Your search keyword '"Shen, Zhiming"' showing total 4 results

1. Neural correlates of single-vessel haemodynamic responses in vivo.

Author

O'Herron P, Chhatbar PY, Levy M, Shen Z, Schramm AE, Lu Z, and Kara P

Subjects

Action Potentials, Animals, Arterioles physiology, Calcium analysis, Calcium metabolism, Calcium Signaling, Cats, Evoked Potentials, Somatosensory, Glutamic Acid metabolism, Male, Microscopy, Fluorescence, Multiphoton, Models, Neurological, Orientation, Photic Stimulation, Rats, Synapses metabolism, Vasodilation, Visual Cortex cytology, Blood Vessels physiology, Hemodynamics, Neurons physiology, Visual Cortex blood supply, Visual Cortex physiology

Abstract

Neural activation increases blood flow locally. This vascular signal is used by functional imaging techniques to infer the location and strength of neural activity. However, the precise spatial scale over which neural and vascular signals are correlated is unknown. Furthermore, the relative role of synaptic and spiking activity in driving haemodynamic signals is controversial. Previous studies recorded local field potentials as a measure of synaptic activity together with spiking activity and low-resolution haemodynamic imaging. Here we used two-photon microscopy to measure sensory-evoked responses of individual blood vessels (dilation, blood velocity) while imaging synaptic and spiking activity in the surrounding tissue using fluorescent glutamate and calcium sensors. In cat primary visual cortex, where neurons are clustered by their preference for stimulus orientation, we discovered new maps for excitatory synaptic activity, which were organized similarly to those for spiking activity but were less selective for stimulus orientation and direction. We generated tuning curves for individual vessel responses for the first time and found that parenchymal vessels in cortical layer 2/3 were orientation selective. Neighbouring penetrating arterioles had different orientation preferences. Pial surface arteries in cats, as well as surface arteries and penetrating arterioles in rat visual cortex (where orientation maps do not exist), responded to visual stimuli but had no orientation selectivity. We integrated synaptic or spiking responses around individual parenchymal vessels in cats and established that the vascular and neural responses had the same orientation preference. However, synaptic and spiking responses were more selective than vascular responses--vessels frequently responded robustly to stimuli that evoked little to no neural activity in the surrounding tissue. Thus, local neural and haemodynamic signals were partly decoupled. Together, these results indicate that intrinsic cortical properties, such as propagation of vascular dilation between neighbouring columns, need to be accounted for when decoding haemodynamic signals.

Published

2016

2. Targeted labeling of neurons in a specific functional micro-domain of the neocortex by combining intrinsic signal and two-photon imaging.

Author

O'Herron P, Shen Z, Lu Z, Schramm AE, Levy M, and Kara P

Subjects

Animals, Electroporation methods, Image Processing, Computer-Assisted methods, Fluorescent Dyes chemistry, Microscopy, Fluorescence, Multiphoton methods, Neocortex cytology, Neurons cytology

Abstract

In the primary visual cortex of non-rodent mammals, neurons are clustered according to their preference for stimulus features such as orientation(1-4), direction(5-7), ocular dominance(8,9) and binocular disparity(9). Orientation selectivity is the most widely studied feature and a continuous map with a quasi-periodic layout for preferred orientation is present across the entire primary visual cortex(10,11). Integrating the synaptic, cellular and network contributions that lead to stimulus selective responses in these functional maps requires the hybridization of imaging techniques that span sub-micron to millimeter spatial scales. With conventional intrinsic signal optical imaging, the overall layout of functional maps across the entire surface of the visual cortex can be determined(12). The development of in vivo two-photon microscopy using calcium sensitive dyes enables one to determine the synaptic input arriving at individual dendritic spines(13) or record activity simultaneously from hundreds of individual neuronal cell bodies(6,14). Consequently, combining intrinsic signal imaging with the sub-micron spatial resolution of two-photon microscopy offers the possibility of determining exactly which dendritic segments and cells contribute to the micro-domain of any functional map in the neocortex. Here we demonstrate a high-yield method for rapidly obtaining a cortical orientation map and targeting a specific micro-domain in this functional map for labeling neurons with fluorescent dyes in a non-rodent mammal. With the same microscope used for two-photon imaging, we first generate an orientation map using intrinsic signal optical imaging. Then we show how to target a micro-domain of interest using a micropipette loaded with dye to either label a population of neuronal cell bodies or label a single neuron such that dendrites, spines and axons are visible in vivo. Our refinements over previous methods facilitate an examination of neuronal structure-function relationships with sub-cellular resolution in the framework of neocortical functional architectures.

Published

2012

3. An artery-specific fluorescent dye for studying neurovascular coupling.

Author

Shen Z, Lu Z, Chhatbar PY, O'Herron P, and Kara P

Subjects

Animals, Brain physiology, Cats, Mice, Rats, Brain blood supply, Cerebral Arteries cytology, Cerebral Arteries physiology, Fluorescent Dyes, Microscopy, Fluorescence, Multiphoton methods, Neurons physiology, Voltage-Sensitive Dye Imaging methods

Abstract

We demonstrate that Alexa Fluor 633 hydrazide (Alexa Fluor 633) selectively labels neocortical arteries and arterioles by binding to elastin fibers. We measured sensory stimulus-evoked arteriole dilation dynamics in mouse, rat and cat visual cortex using Alexa Fluor 633 together with neuronal activity using calcium indicators or blood flow using fluorescein dextran. Arteriole dilation decreased fluorescence recorded from immediately underlying neurons, representing a potential artifact during neuronal functional imaging experiments.

Published

2012

4. Distinct neuron populations for simple and compound calls in the primary auditory cortex of awake marmosets.

Author

Zeng, Huan-huan, Huang, Jun-feng, Li, Jun-ru, Shen, Zhiming, Gong, Neng, Wen, Yun-qing, Wang, Liping, and Poo, Mu-ming

Subjects

AUDITORY cortex, MARMOSETS, AUDITORY neurons, NEURONS, PRIMATES

Abstract

Marmosets are highly social non-human primates that live in families. They exhibit rich vocalization, but the neural basis underlying this complex vocal communication is largely unknown. Here we report the existence of specific neuron populations in marmoset A1 that respond selectively to distinct simple or compound calls made by conspecific marmosets. These neurons were spatially dispersed within A1 but distinct from those responsive to pure tones. Call-selective responses were markedly diminished when individual domains of the call were deleted or the domain sequence was altered, indicating the importance of the global rather than local spectral-temporal properties of the sound. Compound call-selective responses also disappeared when the sequence of the two simple-call components was reversed or their interval was extended beyond 1 s. Light anesthesia largely abolished call-selective responses. Our findings demonstrate extensive inhibitory and facilitatory interactions among call-evoked responses, and provide the basis for further study of circuit mechanisms underlying vocal communication in awake non-human primates. [ABSTRACT FROM AUTHOR]

Published

2021