Your search keyword '"Vincent R. Daria"' showing total 12 results

1. Analyzing Branch‐specific Dendritic Spikes Using an Ultrafast Laser Scalpel

Author

Michael L. Castañares, Hans-A. Bachor, and Vincent R. Daria

Subjects

laser scissors, dendritic spike, pyramidal neuron, dendrites, two-photon imaging, compartmental modeling, Physics, QC1-999

Abstract

Dendritic spikes facilitate neuronal computation and they have been reported to occur in various regions of the dendritic tree of cortical neurons. Spikes that occur only on a select few branches are particularly difficult to analyze especially in complex and intertwined dendritic arborizations where highly localized application of pharmacological blocking agents is not feasible. Here, we present a technique based on highly targeted dendrotomy to tease out and study dendritic spikes that occur in oblique branches of cortical layer five pyramidal neurons. We first analyze the effect of cutting dendrites in silico and then confirmed in vitro using an ultrafast laser scalpel. A dendritic spike evoked in an oblique branch manifests at the soma as an increase in the afterdepolarization (ADP). The spikes are branch-specific since not all but only a few oblique dendrites are observed to evoke spikes. Both our model and experiments show that cutting certain oblique branches, where dendritic spikes are evoked, curtailed the increase in the ADP. On the other hand, cutting neighboring oblique branches that do not evoke spikes maintained the ADP. Our results show that highly targeted dendrotomy can facilitate causal analysis of how branch-specific dendritic spikes influence neuronal output.

Published

2020

2. Improving Focal Photostimulation of Cortical Neurons with Pre-derived Wavefront Correction

Author

Vincent R. Daria, Julian M. C. Choy, Sharmila S. Sané, Woei M. Lee, Christian Stricker, and Hans A. Bachor

Subjects

adaptive optics, two photon microscopy, spatial light modulator, two-photon photolysis, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Recent progress in neuroscience to image and investigate brain function has been made possible by impressive developments in optogenetic and opto-molecular tools. Such research requires advances in optical techniques for the delivery of light through brain tissue with high spatial resolution. The tissue causes distortions to the wavefront of the incoming light which broadens the focus and consequently reduces the intensity and degrades the resolution. Such effects are detrimental in techniques requiring focal stimulation. Adaptive wavefront correction has been demonstrated to compensate for these distortions. However, iterative derivation of the corrective wavefront introduces time constraints that limit its applicability to probe living cells. Here, we demonstrate that we can pre-determine and generalize a small set of Zernike modes to correct for aberrations of the light propagating through specific brain regions. A priori identification of a corrective wavefront is a direct and fast technique that improves the quality of the focus without the need for iterative adaptive wavefront correction. We verify our technique by measuring the efficiency of two-photon photolysis of caged neurotransmitters along the dendrites of a whole-cell patched neuron. Our results show that encoding the selected Zernike modes on the excitation light can improve light propagation through brain slices of rats as observed by the neuron's evoked excitatory post-synaptic potential in response to localized focal uncaging at the spines of the neuron's dendrites.

Published

2017

3. TRPA1 expression and its functional activation in rodent cortex

Author

Ehsan Kheradpezhouh, Julian M. C. Choy, Vincent R. Daria, and Ehsan Arabzadeh

Subjects

cortex, trpa1, layer 5 pyramidal neurons, optovin, photoswitching, Biology (General), QH301-705.5

Abstract

TRPA1 is a non-selective cation channel involved in pain sensation and neurogenic inflammation. Although TRPA1 is well established in a number of organs including the nervous system, its presence and function in the mammalian cortex remains unclear. Here, we demonstrate the expression of TRPA1 in rodent somatosensory cortex through immunostaining and investigate its functional activation by whole-cell electrophysiology, Ca2+ imaging and two-photon photoswitching. Application of TRPA1 agonist (AITC) and antagonist (HC-030031) produced significant modulation of activity in layer 5 (L5) pyramidal neurons in both rats and mice; AITC increased intracellular Ca2+ concentrations and depolarized neurons, and both effects were blocked by HC-030031. These modulations were absent in the TRPA1 knockout mice. Next, we used optovin, a reversible photoactive molecule, to activate TRPA1 in individual L5 neurons of rat cortex. Optical control of activity was established by applying a tightly focused femtosecond-pulsed laser to optovin-loaded neurons. Light application depolarized neurons (n = 17) with the maximal effect observed at λ = 720 nm. Involvement of TRPA1 was further confirmed by repeating the experiment in the presence of HC-030031, which diminished the light modulation. These results demonstrate the presence of TRPA1 in L5 pyramidal neurons and introduce a highly specific approach to further understand its functional significance.

Published

2017

4. Holographic photonic neuron.

Author

Vincent R. Daria

Published

2021

5. To BCVA, or not to BCVA, that is the question

Author

Ted, Maddess and Vincent R, Daria

Subjects

Visual Acuity, Humans, Tomography, Optical Coherence, Retrospective Studies

Published

2017

6. Dynamic optical manipulation of colloidal systems using a spatial light modulator

Author

Vincent R. Daria, RenÉ L. Eriksen, and Jesper Glückstad

Subjects

Atomic and Molecular Physics, and Optics

Published

2003

7. Decrypting binary phase patterns by amplitude.

Author

Jesper Glu¨ckstad, Vincent R. Daria, and Peter J. Rodrigo

Published

2004

8. Phase-only optical decryption in a planar integrated micro-optics system.

Author

Vincent R. Daria and Peter J. Rodrigo

Published

2004

9. Localized two-photon photoswitching of Optovin in rat cortical neurons.

Author

Ehsan Kheradpezhouh, Julian M C Choy, Ehsan Arabzadeh, and Vincent R Daria

Subjects

TRP channels, PYRAMIDAL neurons, NEURONS, RATS

Abstract

Photoswitching molecules are widely used to control neuronal activity by activation of endogenous cellular channels and receptors. Optovin is a photoswitching molecule that targets the cation channel transient receptor potential ankyrin 1 (TRPA1). In zebrafish, bulk single-photon photoswitching of Optovin produced behavioural responses associated with TRPA1 activation. We recently found that TRPA1 is widely expressed in the rodent brain particularly in cortical pyramidal neurons and demonstrated its functional activation via TRPA1 agonists and by two-photon (2P) photoswitching of Optovin in the soma. Here, we exploit the highly localized 2P photoswitching of Optovin to activate TRPA1 along different dendritic and axonal regions of individual pyramidal neurons in the rodent cortex. The technique facilitates measurement of isolated responses when light is directed to the axon and along various dendritic domains of L5 pyramidal neurons. Using this technique, we show that 2P photoswitching of Optovin results in higher levels of depolarization along the base of the apical trunk compared to any other location in the neuron. [ABSTRACT FROM AUTHOR]

Published

2019

10. Light-neuron interactions: key to understanding the brain.

Author

Mary Ann Go and Vincent R Daria

Subjects

*NEURONS, *OPTICS, *NEUROSCIENCES, *LASER microscopy, *MOLECULAR biology

Abstract

In recent years, advances in light-based technology have driven an ongoing optical revolution in neuroscience. Synergistic technologies in laser microscopy, molecular biology, organic and synthetic chemistry, genetic engineering and materials science have allowed light to overcome the limitations of and to replace many conventional tools used by physiologists to record from and to manipulate single cells or whole cellular networks. Here we review the different optical techniques for stimulating neurons, influencing neuronal growth, manipulating neuronal structures and neurosurgery. [ABSTRACT FROM AUTHOR]

Published

2017

11. Using light to probe neuronal function.

Author

Vincent R. Daria and Hans-A. Bachor

Abstract

In the last few years a multi-disciplinary approach has been launched to investigate the brain using new techniques, which are capable of probing neuronal function across the entire length scales of the brain. Here, we discuss optical tools and spatial light patterning techniques to investigate brain function from the perspective of individual neurons and neuronal circuits. We discuss both biochemical and genetic tools to stimulate neurons, as well as techniques to record neuronal activity. We discuss optical projection and imaging tricks that can be dynamically customized to a particular neuron morphology and neuronal circuit layout facilitating a systematic study of their input/output transfer functions. These optical techniques will play a major role towards understanding the operation of a brain. [ABSTRACT FROM AUTHOR]

Published

2015

12. A compact holographic projector module for high-resolution 3D multi-site two-photon photostimulation.

Author

Mary Ann Go, Max Mueller, Michael Lawrence Castañares, Veronica Egger, and Vincent R Daria

Subjects

Medicine, Science

Abstract

Patterned two-photon (2P) photolysis via holographic illumination is a powerful method to investigate neuronal function because of its capability to emulate multiple synaptic inputs in three dimensions (3D) simultaneously. However, like any optical system, holographic projectors have a finite space-bandwidth product that restricts the spatial range of patterned illumination or field-of-view (FOV) for a desired resolution. Such trade-off between holographic FOV and resolution restricts the coverage within a limited domain of the neuron's dendritic tree to perform highly resolved patterned 2P photolysis on individual spines. Here, we integrate a holographic projector into a commercial 2P galvanometer-based 2D scanning microscope with an uncaging unit and extend the accessible holographic FOV by using the galvanometer scanning mirrors to reposition the holographic FOV arbitrarily across the imaging FOV. The projector system utilizes the microscope's built-in imaging functions. Stimulation positions can be selected from within an acquired 3D image stack (the volume-of-interest, VOI) and the holographic projector then generates 3D illumination patterns with multiple uncaging foci. The imaging FOV of our system is 800×800 μm2 within which a holographic VOI of 70×70×70 μm3 can be chosen at arbitrary positions and also moved during experiments without moving the sample. We describe the design and alignment protocol as well as the custom software plugin that controls the 3D positioning of stimulation sites. We demonstrate the neurobiological application of the system by simultaneously uncaging glutamate at multiple spines within dendritic domains and consequently observing summation of postsynaptic potentials at the soma, eventually resulting in action potentials. At the same time, it is possible to perform two-photon Ca2+ imaging in 2D in the dendrite and thus to monitor synaptic Ca2+ entry in selected spines and also local regenerative events such as dendritic action potentials.

Published

2019