Your search keyword '"voltage sensitive dyes"' showing total 35 results

1. A fully-automated low-cost cardiac monolayer optical mapping robot

Author

Peter Lee, Luqia Hou, Faisal J. Alibhai, Rasha Al-attar, Ana Simón-Chica, Andrés Redondo-Rodríguez, Yilin Nie, Maria Mirotsou, Michael A. Laflamme, Gayathri Swaminath, and David Filgueiras-Rama

Subjects

optical mapping, cardiac electrophysiology, automation, robotics, calcium sensitive dyes, voltage sensitive dyes, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Scalable and high-throughput electrophysiological measurement systems are necessary to accelerate the elucidation of cardiac diseases in drug development. Optical mapping is the primary method of simultaneously measuring several key electrophysiological parameters, such as action potentials, intracellular free calcium and conduction velocity, at high spatiotemporal resolution. This tool has been applied to isolated whole-hearts, whole-hearts in-vivo, tissue-slices and cardiac monolayers/tissue-constructs. Although optical mapping of all of these substrates have contributed to our understanding of ion-channels and fibrillation dynamics, cardiac monolayers/tissue-constructs are scalable macroscopic substrates that are particularly amenable to high-throughput interrogation. Here, we describe and validate a scalable and fully-automated monolayer optical mapping robot that requires no human intervention and with reasonable costs. As a proof-of-principle demonstration, we performed parallelized macroscopic optical mapping of calcium dynamics in the well-established neonatal-rat-ventricular-myocyte monolayer plated on standard 35 mm dishes. Given the advancements in regenerative and personalized medicine, we also performed parallelized macroscopic optical mapping of voltage dynamics in human pluripotent stem cell-derived cardiomyocyte monolayers using a genetically encoded voltage indictor and a commonly-used voltage sensitive dye to demonstrate the versatility of our system.

Published

2023

2. METROID: an automated method for robust quantification of subcellular fluorescence events at low SNR

Author

Marcelo Zoccoler and Pedro X. de Oliveira

Subjects

Blind source separation, ROI generation, Fluorescence images, Independent component analysis, Voltage sensitive dyes, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background In cell biology, increasing focus has been directed to fast events at subcellular space with the advent of fluorescent probes. As an example, voltage sensitive dyes (VSD) have been used to measure membrane potentials. Yet, even the most recently developed genetically encoded voltage sensors have demanded exhausting signal averaging through repeated experiments to quantify action potentials (AP). This analysis may be further hampered in subcellular signals defined by small regions of interest (ROI), where signal-to-noise ratio (SNR) may fall substantially. Signal processing techniques like blind source separation (BSS) are designed to separate a multichannel mixture of signals into uncorrelated or independent sources, whose potential to separate ROI signal from noise has been poorly explored. Our aims are to develop a method capable of retrieving subcellular events with minimal a priori information from noisy cell fluorescence images and to provide it as a computational tool to be readily employed by the scientific community. Results In this paper, we have developed METROID (Morphological Extraction of Transmembrane potential from Regions Of Interest Device), a new computational tool to filter fluorescence signals from multiple ROIs, whose code and graphical interface are freely available. In this tool, we developed a new ROI definition procedure to automatically generate similar-area ROIs that follow cell shape. In addition, simulations and real data analysis were performed to recover AP and electroporation signals contaminated by noise by means of four types of BSS: Principal Component Analysis (PCA), Independent Component Analysis (ICA), and two versions with discrete wavelet transform (DWT). All these strategies allowed for signal extraction at low SNR (− 10 dB) without apparent signal distortion. Conclusions We demonstrate the great capability of our method to filter subcellular signals from noisy fluorescence images in a single trial, avoiding repeated experiments. We provide this novel biomedical application with a graphical user interface at https://doi.org/10.6084/m9.figshare.11344046.v1 , and its code and datasets are available in GitHub at https://github.com/zoccoler/metroid .

Published

2020

3. Imaging membrane potential

Author

Wilkinson, James Daniel and Anderson, Harry L.

Subjects

547, Chemistry & allied sciences, Advanced materials, Biosensors, Organic chemistry, Organic synthesis, Supramolecular chemistry, Surface analysis, Surface chemistry, Synthetic organic chemistry, Voltage Sensitive Dyes

Abstract

Imaging membrane potential is a promising technique in the elucidation of the interactions of large networks of neurons. The membrane potential in a neuron varies as an action potential, the basic electrical signal of neuronal communication, travels along the length of the cell. Voltage sensitive dyes play a key role by providing an optical readout of the electric field generated across a neuron membrane by the action potential. However, none of the dyes reviewed in Chapter 1 generate sufficient signal change with changes in membrane potential; this sensitivity problem limits the ability of the imaging membrane potential technique to allow the high spatial and temporal resolution necessary for neuronal networks to be better understood. This thesis features two avenues of research that are expected to result in the necessary enhancements to voltage sensitive dyes to improve the signal change. The first avenue is based on the effect of an electric field upon the non-linear optical properties of a porphyrin macromolecule. The encouraging field sensitivity of a previous porphyrin monomer voltage sensor inspired an investigation which identified optimisations to enhance the voltage sensitivity (Chapter 2). The design, synthesis and initial characterisation of optimised porphyrin voltage sensors is detailed in Chapter 3. The second avenue is based on the effect of an electric field upon the rate of intermolecular electron transfer. In a suitably designed dye, the competition between electron transfer and fluorescence, following excitation by incoming light, allows the fluorescence intensity to act as an optical indicator of the electron transfer rate. New dyes were rationally designed and synthesised, as this effect had not been applied to voltage sensitive imaging before the research detailed in Chapter 4. The challenging purification of the new amphiphilic dyes synthesised also inspired research into a novel testing method which does not require amphiphilic dyes (Chapter 5).

Published

2014

4. A Complete and Low-Cost Cardiac Optical Mapping System in Translational Animal Models

Author

Manuel Marina-Breysse, Alba García-Escolano, Joaquín Vila-García, Gabriel Reale-Nosei, José M. Alfonso-Almazán, Ping Yan, Jorge G. Quintanilla, Leslie M. Loew, Peter Lee, and David Filgueiras-Rama

Subjects

optical mapping, cardiac electrophysiology, voltage sensitive dyes, calcium sensitive dyes, animal models, Physiology, QP1-981

Abstract

Clinicians, biologists, physicists, engineers, and computer scientists are coming together to better understand heart disease, which is currently the leading cause of death globally. Optical mapping, a high-speed fluorescence imaging technique that visualizes and measures key cardiac parameters such as action potentials, cytosolic calcium transients, and fibrillation dynamics, is a core research tool that has arisen from such interdisciplinary collaborations. In an effort to broaden its use, especially among clinical scientists and students, we developed a complete and low-cost optical mapping system, including a constant-flow Langendorff perfusion system, which minimizes the economic threshold to widespread use of this powerful tool in cardiac electrophysiology research. The system described here provides high spatiotemporal resolution data about action potentials, intracellular calcium transients and fibrillation wave dynamics in isolated Langendorff-perfused hearts (pigs and rabbits), relevant for translational research. All system components and software elements are fully disclosed with the aim of increasing the use of this affordable and highly versatile tool among clinicians, basic scientists and students wishing to tackle their own research questions with their own customizable systems.

Published

2021

5. A Complete and Low-Cost Cardiac Optical Mapping System in Translational Animal Models.

Author

Marina-Breysse, Manuel, García-Escolano, Alba, Vila-García, Joaquín, Reale-Nosei, Gabriel, Alfonso-Almazán, José M., Yan, Ping, Quintanilla, Jorge G., Loew, Leslie M., Lee, Peter, and Filgueiras-Rama, David

Subjects

CAUSES of death, ANIMAL models in research, METADATA, MEDICAL personnel, INTRACELLULAR calcium, IMAGING systems in biology, CARDIAC contraction

Abstract

Clinicians, biologists, physicists, engineers, and computer scientists are coming together to better understand heart disease, which is currently the leading cause of death globally. Optical mapping, a high-speed fluorescence imaging technique that visualizes and measures key cardiac parameters such as action potentials, cytosolic calcium transients, and fibrillation dynamics, is a core research tool that has arisen from such interdisciplinary collaborations. In an effort to broaden its use, especially among clinical scientists and students, we developed a complete and low-cost optical mapping system, including a constant-flow Langendorff perfusion system, which minimizes the economic threshold to widespread use of this powerful tool in cardiac electrophysiology research. The system described here provides high spatiotemporal resolution data about action potentials, intracellular calcium transients and fibrillation wave dynamics in isolated Langendorff-perfused hearts (pigs and rabbits), relevant for translational research. All system components and software elements are fully disclosed with the aim of increasing the use of this affordable and highly versatile tool among clinicians, basic scientists and students wishing to tackle their own research questions with their own customizable systems. [ABSTRACT FROM AUTHOR]

Published

2021

6. Two-photon excitation of FluoVolt allows improved interrogation of transmural electrophysiological function in the intact mouse heart.

Author

Salerno, Simona, Garten, Karin, Smith, Godfrey L., Stølen, Tomas, and Kelly, Allen

Subjects

*CHARGE exchange, *HEART, *QUESTIONING, *CONFOCAL microscopy, *MEMBRANE potential, *BIOFLUORESCENCE

Abstract

Two-photon excitation of voltage sensitive dyes (VSDs) can measure rapidly changing electrophysiological signals deep within intact cardiac tissue with improved three-dimensional resolution along with reduced photobleaching and photo-toxicity compared to conventional confocal microscopy. Recently, a category of VSDs has emerged which records membrane potentials by photo-induced electron transfer. FluoVolt is a novel VSD in this category which promises fast response and a 25% fractional change in fluorescence per 100 mV, making it an attractive optical probe for action potential (AP) recordings within intact cardiac tissue. The purpose of this study was to characterize the fluorescent properties of FluoVolt as well as its utility for deep tissue imaging. Discrete tissue layers throughout the left ventricular wall of isolated perfused murine hearts loaded with FluoVolt or di-4-ANEPPS were sequentially excited with two-photon microscopy. FluoVolt loaded hearts suffered significantly fewer episodes of atrio-ventricular block compared to di-4-ANEPPS loaded hearts, indicating comparatively low toxicity of FluoVolt in the intact heart. APs recorded with FluoVolt were characterized by a lower signal-to-noise ratio and a higher dynamic range compared to APs recorded with di-4-ANEPPS. Although both depolarization and repolarization parameters were similar in APs recorded with either dye, FluoVolt allowed deeper tissue excitation with improved three-dimensional resolution due to reduced out-of-focus fluorescence generation under two-photon excitation. Our results demonstrate several advantages of two-photon excitation of FluoVolt in functional studies in intact heart preparations, including reduced toxicity and improved fluorescent properties. [ABSTRACT FROM AUTHOR]

Published

2020

7. METROID: an automated method for robust quantification of subcellular fluorescence events at low SNR.

Author

Zoccoler, Marcelo and de Oliveira, Pedro X.

Abstract

Background: In cell biology, increasing focus has been directed to fast events at subcellular space with the advent of fluorescent probes. As an example, voltage sensitive dyes (VSD) have been used to measure membrane potentials. Yet, even the most recently developed genetically encoded voltage sensors have demanded exhausting signal averaging through repeated experiments to quantify action potentials (AP). This analysis may be further hampered in subcellular signals defined by small regions of interest (ROI), where signal-to-noise ratio (SNR) may fall substantially. Signal processing techniques like blind source separation (BSS) are designed to separate a multichannel mixture of signals into uncorrelated or independent sources, whose potential to separate ROI signal from noise has been poorly explored. Our aims are to develop a method capable of retrieving subcellular events with minimal a priori information from noisy cell fluorescence images and to provide it as a computational tool to be readily employed by the scientific community. Results: In this paper, we have developed METROID (Morphological Extraction of Transmembrane potential from Regions Of Interest Device), a new computational tool to filter fluorescence signals from multiple ROIs, whose code and graphical interface are freely available. In this tool, we developed a new ROI definition procedure to automatically generate similar-area ROIs that follow cell shape. In addition, simulations and real data analysis were performed to recover AP and electroporation signals contaminated by noise by means of four types of BSS: Principal Component Analysis (PCA), Independent Component Analysis (ICA), and two versions with discrete wavelet transform (DWT). All these strategies allowed for signal extraction at low SNR (− 10 dB) without apparent signal distortion. Conclusions: We demonstrate the great capability of our method to filter subcellular signals from noisy fluorescence images in a single trial, avoiding repeated experiments. We provide this novel biomedical application with a graphical user interface at 10.6084/m9.figshare.11344046.v1, and its code and datasets are available in GitHub at . [ABSTRACT FROM AUTHOR]

Published

2020

8. Study of Transmembrane Voltage Kinetics during 100 μs Pulse Using Voltage Sensitive Dyes

Author

Silve, A., Poignard, C., Sack, M., Straessner, R., Frey, W., MAGJAREVIC, Ratko, Editor-in-chief, Ladyzynsk, Piotr, Series editor, Ibrahim, Fatimah, Series editor, Lacković, Igor, Series editor, Rock, Emilio Sacristan, Series editor, Jarm, Tomaz, editor, and Kramar, Peter, editor

Published

2016

9. Development of Genetically Targeted Voltage Sensitive Dyes

Author

Liu, Pei

Subjects

Chemistry, voltage sensitive dyes, voltage sensor

Abstract

Comprehensively mapping and recording the electrical inputs and outputs of multiple neurons simultaneously with cellular spatial resolution and millisecond time resolution remains an outstanding challenge in the field of neurobiology. Development of fluorescence indicators for direct visualization of membrane potential changes offers a powerful method for probing voltage dynamics in neurons with unprecedented spatial and temporal resolution. Despite the promise of voltage imaging, key challenges of speed, sensitivity, brightness, and localization remain. The Miller lab has developed a new class of small molecules dyes, VoltageFluors (VF), that rely on photoinduced electron transfer (PeT) and display voltage-sensitive fluorescence due to modulation of the rate of PeT within the VF scaffold by the transmembrane electric field. This approach allows for fast, sensitive and non-invasive recording of neuronal activity in cultured mammalian neurons and in ex vivo tissue slices in single trials. One major limitation of small-molecule dye imaging is the inability to target the dye to specific cells of interest, which significantly erodes signal to noise and cellular resolution. To solve this problem, we have worked to combine VF dyes with a genetically encoded component to enable high-contrast imaging in defined neurons. We first attempted a fluorogenic approach, in which the parent VF dye is chemically modified to be minimally fluorescent and non-voltage-sensitive and must be enzymatically activated prior to imaging. We designed a couple of dyes which can only be activated by a cell-surface pig liver esterase (PLE) and observed enhanced contrast in both HEK cells and cultured neurons with good sensitivity. We have also shown that our genetically targeted voltage dyes outperform purely genetically encoded voltage indicators. In addition, we are exploring other enzyme/substrate pair for fluorogenic activation purpose. The second approach is covalent labeling of voltage sensitive dye to cells of interest using a cell-surface HaloTag enzyme. We have successfully demonstrated selective membrane staining in mouse brain slices and live animal using this strategy. Current efforts focus on applying this method for targeted voltage imaging in live animals to probe specific neuroscience questions.

Published

2019

10. Synthesis and Development of Fluorescent Dyes for Imaging Neuronal Activity

Author

Ortiz, Gloria

Subjects

Chemistry, fluorescence imaging, fluorophores, genetic targeting, neuronal activity, red shifted probes, voltage sensitive dyes

Abstract

Fluorescent probes are noninvasive tools that can be used to map the electrical activity and synaptic communication of large networks of neurons. Fluorescent probes that bind Ca2+ or measure voltage changes translate activity into fluorescence signals with high spatial and temporal resolution. Current probes used for measuring neuronal activity utilize relatively short wavelengths of light. This dissertation discusses new synthetic methods to access sulfonated voltage sensitive dyes (VSDs) that are red-shifted and exhibit improved performance in cells, including greater photostability, voltage sensitivity, brightness, and signal to noise ratios. As most small molecule VSDs nonspecifically label cells, limiting their use in more complex tissues, chemical-genetic targeting approaches to target VSDs dyes for increased contrast and reduced background fluorescence will be discussed. We synthesize sulfonated carbofluorescein VoltageFluors (carboVFs) which utilize photoinduced electron transfer as a trigger to sense voltage in cells. CarboVFs display red-shifted profiles of >560 nm and high voltage sensitivities (up to 31% ΔF/F per 100 mV). The best performing carboVF, carboVF2.1(OMe).Cl, can be incorporated into an enzymatic, fluorogenic targeting strategy to specifically label cells. By replacing the oxygens in carboVFs with dimethylaminos, we accessed far-red TMCRh voltage indicators which possess excitation and emission profiles >620 nm, display improved photostability and reduced phototoxicity, and still maintain good voltage sensitivities (up to 18% ΔF/F per 100 mV). In particular, TMCRh.OMe rivals or outperforms reported far-red silicon rhodamine VSD, BeRST 1, when comparing signal to noise and ΔF/F in neurons, and has the potential to be used as a bright reporter of absolute membrane potential in non-excitable cells using fluorescence lifetime imaging. In addition to derivatizing the carbofluorescein scaffold to obtain new VSDs, this dissertation discusses a new synthetic route to access sulfonated silicon rhodamines and progress towards applying this strategy to carboxylated silicon rhodamines. Silicon rhodamines which bear a carboxyl instead of the typical sulfonate membrane anchor are important for the genetic-targeting of rhodamine-based VSD dyes to specific cells. We report the development of a genetically-targeted silicon rhodamine voltage indicator, isoBeRST-Halo, through a covalent labeling strategy using the HaloTag system. IsoBeRST-Halo maintains the high voltage sensitivity of the untargeted isoBeRSTs, while achieving high selectivity in cultured cells and cortical brain slice. To address the limitations of fast voltage imaging speeds and allow for the comprehensive mapping of neuronal networks, we sought to develop Ca2+ integrators based on the fluorogenic spirobenzopyran scaffold, calcium ligands, and a photoactivatable group. Various modifications to the spirobenzopyran scaffold will be discussed, as well as the synthesis and initial characterization of new calcium ligands. Together, this work demonstrates the power of synthetic chemistry to achieve highly selective, bright, and functional reporters of neuronal activity.

Published

2019

11. Design and Synthesis of Chemical Tools for Imaging Neuronal Activity

Author

Deal, Parker

Subjects

Chemistry, Bioimaging, Fluorescence Microscopy, Ion Sensing, Photocaging, RhoVR, Voltage Sensitive Dyes

Abstract

The ultimate goal of neuroscience is to correlate the activity of neurons and neuronal networks to higher order behaviors and cognition. This colossal task necessitates a variety of optical tools that can both measure and modulate neuronal activity. This dissertation describes the design, synthesis and characterization of a variety of such tools. In order to interrogate the electrical activity of neuronal circuits directly, we synthesized tetramethylrhodamine-based voltage reporters, or RhoVRs, that possess excitation and emission profiles in the green to orange region of the visible spectrum and use photoinduced electron transfer (PeT) as a trigger for voltage sensing. Two RhoVRs with particularly attractive photophysical properties were developed: RhoVR 1, which possessed the highest voltage sensitivity of any RhoVR (47% ΔF/F per 100 mV), and RhoVR(Me), a less sensitive (13% ΔF/F per 100 mV) but far brighter RhoVR (4-fold brighter than RhoVR 1). In order to facilitate the use of RhoVRs in complex tissues such as brain slice or in vivo, we developed genetically targetable RhoVRs using the HaloTag system (RhoVR-Halos). RhoVR-Halos maintained the fast kinetics and high sensitivities typical of RhoVRs (up to 34% ΔF/F per 100 mV) while labeling HaloTag expressing cells with high selectivity in culture, brain slice and in vivo. In addition, RhoVRs possess high two-photon cross sections (up to 190 GM), making them excellent candidates for two-photon voltage imaging. While voltage indicators allow for the study of fast voltage dynamics in real time, they necessitate very fast imaging speeds that are not well suited for mapping activity across large neuronal networks. In order to facilitate neuronal activity mapping, we developed a Ca2+ integrator MethylAzid-1 (MA-1). MA-1 acts as a coincidence detector for both light and Ca2+, allowing a temporally precise “snapshot” of [Ca2+] to be taken. MA-1 undergoes a 25 nm shift in absorbance upon chelation of Ca2+ (Kd = 270 nM) that allows for the selective photolysis of Ca2+-free MA-1 with 400 nm light. The extent of photolysis can be visualized post hoc through either “click chemistry” or the fluorogenic reduction of remaining MA-1. In addition to tools which report neuronal activity, we synthesized a new class of photocages based on 6-aminobenzofurans (BFCs) that can be used to selectively release caged compounds, such as neurotransmitters, upon irradiation with UV light. BFCs operate through a photo-induced elimination reaction that generates an extended azaquinone-methide from the excited state. Initial studies revealed BFCs are strong absorbers of UV/Violet light (λmax = 365 nm, ε = 30,000 M-1 cm-1) that readily photolyze (Φphotolysis up to 0.18) to release their caged cargo. Together, this work demonstrates the power of optical tools to study neuronal systems ranging from sub-cellular domains to large networks of neurons and lays the groundwork for their application in complex tissues such as brain slice or in vivo.

Published

2018

12. Two-photon excitation of FluoVolt allows improved interrogation of transmural electrophysiological function in the intact mouse heart

Author

Allen Kelly, Karin Garten, Godfrey L. Smith, Simona Salerno, and Tomas Stølen

Subjects

Optical Phenomena, 030303 biophysics, Biophysics, Action Potentials, Voltage sensitive dyes, Article, law.invention, Mice, 03 medical and health sciences, Two-photon excitation microscopy, Confocal microscopy, law, Microscopy, Animals, Ventricular Function, Repolarization, Molecular Biology, Photons, 0303 health sciences, Chemistry, Heart, Depolarization, Photobleaching, Fluorescence, Electrophysiology, Isolated perfused heart, Two photon excitation microscopy, Biomedical engineering

Abstract

Background and aims:\ud Two-photon excitation of voltage sensitive dyes (VSDs) can measure rapidly changing electrophysiological signals deep within intact cardiac tissue with improved three-dimensional resolution along with reduced photobleaching and photo-toxicity compared to conventional confocal microscopy. Recently, a category of VSDs has emerged which records membrane potentials by photo-induced electron transfer. FluoVolt is a novel VSD in this category which promises fast response and a 25% fractional change in fluorescence per 100 mV, making it an attractive optical probe for action potential (AP) recordings within intact cardiac tissue. The purpose of this study was to characterize the fluorescent properties of FluoVolt as well as its utility for deep tissue imaging.\ud \ud Methods:\ud Discrete tissue layers throughout the left ventricular wall of isolated perfused murine hearts loaded with FluoVolt or di-4-ANEPPS were sequentially excited with two-photon microscopy.\ud \ud Results:\ud FluoVolt loaded hearts suffered significantly fewer episodes of atrio-ventricular block compared to di-4-ANEPPS loaded hearts, indicating comparatively low toxicity of FluoVolt in the intact heart. APs recorded with FluoVolt were characterized by a lower signal-to-noise ratio and a higher dynamic range compared to APs recorded with di-4-ANEPPS. Although both depolarization and repolarization parameters were similar in APs recorded with either dye, FluoVolt allowed deeper tissue excitation with improved three-dimensional resolution due to reduced out-of-focus fluorescence generation under two-photon excitation.\ud \ud Conclusion:\ud Our results demonstrate several advantages of two-photon excitation of FluoVolt in functional studies in intact heart preparations, including reduced toxicity and improved fluorescent properties.

Published

2020

13. METROID: an automated method for robust quantification of subcellular fluorescence events at low SNR

Author

Pedro Xavier de Oliveira and Marcelo Zoccoler

Subjects

Discrete wavelet transform, Fluorescence images, 030310 physiology, Independent component analysis, Signal-To-Noise Ratio, lcsh:Computer applications to medicine. Medical informatics, Biochemistry, Blind signal separation, Signal, Voltage sensitive dyes, Fluorescence, Membrane Potentials, Automation, User-Computer Interface, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, ROI generation, Animals, Humans, Computer Simulation, Coloring Agents, Molecular Biology, lcsh:QH301-705.5, Principal Component Analysis, 0303 health sciences, Signal processing, Noise (signal processing), business.industry, Methodology Article, Applied Mathematics, Signal Processing, Computer-Assisted, Pattern recognition, Filter (signal processing), Rats, Computer Science Applications, lcsh:Biology (General), Blind source separation, lcsh:R858-859.7, Signal averaging, Artificial intelligence, business, Algorithms, Software, 030217 neurology & neurosurgery, Subcellular Fractions

Abstract

Background In cell biology, increasing focus has been directed to fast events at subcellular space with the advent of fluorescent probes. As an example, voltage sensitive dyes (VSD) have been used to measure membrane potentials. Yet, even the most recently developed genetically encoded voltage sensors have demanded exhausting signal averaging through repeated experiments to quantify action potentials (AP). This analysis may be further hampered in subcellular signals defined by small regions of interest (ROI), where signal-to-noise ratio (SNR) may fall substantially. Signal processing techniques like blind source separation (BSS) are designed to separate a multichannel mixture of signals into uncorrelated or independent sources, whose potential to separate ROI signal from noise has been poorly explored. Our aims are to develop a method capable of retrieving subcellular events with minimal a priori information from noisy cell fluorescence images and to provide it as a computational tool to be readily employed by the scientific community. Results In this paper, we have developed METROID (Morphological Extraction of Transmembrane potential from Regions Of Interest Device), a new computational tool to filter fluorescence signals from multiple ROIs, whose code and graphical interface are freely available. In this tool, we developed a new ROI definition procedure to automatically generate similar-area ROIs that follow cell shape. In addition, simulations and real data analysis were performed to recover AP and electroporation signals contaminated by noise by means of four types of BSS: Principal Component Analysis (PCA), Independent Component Analysis (ICA), and two versions with discrete wavelet transform (DWT). All these strategies allowed for signal extraction at low SNR (− 10 dB) without apparent signal distortion. Conclusions We demonstrate the great capability of our method to filter subcellular signals from noisy fluorescence images in a single trial, avoiding repeated experiments. We provide this novel biomedical application with a graphical user interface at 10.6084/m9.figshare.11344046.v1, and its code and datasets are available in GitHub at https://github.com/zoccoler/metroid.

Published

2020

14. A fully-automated low-cost cardiac monolayer optical mapping robot.

Author

Lee P, Hou L, Alibhai FJ, Al-Attar R, Simón-Chica A, Redondo-Rodríguez A, Nie Y, Mirotsou M, Laflamme MA, Swaminath G, and Filgueiras-Rama D

Abstract

Scalable and high-throughput electrophysiological measurement systems are necessary to accelerate the elucidation of cardiac diseases in drug development. Optical mapping is the primary method of simultaneously measuring several key electrophysiological parameters, such as action potentials, intracellular free calcium and conduction velocity, at high spatiotemporal resolution. This tool has been applied to isolated whole-hearts, whole-hearts in-vivo, tissue-slices and cardiac monolayers/tissue-constructs. Although optical mapping of all of these substrates have contributed to our understanding of ion-channels and fibrillation dynamics, cardiac monolayers/tissue-constructs are scalable macroscopic substrates that are particularly amenable to high-throughput interrogation. Here, we describe and validate a scalable and fully-automated monolayer optical mapping robot that requires no human intervention and with reasonable costs. As a proof-of-principle demonstration, we performed parallelized macroscopic optical mapping of calcium dynamics in the well-established neonatal-rat-ventricular-myocyte monolayer plated on standard 35 mm dishes. Given the advancements in regenerative and personalized medicine, we also performed parallelized macroscopic optical mapping of voltage dynamics in human pluripotent stem cell-derived cardiomyocyte monolayers using a genetically encoded voltage indictor and a commonly-used voltage sensitive dye to demonstrate the versatility of our system., Competing Interests: PL is both an owner and employee of Essel Research and Development Inc. LH, YN, MM and GS are employees of Merck Sharp & Dohme LLC, a subsidiary of Merck & Co., Inc., Rahway, NJ, USA. MAL is a scientific founder and paid consultant for BlueRock Therapeutics LP. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (© 2023 Lee, Hou, Alibhai, Al-attar, Simon-Chica, Redondo-Rodriguez, Nie, Mirotsou, Laflamme, Swaminath and Filgueiras-Rama.)

Published

2023

15. Fluorescence-Based Automated Screening Assay for the Study of the pH-Sensitive Channel ASIC1a.

Author

Mazzocchi, Nausicaa, De Ceglia, Roberta, Mazza, Davide, Forti, Lia, Muzio, Luca, and Menegon, Andrea

Abstract

Acid-sensing ion channel 1a (ASIC1a) is involved in several pathologies, including neurodegenerative and neuroinflammatory disorders, stroke, epilepsy, and inflammatory pain. ASIC1a has been the subject of intense drug discovery programs devoted to the development of new pharmacological tools for its modulation. However, these efforts to generate new compounds have faced the lack of an efficient screening procedure. In the past decades, improvements in screening technologies and fluorescent sensors for the study of ion channels have provided new opportunities in this field. Unfortunately, ASIC1a is mainly a Na+ permeable channel and undergoes desensitization after its activation, two features that make the use of the available screening procedures problematic. We propose here a novel screening approach for the study of ASIC1a activity in full automation. Our method is based on the stimulation of ASIC1a-expressing cells by protons and the use of electrochromic fluorescent voltage sensors as a readout of ion channel activation. This method will prove to be useful for drug screening programs aimed at ASIC1a modulation. [ABSTRACT FROM AUTHOR]

Published

2016

16. Review paperRecording of the neuronal activity in the gastrointestinal tract using the Multisite Optical Recording Technique (MSORT)

Author

Michał Ceregrzyn, Klaus Michel, and Michael Schemann

Subjects

enteric nervous system, neuroimaging, myenteric plexus, voltage sensitive dyes, fast excitatory postsynaptic potential, Medicine

Abstract

The Enteric Nervous System (ENS) plays a key role in regulating the function of the gastrointestinal tract. The knowledge about the function of neurons is based on experiments using the intracellular recording method. Limitations of the method have become a stimulus for developing an alternative technique that would record cell membrane potential changes without mechanical interruption and with no cells bias due to their size. The recently developed neuroimaging method meets these demands. The principle of the technique is based on fluorescence of voltage sensitive dyes (VSD) specific molecules that incorporated in cell membranes react to their potential. Photodiode arrays or charge-coupled device (CCD) cameras can be used for acquiring the fluorescent light that permits to monitor fast changes in membrane potential. The Multisite Optical Recording Technique (MSORT) is capable of recording changes in membrane potential in all neurons in the ENS with sufficient spatial and temporal resolution. Studies published up to date are very promising and give an interesting view on the function of neurons in the ENS.

Published

2005

17. Temporally-structured acquisition of multidimensional optical imaging data facilitates visualization of elusive cortical representations in the behaving monkey.

Author

Omer, David B., Hildesheim, Rina, and Grinvald, Amiram

Subjects

*COGNITIVE ability, *VISUALIZATION, *SPATIOTEMPORAL processes, *LABORATORY monkeys, *MULTIDIMENSIONAL databases, *BRAIN imaging, *OPTICAL imaging sensors

Abstract

Abstract: Fundamental understanding of higher cognitive functions can greatly benefit from imaging of cortical activity with high spatiotemporal resolution in the behaving non-human primate. To achieve rapid imaging of high-resolution dynamics of cortical representations of spontaneous and evoked activity, we designed a novel data acquisition protocol for sensory stimulation by rapidly interleaving multiple stimuli in continuous sessions of optical imaging with voltage-sensitive dyes. We also tested a new algorithm for the “temporally structured component analysis” (TSCA) of a multidimensional time series that was developed for our new data acquisition protocol, but was tested only on simulated data (Blumenfeld, 2010). In addition to the raw data, the algorithm incorporates prior knowledge about the temporal structure of the data as well as input from other information. Here we showed that TSCA can successfully separate functional signal components from other signals referred to as noise. Imaging of responses to multiple visual stimuli, utilizing voltage-sensitive dyes, was performed on the visual cortex of awake monkeys. Multiple cortical representations, including orientation and ocular dominance maps as well as the hitherto elusive retinotopic representation of orientation stimuli, were extracted in only 10s of imaging, approximately two orders of magnitude faster than accomplished by conventional methods. Since the approach is rather general, other imaging techniques may also benefit from the same stimulation protocol. This methodology can thus facilitate rapid optical imaging explorations in monkeys, rodents and other species with a versatility and speed that were not feasible before. [Copyright &y& Elsevier]

Published

2013

18. Electrogenic plasma membrane H-ATPase activity using voltage sensitive dyes.

Author

Amoroso, Steve, Clarke, Ronald, Larkum, Anthony, and Quinnell, Rosanne

Subjects

*CELL membranes, *ADENOSINE triphosphate, *CELLULOSE dyeing, *PROTON pump inhibitors, *FLUORESCENCE spectroscopy, *BIOPHYSICS, *PLANT extracts

Abstract

Fast responding voltage sensitive dyes, RH421 and di-4-ASPBS, were used to study the electrogenic properties of plant plasma membrane proton pumps on sealed plasma membrane vesicles extracted by two-phase partitioning from Beta vulgaris and Avena sativa cv Swan root material. Fluorescence spectroscopy in the presence of the dye RH421 (10.8 nM) was sufficiently sensitive to detect electrogenic activity of the extracted plant vesicles. The dye detection system could detect inhibition of electrogenic activity of vesicles by vanadate (75 μM) and stimulation by nigericin (0.5 μM). The newly developed dye di-4-ASPBS was less sensitive to detecting the electrogenic proton pump activity. This study represents an important innovation in plant biophysics as this class of fast responding voltage sensitive dyes have never to our knowledge been used to study electrogenic proton pump activity derived from plant membranes and represents a novel approach for carrying out such studies. [ABSTRACT FROM AUTHOR]

Published

2010

19. The role of multi-area interactions for the computation of apparent motion

Author

Deco, Gustavo and Roland, Per

Subjects

*NEURAL physiology, *VISUAL cortex, *BRAIN research, *OCCIPITAL lobe, *MOTION capture (Human mechanics), *COMPUTERS in medicine

Abstract

Abstract: Apparent motion (AM) is a robust visual illusion, in which fast displays of static objects in successively different positions elicit the perception of object motion. Neurons in higher order areas 21 and 19 compute object motion under such conditions and send feedback to early visual areas 18 and 17, which is instrumental in eliciting computation of motion in those very areas. To explore the computational dynamics of AM, we made a neural field model consisting of two one-dimensional rings of simple neurons expressing firing rates, one for areas 17/18 and one for areas 19/21. The model neurons, without any orientation or direction selectivity, computed apparent motion for the range of space-timings of stimuli associated with short- and long-range AM in humans. The computation of long-range AM in 17/18 required two model areas and the presence of feedback and conduction/computation delays between those areas. As in the in vivo experiments of long-range AM, the stationary stimuli were initially mapped as stationary in model area 17/18, but after the feedback also these lower areas computed AM. The dynamics of the two-area network produces short-range and long-range apparent motion for a large range of feedback strengths and a small range of lateral excitation near the bifurcation to an amplitude instability. The computation of AM in higher order areas was due to the neurons in these areas having large receptive fields as a consequence of divergent feed-forward connectivity. This implies that these areas compute long-range AM when early areas 17 and 18 do not, and therefore higher order areas must enslave lower order areas to compute the same, if the whole network is to arrive at a coherent perceptual solution. [Copyright &y& Elsevier]

Published

2010

20. Feed-forward, feedback and lateral interactions in membrane potentials and spike trains from the visual cortex in vivo

Author

Eriksson, David and Roland, Per

Subjects

*VISUAL cortex, *NEURONS, *CELLS, *NERVOUS system

Abstract

Abstract: Neurons in the visual cortex receive input from the lateral geniculate nucleus (feed-forward), higher order visual areas (feedback) and local neurons in the surroundings (lateral interactions). Here we first briefly review the approximate timing and proportion of these three types of influences on the membrane potentials in visual areas 17, 18 and 19. Then we present original results from an independent component analysis of multiunit spike trains in the same visual areas to resolve the contribution from these three sources. We stimulated the visual cortex of the ferret with a small transient contrast square stimulus and recorded the multiunit activity in areas 17, 18 and 19 with single or multiple electrodes. The spike trains had three reproducible components having their maxima at 40, 55 and 105ms after the start of the presentation of the stimulus. The time course of the third component was significantly correlated with the population membrane potential in the supragranular layers of areas 17, 18 and 19. The first spike train component was interpreted as a feed-forward response, the second spike train component as driving the laterally spreading depolarization and the third spike train component as the firing caused by the lateral spreading- and the feedback depolarization. [Copyright &y& Elsevier]

Published

2006

21. Cardiac tissue geometry as a determinant of unidirectional conduction block: assessment of microscopic excitation spread by optical mapping in patterned cell cultures and in a computer model.

Author

Fast, Vladimir G and Kléber, André G

Abstract

Objective: Unidirectional conduction block (UCB) and reentry may occur as a consequence of an abrupt tissue expansion and a related change in the electrical load. The aim of this study was to evaluate critical dimensions of the tissue necessary for establishing UCB in heart cell culture. Methods: Neonatal rat heart cell cultures with cell strands of variable width emerging into a large cell area were grown using a technique of patterned cell growth. Action potential upstrokes were measured using a voltage sensitive dye (RH-237) and a linear array of 10 photodiodes with a 15 μm resolution. A mathematical model was used to relate action potential wave shapes to underlying ionic currents. Results: UCB (block of a single impulse in anterograde direction — from a strand to a large area — and conduction in the retrograde direction) occurred in narrow cell strands with a width of 15(SD 4) μm (1–2 cells in width, n = 7) and there was no conduction block in strands with a width of 31(8) μm (n = 9, P < 0.001) or larger. The analysis of action potential waveshapes indicated that conduction block was either due to geometrical expansion alone (n = 5) or to additional local depression of conduction (n = 2). In wide strands, action potential upstrokes during anterograde conduction were characterised by multiple rising phases. Mathematical modelling showed that two rising phases were caused by electronic current flow, whereas local ionic current did not coincide with the rising portions of the upstrokes. Conclusions: (1) High resolution optical mapping shows multiphasic action potential upstrokes at the region of abrupt expansion. At the site of the maximum decrement in conduction, these peaks were largely determined by the electrotonus and not by the local ionic current. (2) Unidirectional conduction block occurred in strands with a width of 15(4) μm (1–2 cells). [ABSTRACT FROM PUBLISHER]

Published

1995

22. In vivo tracing of pathways and spatio-temporal activity patterns in rat visual cortex using voltage sensitive dyes.

Author

Orbach, H. and Essen, D.

Abstract

We monitored optical signals from cortex stained with a voltage sensitive dye to study activity evoked by intracortical electrical stimulation. The objectives were to study the spatial and temporal spread of activity from intrinsic connections near the stimulating electrode and to develop a new technique to study extrinsic projections from striate cortex to extrastriate target areas. Various measures were made of the time course of the optical signal (latency, rise time, decay time, temporal summation, facilitation versus depression, and presence or absence of a slow undershoot); in general, these measures were found to vary significantly across different response positions, different experiments, and even different runs within the same experiment. The spatial distribution of responses near the stimulating electrode in striate cortex was usually elliptical and was most often elongated along the anterior-posterior axis, with a typical size (full width at 75% max) of 1.3 mm (anterior-posterior axis) by 0.75 mm (medio-lateral axis). In some cases, complex spatio-temporal patterns were observed, in which the position of the maximum optical signal shifted with time or split into multiple peaks. In eight experiments, a response focus was found in extrastriate cortex at an expected location within the lateromedial area (LM). The response focus in LM was typically about half the size of that in striate cortex. In some experiments we observed additional focal responses in the anterolateral visual area (AL). The extrastriate responses showed a significant delay (3-10 ms) in onset and time to peak relative to the striate response. The validity of this technique for determining extrinsic projections was tested in two types of experiments. In the first, stimulation from two electrodes in striate cortex generated response foci consistent with the known topographic organization of area LM. In the second, the optically measured response focus was shown to correlate with the histologically reconstructed projection of a chemical tracer injected near the site of stimulation. We discuss the chain of neurophysiological events that occur during and after focal electrical stimulation and how they relate to the observed optical signal. We conclude that direct passive responses were a small component of our signal, that the component due to action potentials in directly stimulated neurons should have occurred in the first 1-2 ms post stimulus and is small compared to the peak signal, and that overall our signals were probably dominated by a combination of asynchronously occurring action potentials and excitatory and inhibitory synaptic potentials. These results, together with the prospect of being able to trace many connections in a single experiment, indicate that the combination of optical recording and focal electrical stimulation provides a valuable means for analyzing structural and physiological aspects of cortical circuitry. [ABSTRACT FROM AUTHOR]

Published

1993

23. Design and use of an 'optrode' for optical recordings of cardiac action potentials.

Author

Neunlist, Michel, Zou, Sha-zhou, and Tung, Leslie

Abstract

An optical method was used to measure action potentials from frog ventricle, in vitro, under normal physiological conditions with 0.5-1 mM Ca Ringer's solution. The approach presented in this paper involves a portable fluorimeter coupled to a multimode optical fiber running into a glass pipette ('optrode') to carry both excitation light to and fluorescence from the ventricle stained with the voltage sensitive dye di-4-ANEPPS. A suction technique was used to stabilize the optrode-tissue interface, significantly reducing motion artifacts from the beating ventricle. The typical fractional change in fluorescence intensity for an action potential was −9%. The optical recordings faithfully reproduced membrane action potentials as measured with microelectrode recordings. To confirm further the validity of our method we studied the effect of an increasing stimulation rate on the optical action potential. The amplitude of the action potential did not increase, and the change in action potential duration was similar to published results obtained with microelectrode recordings, suggesting that our optical action potentials are relatively free of motion artifacts. Finally, our optical recordings suggest that during anodal and cathodal point stimulation, the time course of membrane potential differs from that predicted simply by a passive cable model. [ABSTRACT FROM AUTHOR]

Published

1992

24. Nanoscale optical voltage sensing in biological systems.

Author

Goris, Toon, Langley, Daniel P., Stoddart, Paul R., and del Rosal, Blanca

Subjects

*BIOLOGICAL systems, *CELL communication, *ELECTRIC fields, *KNOWLEDGE gap theory, *CELL membranes, *VOLTAGE-gated ion channels

Abstract

Local electric fields modulate a variety of cellular processes and are particularly relevant in the nervous system. Signal propagation along an axon occurs through small (around 100 mV) rapid changes in the potential across the cell membrane. Experimental techniques capable of measuring voltage changes in cells, tissue, and animal models have been instrumental in understanding cell signaling in the nervous system. Optical approaches relying on fluorescent voltage sensors have emerged as a minimally invasive – and less technically demanding – alternative to traditional, electrode-based techniques. Combined with state-of-the-art optical microscopy techniques, luminescent voltage sensors allow voltage sensing at relevant timescales (sub-millisecond) and diffraction-limited spatial resolutions. Voltage-sensitive dyes and proteins are already well-established fluorescent voltage sensors, while semiconductor nanostructures and nitrogen vacancy-containing diamonds are attracting increasing attention due to their superior photoluminescent properties. In this review, we describe the working mechanism of the different classes of fluorescent voltage sensors, discuss their advantages and limitations, and compare their performance based on sensitivity and temporal resolution. Further, we discuss the more recent advances in optical voltage sensing and identify the knowledge gaps that need to be addressed for this technique to realize its full potential as a valid replacement to electrode-based sensing. • The state of the art in photoluminescent voltage sensing is discussed. • We describe the working mechanism of different photoluminescent voltage sensors. • We compare the performance of molecular and nanoparticle-based voltage sensors. • We summarize the approaches for calibrating sensors and their limitations. • We discuss the current limitations of photoluminescent voltage sensors. [ABSTRACT FROM AUTHOR]

Published

2021

25. Fluorescence-based automated screening assay for the study of the pH-sensitive channel ASIC1a

Author

Lia Forti, Roberta De Ceglia, Davide Mazza, Luca Muzio, Nausicaa Mazzocchi, Andrea Menegon, Mazzocchi, N, De Ceglia, R, Mazza, D, Forti, L, Muzio, L, and Menegon, A

Subjects

0301 basic medicine, Patch-Clamp Techniques, Computer science, Primary Cell Culture, Spider Venoms, Pyridinium Compounds, Nanotechnology, CHO Cells, Computational biology, Biochemistry, Cell Line, Styrenes, Analytical Chemistry, Mice, 03 medical and health sciences, Cricetulus, 0302 clinical medicine, ASIC1a, Animals, Permeable channel, Transgenes, Screening procedures, Ion channel, Fluorescent Dyes, Pyrans, Automation, Laboratory, Cerebral Cortex, Neurons, Drug discovery, screening, Sodium, Screening assay, Cations, Monovalent, Hydrogen-Ion Concentration, Inflammatory pain, Fluorescence, Voltage-Sensitive Dye Imaging, High-Throughput Screening Assays, Acid Sensing Ion Channels, Mice, Inbred C57BL, 030104 developmental biology, voltage sensitive dyes, Molecular Medicine, Peptides, Diminazene, 030217 neurology & neurosurgery, Biotechnology, Communication channel

Abstract

Acid-sensing ion channel 1a (ASIC1a) is involved in several pathologies, including neurodegenerative and neuroinflammatory disorders, stroke, epilepsy, and inflammatory pain. ASIC1a has been the subject of intense drug discovery programs devoted to the development of new pharmacological tools for its modulation. However, these efforts to generate new compounds have faced the lack of an efficient screening procedure. In the past decades, improvements in screening technologies and fluorescent sensors for the study of ion channels have provided new opportunities in this field. Unfortunately, ASIC1a is mainly a Na(+) permeable channel and undergoes desensitization after its activation, two features that make the use of the available screening procedures problematic. We propose here a novel screening approach for the study of ASIC1a activity in full automation. Our method is based on the stimulation of ASIC1a-expressing cells by protons and the use of electrochromic fluorescent voltage sensors as a readout of ion channel activation. This method will prove to be useful for drug screening programs aimed at ASIC1a modulation.

Published

2016

26. Review paper Recording of the neuronal activity in the gastrointestinal tract using the Multisite Optical Recording Technique (MSORT)

Author

Michał Ceregrzyn, Klaus Michel, and Michael Schemann

Subjects

enteric nervous system, neuroimaging, voltage sensitive dyes, lcsh:R, lcsh:Medicine, fast excitatory postsynaptic potential, myenteric plexus

Abstract

The Enteric Nervous System (ENS) plays a key role in regulating the function of the gastrointestinal tract. The knowledge about the function of neurons is based on experiments using the intracellular recording method. Limitations of the method have become a stimulus for developing an alternative technique that would record cell membrane potential changes without mechanical interruption and with no cells bias due to their size. The recently developed neuroimaging method meets these demands. The principle of the technique is based on fluorescence of voltage sensitive dyes (VSD) specific molecules that incorporated in cell membranes react to their potential. Photodiode arrays or charge-coupled device (CCD) cameras can be used for acquiring the fluorescent light that permits to monitor fast changes in membrane potential. The Multisite Optical Recording Technique (MSORT) is capable of recording changes in membrane potential in all neurons in the ENS with sufficient spatial and temporal resolution. Studies published up to date are very promising and give an interesting view on the function of neurons in the ENS.

Published

2005

27. Spatiotemporal properties of sensory responses in vivo are strongly dependent on network context

Author

Diego Contreras and Eugene F. Civillico

Subjects

Mouse, Cognitive Neuroscience, Voltage-sensitive dye, Neuroscience (miscellaneous), Context (language use), Sensory system, Local field potential, spatiotemporal dynamics, lcsh:RC321-571, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Developmental Neuroscience, medicine, Oscillation (cell signaling), Original Research Article, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, 030304 developmental biology, 0303 health sciences, Neocortex, Network State, Depolarization, Barrel cortex, ongoing activity, in vivo, medicine.anatomical_structure, voltage sensitive dyes, barrel cortex, Psychology, Neuroscience, 030217 neurology & neurosurgery

Abstract

Sensory responses in neocortex are strongly modulated by changes in brain state, such as those observed between sleep stages or attentional levels. However, the specific effects of network state changes on the spatiotemporal properties of sensory responses are poorly understood. The slow oscillation, which is observed in neocortex under ketamine-xylazine anesthesia and is characterized by alternating depolarizing (up-states) and hyperpolarizing (down-states) phases, provides an opportunity to study the state-dependence of primary sensory responses in large networks. Here we used voltage sensitive dye (VSD) imaging to record the spatiotemporal properties of sensory responses and local field potential (LFP) and multiunit activity (MUA) recordings to monitor the ongoing brain state in which the sensory responses occurred. Despite a rich variability of slow oscillation patterns, sensory responses showed a consistent relationship with the ongoing oscillation and triggered a new up-state only after the termination of the refractory period that followed the preceding oscillatory cycle. We show that spatiotemporal properties of whisker-evoked responses are highly dependent on their timing with regard to the ongoing oscillation. In both the up- and down-states, responses spread across large portions of the barrel field, although the up-state responses were reduced in total area due to their sparseness. The depolarizing response in the up-state showed a tendency to propagate along the rows, with an amplitude and slope favoring the higher-numbered arcs. In the up-state, but not in the down-state, the depolarizing response was followed by a hyperpolarizing wave with a consistent spatial structure. We measured the suppression of whisker-evoked responses by a preceding response at 100 ms, and found that suppression showed the same spatial asymmetry as the depolarization. Because the resting level of cells in the up-state is likely to be closer to that in the awake animal, we suggest that the polarities in signal propagation which we observed in the up-state could be used as computational mechanisms in the behaving animal. These results demonstrate the critical importance of ongoing network activity on the dynamics of sensory responses and their integration.

Published

2012

28. Spatiotemporal properties of sensory responses in vivo are strongly dependent on network context.

Author

Civillico EF and Contreras D

Abstract

Sensory responses in neocortex are strongly modulated by changes in brain state, such as those observed between sleep stages or attentional levels. However, the specific effects of network state changes on the spatiotemporal properties of sensory responses are poorly understood. The slow oscillation, which is observed in neocortex under ketamine-xylazine anesthesia and is characterized by alternating depolarizing (up-states) and hyperpolarizing (down-states) phases, provides an opportunity to study the state-dependence of primary sensory responses in large networks. Here we used voltage sensitive dye (VSD) imaging to record the spatiotemporal properties of sensory responses and local field potential (LFP) and multiunit activity (MUA) recordings to monitor the ongoing brain state in which the sensory responses occurred. Despite a rich variability of slow oscillation patterns, sensory responses showed a consistent relationship with the ongoing oscillation and triggered a new up-state only after the termination of the refractory period that followed the preceding oscillatory cycle. We show that spatiotemporal properties of whisker-evoked responses are highly dependent on their timing with regard to the ongoing oscillation. In both the up- and down-states, responses spread across large portions of the barrel field, although the up-state responses were reduced in total area due to their sparseness. The depolarizing response in the up-state showed a tendency to propagate along the rows, with an amplitude and slope favoring the higher-numbered arcs. In the up-state, but not in the down-state, the depolarizing response was followed by a hyperpolarizing wave with a consistent spatial structure. We measured the suppression of whisker-evoked responses by a preceding response at 100 ms, and found that suppression showed the same spatial asymmetry as the depolarization. Because the resting level of cells in the up-state is likely to be closer to that in the awake animal, we suggest that the polarities in signal propagation which we observed in the up-state could be used as computational mechanisms in the behaving animal. These results demonstrate the critical importance of ongoing network activity on the dynamics of sensory responses and their integration.

Published

2012

29. Měření membránového napětí pomocí napěťově citlivých barviv ve fluorescenční mikroskopii

Author

Čmiel, Vratislav, Janoušek, Oto, Čmiel, Vratislav, and Janoušek, Oto

Abstract

Cílem této práce je sestavit literární rešerši v oblasti měření membránového napětí pomocí napěťově citlivých barviv a navrhnout postup měření membránového napětí na dostupných buňkách s využitím napěťově citlivého barviva di-4-ANEPPS a realizovat ho. Práce obsahuje úvod do elektrofyziologie živočišných buněk, vysvětluje fluorescenci a její typické vlastnosti a věnuje se popisu fluorescenčního mikroskopu. Dokument se z části věnuje charakterizaci a rozdělení napěťově citlivých barviv. Velká část práce obsahuje popis realizace a měření experimentu. V dokumentu jsou také zahrnuty různé metody měření a zpracování všech výsledků., The aim of this work is to make a literature search in the measurement of membrane voltage using voltage-sensitive dyes and suggest a method for measuring the membrane voltage on the available cells using the voltage-sensitive dye di 4 ANEPPS and its further implementation. The work contains an introduction to electrophysiology of cells, and explains typical fluorescence characteristics. The thesis contains the description of a fluorescence microscope. The document presents characteristics of voltage-sensitive dyes and their distribution. A large part of the work describes the implementation and measurement of the experiment. The document also includes different methods for measuring and processing of all results.

30. Měření spektrálních charakteristik fluorescenčních napěťově-citlivých barviv

Author

Provazník, Ivo, Čmiel, Vratislav, Provazník, Ivo, and Čmiel, Vratislav

Abstract

Práce se zabývá optickým měřením vlastností látek s využitím absorpční a fluorescenční spektroskopie. Je zde vysvětlen princip fluorescence, který má přímou souvislost s měřením spektrálních charakteristik tzv. napěťově-citlivých barviv (konkrétně di-4-ANEPPS). Toto barvivo se používá pro bezkontaktní (optické) snímání elektrické aktivity organismu, přičemž se využívá jeho napěťově závislého spektrálního posunu po navázání na buněčnou membránu. Správná aplikace tohoto fluorescenčního barviva je však závislá na mnoha faktorech – jedním z nich je zde diskutovaná a proměřená spektrální závislost na bezprostředním okolí použitého fluorescenčního barviva di-4-ANEPPS., This bachelor thesis deals with optical measurement of substances properties in practical service of absorption and fluorescent spectroscopy. The work specifies the principle of fluorescence, which has direct association with spectral characteristics measurement of so-called voltage-sensitive dyes (in this instance di-4-ANEPPS). This dye is used for contactless (optical) imaging of organisms electric activity in practical service of its voltage dependent spectral shift after binding itself on cell membrane. However, the right application of this fluorescent dye is dependent on too many factors – one of them, discussed and measured in this work, is di-4-ANEPPS spectral dependency on its immediate environment.

31. Měření spektrálních charakteristik fluorescenčních napěťově-citlivých barviv

Author

Provazník, Ivo, Čmiel, Vratislav, Provazník, Ivo, and Čmiel, Vratislav

Abstract

Práce se zabývá optickým měřením vlastností látek s využitím absorpční a fluorescenční spektroskopie. Je zde vysvětlen princip fluorescence, který má přímou souvislost s měřením spektrálních charakteristik tzv. napěťově-citlivých barviv (konkrétně di-4-ANEPPS). Toto barvivo se používá pro bezkontaktní (optické) snímání elektrické aktivity organismu, přičemž se využívá jeho napěťově závislého spektrálního posunu po navázání na buněčnou membránu. Správná aplikace tohoto fluorescenčního barviva je však závislá na mnoha faktorech – jedním z nich je zde diskutovaná a proměřená spektrální závislost na bezprostředním okolí použitého fluorescenčního barviva di-4-ANEPPS., This bachelor thesis deals with optical measurement of substances properties in practical service of absorption and fluorescent spectroscopy. The work specifies the principle of fluorescence, which has direct association with spectral characteristics measurement of so-called voltage-sensitive dyes (in this instance di-4-ANEPPS). This dye is used for contactless (optical) imaging of organisms electric activity in practical service of its voltage dependent spectral shift after binding itself on cell membrane. However, the right application of this fluorescent dye is dependent on too many factors – one of them, discussed and measured in this work, is di-4-ANEPPS spectral dependency on its immediate environment.

32. Měření membránového napětí pomocí napěťově citlivých barviv ve fluorescenční mikroskopii

Author

Čmiel, Vratislav, Janoušek, Oto, Čmiel, Vratislav, and Janoušek, Oto

Abstract

Cílem této práce je sestavit literární rešerši v oblasti měření membránového napětí pomocí napěťově citlivých barviv a navrhnout postup měření membránového napětí na dostupných buňkách s využitím napěťově citlivého barviva di-4-ANEPPS a realizovat ho. Práce obsahuje úvod do elektrofyziologie živočišných buněk, vysvětluje fluorescenci a její typické vlastnosti a věnuje se popisu fluorescenčního mikroskopu. Dokument se z části věnuje charakterizaci a rozdělení napěťově citlivých barviv. Velká část práce obsahuje popis realizace a měření experimentu. V dokumentu jsou také zahrnuty různé metody měření a zpracování všech výsledků., The aim of this work is to make a literature search in the measurement of membrane voltage using voltage-sensitive dyes and suggest a method for measuring the membrane voltage on the available cells using the voltage-sensitive dye di 4 ANEPPS and its further implementation. The work contains an introduction to electrophysiology of cells, and explains typical fluorescence characteristics. The thesis contains the description of a fluorescence microscope. The document presents characteristics of voltage-sensitive dyes and their distribution. A large part of the work describes the implementation and measurement of the experiment. The document also includes different methods for measuring and processing of all results.

33. Měření membránového napětí pomocí napěťově citlivých barviv ve fluorescenční mikroskopii

Author

Čmiel, Vratislav, Janoušek, Oto, Čmiel, Vratislav, and Janoušek, Oto

Abstract

Cílem této práce je sestavit literární rešerši v oblasti měření membránového napětí pomocí napěťově citlivých barviv a navrhnout postup měření membránového napětí na dostupných buňkách s využitím napěťově citlivého barviva di-4-ANEPPS a realizovat ho. Práce obsahuje úvod do elektrofyziologie živočišných buněk, vysvětluje fluorescenci a její typické vlastnosti a věnuje se popisu fluorescenčního mikroskopu. Dokument se z části věnuje charakterizaci a rozdělení napěťově citlivých barviv. Velká část práce obsahuje popis realizace a měření experimentu. V dokumentu jsou také zahrnuty různé metody měření a zpracování všech výsledků., The aim of this work is to make a literature search in the measurement of membrane voltage using voltage-sensitive dyes and suggest a method for measuring the membrane voltage on the available cells using the voltage-sensitive dye di 4 ANEPPS and its further implementation. The work contains an introduction to electrophysiology of cells, and explains typical fluorescence characteristics. The thesis contains the description of a fluorescence microscope. The document presents characteristics of voltage-sensitive dyes and their distribution. A large part of the work describes the implementation and measurement of the experiment. The document also includes different methods for measuring and processing of all results.

34. Měření spektrálních charakteristik fluorescenčních napěťově-citlivých barviv

Author

Provazník, Ivo, Čmiel, Vratislav, Pavlík, Dušan, Provazník, Ivo, Čmiel, Vratislav, and Pavlík, Dušan

Abstract

Práce se zabývá optickým měřením vlastností látek s využitím absorpční a fluorescenční spektroskopie. Je zde vysvětlen princip fluorescence, který má přímou souvislost s měřením spektrálních charakteristik tzv. napěťově-citlivých barviv (konkrétně di-4-ANEPPS). Toto barvivo se používá pro bezkontaktní (optické) snímání elektrické aktivity organismu, přičemž se využívá jeho napěťově závislého spektrálního posunu po navázání na buněčnou membránu. Správná aplikace tohoto fluorescenčního barviva je však závislá na mnoha faktorech – jedním z nich je zde diskutovaná a proměřená spektrální závislost na bezprostředním okolí použitého fluorescenčního barviva di-4-ANEPPS., This bachelor thesis deals with optical measurement of substances properties in practical service of absorption and fluorescent spectroscopy. The work specifies the principle of fluorescence, which has direct association with spectral characteristics measurement of so-called voltage-sensitive dyes (in this instance di-4-ANEPPS). This dye is used for contactless (optical) imaging of organisms electric activity in practical service of its voltage dependent spectral shift after binding itself on cell membrane. However, the right application of this fluorescent dye is dependent on too many factors – one of them, discussed and measured in this work, is di-4-ANEPPS spectral dependency on its immediate environment.

35. Měření membránového napětí pomocí napěťově citlivých barviv ve fluorescenční mikroskopii

Author

Čmiel, Vratislav, Janoušek, Oto, Tkáč, Jan, Čmiel, Vratislav, Janoušek, Oto, and Tkáč, Jan

Abstract

Cílem této práce je sestavit literární rešerši v oblasti měření membránového napětí pomocí napěťově citlivých barviv a navrhnout postup měření membránového napětí na dostupných buňkách s využitím napěťově citlivého barviva di-4-ANEPPS a realizovat ho. Práce obsahuje úvod do elektrofyziologie živočišných buněk, vysvětluje fluorescenci a její typické vlastnosti a věnuje se popisu fluorescenčního mikroskopu. Dokument se z části věnuje charakterizaci a rozdělení napěťově citlivých barviv. Velká část práce obsahuje popis realizace a měření experimentu. V dokumentu jsou také zahrnuty různé metody měření a zpracování všech výsledků., The aim of this work is to make a literature search in the measurement of membrane voltage using voltage-sensitive dyes and suggest a method for measuring the membrane voltage on the available cells using the voltage-sensitive dye di 4 ANEPPS and its further implementation. The work contains an introduction to electrophysiology of cells, and explains typical fluorescence characteristics. The thesis contains the description of a fluorescence microscope. The document presents characteristics of voltage-sensitive dyes and their distribution. A large part of the work describes the implementation and measurement of the experiment. The document also includes different methods for measuring and processing of all results.