineering to analysis of bioelectric phenomena.

Published

2016

7. Nanoparticle-assisted optical tethering of endosomes reveals the cooperative function of dyneins in retrograde axonal transport

Author

Massachusetts Institute of Technology. Department of Chemistry, Chen, Ou, Bawendi, Moungi G., Chowdary, Praveen D., Che, Daphne L., Kaplan, Luke, Pu, Kanyi, Cui, Bianxiao, Massachusetts Institute of Technology. Department of Chemistry, Chen, Ou, Bawendi, Moungi G., Chowdary, Praveen D., Che, Daphne L., Kaplan, Luke, Pu, Kanyi, and Cui, Bianxiao

Abstract

Dynein-dependent transport of organelles from the axon terminals to the cell bodies is essential to the survival and function of neurons. However, quantitative knowledge of dyneins on axonal organelles and their collective function during this long-distance transport is lacking because current technologies to do such measurements are not applicable to neurons. Here, we report a new method termed nanoparticle-assisted optical tethering of endosomes (NOTE) that made it possible to study the cooperative mechanics of dyneins on retrograde axonal endosomes in live neurons. In this method, the opposing force from an elastic tether causes the endosomes to gradually stall under load and detach with a recoil velocity proportional to the dynein forces. These recoil velocities reveal that the axonal endosomes, despite their small size, can recruit up to 7 dyneins that function as independent mechanical units stochastically sharing load, which is vital for robust retrograde axonal transport. This study shows that NOTE, which relies on controlled generation of reactive oxygen species, is a viable method to manipulate small cellular cargos that are beyond the reach of current technology., National Institutes of Health (U.S.) (DP2-NS082125), National Science Foundation (U.S.) (Award 1055112), National Science Foundation (U.S.) (Award 1344302)

Published

2016

8. A skin-inspired organic digital mechanoreceptor.

Author

Tee, Benjamin C-K, Tee, Benjamin C-K, Chortos, Alex, Berndt, Andre, Nguyen, Amanda Kim, Tom, Ariane, McGuire, Allister, Lin, Ziliang Carter, Tien, Kevin, Bae, Won-Gyu, Wang, Huiliang, Mei, Ping, Chou, Ho-Hsiu, Cui, Bianxiao, Deisseroth, Karl, Ng, Tse Nga, Bao, Zhenan, Tee, Benjamin C-K, Tee, Benjamin C-K, Chortos, Alex, Berndt, Andre, Nguyen, Amanda Kim, Tom, Ariane, McGuire, Allister, Lin, Ziliang Carter, Tien, Kevin, Bae, Won-Gyu, Wang, Huiliang, Mei, Ping, Chou, Ho-Hsiu, Cui, Bianxiao, Deisseroth, Karl, Ng, Tse Nga, and Bao, Zhenan

Abstract

Human skin relies on cutaneous receptors that output digital signals for tactile sensing in which the intensity of stimulation is converted to a series of voltage pulses. We present a power-efficient skin-inspired mechanoreceptor with a flexible organic transistor circuit that transduces pressure into digital frequency signals directly. The output frequency ranges between 0 and 200 hertz, with a sublinear response to increasing force stimuli that mimics slow-adapting skin mechanoreceptors. The output of the sensors was further used to stimulate optogenetically engineered mouse somatosensory neurons of mouse cortex in vitro, achieving stimulated pulses in accordance with pressure levels. This work represents a step toward the design and use of large-area organic electronic skins with neural-integrated touch feedback for replacement limbs.

Published

2015

9. Activity-dependent BDNF release via endocytic pathways is regulated by synaptotagmin-6 and complexin.

Author

Wong, Yu-Hui, Wong, Yu-Hui, Lee, Chia-Ming, Xie, Wenjun, Cui, Bianxiao, Poo, Mu-ming, Wong, Yu-Hui, Wong, Yu-Hui, Lee, Chia-Ming, Xie, Wenjun, Cui, Bianxiao, and Poo, Mu-ming

Abstract

Brain-derived neurotrophic factor (BDNF) is known to modulate synapse development and plasticity, but the source of synaptic BDNF and molecular mechanisms regulating BDNF release remain unclear. Using exogenous BDNF tagged with quantum dots (BDNF-QDs), we found that endocytosed BDNF-QDs were preferentially localized to postsynaptic sites in the dendrite of cultured hippocampal neurons. Repetitive neuronal spiking induced the release of BDNF-QDs at these sites, and this process required activation of glutamate receptors. Down-regulating complexin 1/2 (Cpx1/2) expression eliminated activity-induced BDNF-QD secretion, although the overall activity-independent secretion was elevated. Among eight synaptotagmin (Syt) isoforms examined, down-regulation of only Syt6 impaired activity-induced BDNF-QD secretion. In contrast, activity-induced release of endogenously synthesized BDNF did not depend on Syt6. Thus, neuronal activity could trigger the release of endosomal BDNF from postsynaptic dendrites in a Cpx- and Syt6-dependent manner, and endosomes containing BDNF may serve as a source of BDNF for activity-dependent synaptic modulation.

Published

2015

10. A skin-inspired organic digital mechanoreceptor.

Author

Tee, Benjamin C-K, Tee, Benjamin C-K, Chortos, Alex, Berndt, Andre, Nguyen, Amanda Kim, Tom, Ariane, McGuire, Allister, Lin, Ziliang Carter, Tien, Kevin, Bae, Won-Gyu, Wang, Huiliang, Mei, Ping, Chou, Ho-Hsiu, Cui, Bianxiao, Deisseroth, Karl, Ng, Tse Nga, Bao, Zhenan, Tee, Benjamin C-K, Tee, Benjamin C-K, Chortos, Alex, Berndt, Andre, Nguyen, Amanda Kim, Tom, Ariane, McGuire, Allister, Lin, Ziliang Carter, Tien, Kevin, Bae, Won-Gyu, Wang, Huiliang, Mei, Ping, Chou, Ho-Hsiu, Cui, Bianxiao, Deisseroth, Karl, Ng, Tse Nga, and Bao, Zhenan

Abstract

Human skin relies on cutaneous receptors that output digital signals for tactile sensing in which the intensity of stimulation is converted to a series of voltage pulses. We present a power-efficient skin-inspired mechanoreceptor with a flexible organic transistor circuit that transduces pressure into digital frequency signals directly. The output frequency ranges between 0 and 200 hertz, with a sublinear response to increasing force stimuli that mimics slow-adapting skin mechanoreceptors. The output of the sensors was further used to stimulate optogenetically engineered mouse somatosensory neurons of mouse cortex in vitro, achieving stimulated pulses in accordance with pressure levels. This work represents a step toward the design and use of large-area organic electronic skins with neural-integrated touch feedback for replacement limbs.

Published

2015

11. One at a time, live tracking of NGF axonal transport using quantum dots

Author

Cui, Bianxiao, Wu, Chengbiao, Chen, Liang, Ramirez, Alfredo, Bearer, Elaine L., Li, Wei-Ping, Mobley, William C., Chu, Steven, Cui, Bianxiao, Wu, Chengbiao, Chen, Liang, Ramirez, Alfredo, Bearer, Elaine L., Li, Wei-Ping, Mobley, William C., and Chu, Steven

Abstract

Retrograde axonal transport of nerve growth factor (NGF) signals is critical for the survival, differentiation, and maintenance of peripheral sympathetic and sensory neurons and basal forebrain cholinergic neurons. However, the mechanisms by which the NGF signal is propagated from the axon terminal to the cell body are yet to be fully elucidated. To gain insight into the mechanisms, we used quantum dot-labeled NGF (QD-NGF) to track the movement of NGF in real time in compartmentalized culture of rat dorsal root ganglion (DRG) neurons. Our studies showed that active transport of NGF within the axons was characterized by rapid, unidirectional movements interrupted by frequent pauses. Almost all movements were retrograde, but short-distance anterograde movements were occasionally observed. Surprisingly, quantitative analysis at the single molecule level demonstrated that the majority of NGF-containing endosomes contained only a single NGF dimer. Electron microscopic analysis of axonal vesicles carrying QD-NGF confirmed this finding. The majority of QD-NGF was found to localize in vesicles 50–150 nm in diameter with a single lumen and no visible intralumenal membranous components. Our findings point to the possibility that a single NGF dimer is sufficient to sustain signaling during retrograde axonal transport to the cell body.

Published

2007

12. One at a time, live tracking of NGF axonal transport using quantum dots

Author

Cui, Bianxiao, Wu, Chengbiao, Chen, Liang, Ramirez, Alfredo, Bearer, Elaine L., Li, Wei-Ping, Mobley, William C., Chu, Steven, Cui, Bianxiao, Wu, Chengbiao, Chen, Liang, Ramirez, Alfredo, Bearer, Elaine L., Li, Wei-Ping, Mobley, William C., and Chu, Steven

Abstract

Retrograde axonal transport of nerve growth factor (NGF) signals is critical for the survival, differentiation, and maintenance of peripheral sympathetic and sensory neurons and basal forebrain cholinergic neurons. However, the mechanisms by which the NGF signal is propagated from the axon terminal to the cell body are yet to be fully elucidated. To gain insight into the mechanisms, we used quantum dot-labeled NGF (QD-NGF) to track the movement of NGF in real time in compartmentalized culture of rat dorsal root ganglion (DRG) neurons. Our studies showed that active transport of NGF within the axons was characterized by rapid, unidirectional movements interrupted by frequent pauses. Almost all movements were retrograde, but short-distance anterograde movements were occasionally observed. Surprisingly, quantitative analysis at the single molecule level demonstrated that the majority of NGF-containing endosomes contained only a single NGF dimer. Electron microscopic analysis of axonal vesicles carrying QD-NGF confirmed this finding. The majority of QD-NGF was found to localize in vesicles 50–150 nm in diameter with a single lumen and no visible intralumenal membranous components. Our findings point to the possibility that a single NGF dimer is sufficient to sustain signaling during retrograde axonal transport to the cell body.

Published

2007