Biology:Voltage-sensitive dye

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Voltage-sensitive dyes, also known as potentiometric dyes, are dyes which change their spectral properties in response to voltage changes.[1] They are able to provide linear measurements of firing activity of single neurons, large neuronal populations or activity of myocytes. Many physiological processes are accompanied by changes in cell membrane potential which can be detected with voltage sensitive dyes. Measurements may indicate the site of action potential origin, and measurements of action potential velocity and direction may be obtained.[2]

Potentiometric dyes are used to monitor the electrical activity inside cell organelles where it is not possible to insert an electrode, such as the mitochondria and dendritic spine. This technology is especially powerful for the study of patterns of activity in complex multicellular preparations. It also makes possible the measurement of spatial and temporal variations in membrane potential along the surface of single cells.

Types of dyes

Pioneers of voltage-sensitive dyes: A. Grinvald, L.B. Cohen, K. Kamino, B.M. Salzberg, W.N. Ross; Tokyo, 2000

Fast-response probes: These are amphiphilic membrane staining dyes which usually have a pair of hydrocarbon chains acting as membrane anchors and a hydrophilic group which aligns the chromophore perpendicular to the membrane/aqueous interface. The chromophore is believed to undergo a large electronic charge shift as a result of excitation from the ground to the excited state and this underlies the putative electrochromic mechanism for the sensitivity of these dyes to membrane potential. This molecule (dye) intercalates among the lipophilic part of biological membranes. This orientation assures that the excitation induced charge redistribution will occur parallel to the electric field within the membrane. A change in the voltage across the membrane will therefore cause a spectral shift resulting from a direct interaction between the field and the ground and excited state dipole moments.

New voltage dyes can sense voltage with high speed and sensitivity using photoinduced electron transfer (PeT) through a conjugated molecular wire.[3][4]

Slow-response probes: These exhibit potential-dependent changes in their transmembrane distribution which are accompanied by a fluorescence change. Typical slow-response probes include cationic carbocyanines and rhodamines, and ionic oxonols.

Examples

Commonly used voltage sensitive dyes are substituted aminonaphthylethenylpyridinium (ANEP) dyes, such as di-4-ANEPPS, di-8-ANEPPS, and RH237. Depending on their chemical modifications which change their physical properties they are used for different experimental procedures.[5] They were first described in 1985 by the research group of Leslie Loew.[6] ANNINE-6plus is a voltage sensitive dye with fast response (ns response time) and high sensitivity. It has been applied to measure the action potentials of a single t-tubule of cardiomyocytes by Guixue Bu et al.[7] More recently, a series of fluorinated ANEP dyes was introduced that offer enhanced sensitivity and photostability; they are also available over a wide choice of excitation and emission wavelengths.[8] A recent computational study confirmed that the ANEP dyes are affected only by the electrostatic environment and not by specific molecular interactions.[9] Other structural scaffolds, such as xanthenes,[10] are also successfully used.

Materials

The core material for imaging brain activity with voltage-sensitive dyes are the dyes themselves. These voltage-sensitive dyes are lipophilic and preferably localized in membranes with their hydrophobic tails. They are used in applications involving fluorescence or absorption; they are fast acting and are able to provide linear measurements of changes in membrane potential.[11] Voltage sensitive dyes are supplied by many companies who offer fluorescent probes for biological applications. Potentiometric Probes, LLC specializes only in voltage sensitive dyes; they have an exclusive license to distribute the large set of fluorinated VSDs, marketed under the ElectroFluor brand.

A variety of specialized equipment may be used in conjunction with the dyes, and choices in equipment will vary according to the particularities of a preparation. Essentially, equipment will include specialized microscopes and imaging devices, and may include technical lamps or lasers.[11]

Strengths and weaknesses

Strengths of imaging brain activity with voltage-sensitive dyes include the following abilities:

  • Measurement of population signals from many areas may be taken simultaneously, and hundreds of neurons may be recorded from. Such multisite recordings may provide precise information on action potential initiation and propagation (including direction and velocity), and on the entire branching structure of a neuron.[11]
  • Measurements of spike activity in a ganglion that is producing behaviour can be taken and may provide information about how the behaviour is producing.[11]
  • In certain preparations the pharmacological effects of the dyes may be completely reversed by removing the staining pipette and allowing the neuron 1–2 hours for recovery.[11]
  • Dyes may be used to analyze signal integration in terminal dendritic branches. Voltage-sensitive dyes offer the only alternative to genetically encoded voltage sensitive proteins (such as Ci-VSP derived proteins) for doing this.[11]
  • More soluble dyes such as ElectroFluor-530s, or di-2-ANEPEQ may perfused internally into single cell through a patch pipet. This technique has permitted the study of electrical signals in individual dendrites[12][13] and dendritic spines[14][15][16][17] within brain slices.

Weaknesses of imaging brain activity with voltage-sensitive dyes include the following problems:

  • Voltage-sensitive dyes may respond very differently from one preparation to another; typically tens of dyes must be tested in order to obtain an optimal signal.,[11] imaging parameters, such as excitation wavelength, emission wavelength, exposure time, should also be optimized.
  • Voltage-sensitive dyes often fail to penetrate through connective tissue or move through intracellular spaces to the region of membrane desired for study.[11] Staining is a serious issue in applications of these dyes. Water-soluble dyes, such as ANNINE-6plus, ElectroFluor-530s, or di-2-ANEPEQ, do not suffer this problem.
  • On the other hand, if the dyes are too water-soluble, staining may not persist. This can be addressed by utilizing dyes containing longer alkyl chains to increase lipophilicity.
  • Noise is a problem in all preparations with voltage-sensitive dyes and in certain preparations the signal may be significantly obscured.[11] Signal to noise ratios can be improved with spatial filtering or temporal filtering algorithms. Many such algorithms exist; one signal processing algorithm can be found in recent work with the ANNINE-6plus dye.[7]
  • Cells may be permanently affected by treatments. Lasting pharmacological effects are possible, and the photodynamics of the dyes can be damaging.[11] Recently developed fuorinated voltages sensitive dyes have been shown to mitigate these effects.[8][18]

Uses

Voltage-sensitive dyes have been used to measure neural activity in several areas of the nervous system in a variety of organisms, including the squid giant axon,[19] whisker barrels of the rat somatosensory cortex,[20][21] olfactory bulb of the salamander,[22][23][24] visual cortex of the cat,[25] optic tectum of the frog,[26] and the visual cortex of the rhesus monkey.[27][28]

Many applications in cardiac electrophysiology have been published, including ex vivo mapping of electrical activity in whole hearts from various animal species,[29][30] subcellular imaging from single cardiomyocytes,[31] and even mapping both sinus rhythms and arrhytmias in open heart in vivo pig,[18] where motion artifacts could be eliminated by dual wavelength ratio imaging of the voltage sensitive dye fluorescence.

References

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  2. "Optical measurement of membrane potential". Reviews of Physiology, Biochemistry and Pharmacology 83: 35–88. 1978. doi:10.1007/3-540-08907-1_2. ISBN 978-3-540-08907-0. PMID 360357. 
  3. "Improved PeT molecules for optically sensing voltage in neurons". Journal of the American Chemical Society 137 (5): 1817–1824. February 2015. doi:10.1021/ja510602z. PMID 25584688. 
  4. "Locally Excited State-Charge Transfer State Coupled Dyes as Optically Responsive Neuron Firing Probes". Chemistry: A European Journal 23 (58): 14639–14649. October 2017. doi:10.1002/chem.201703366. PMID 28833695. https://publications.aston.ac.uk/id/eprint/40362/1/Locally_Excited_State_Charge_Transfer_State.pdf. 
  5. "Potential-Sensitive ANEP Dyes". Invitrogen. 24 March 2006. https://assets.thermofisher.com/TFS-Assets/LSG/manuals/mp01199.pdf. 
  6. "Spectra, membrane binding, and potentiometric responses of new charge shift probes". Biochemistry 24 (21): 5749–5755. October 1985. doi:10.1021/bi00342a010. PMID 4084490. 
  7. 7.0 7.1 "Uniform action potential repolarization within the sarcolemma of in situ ventricular cardiomyocytes". Biophysical Journal 96 (6): 2532–2546. March 2009. doi:10.1016/j.bpj.2008.12.3896. PMID 19289075. Bibcode2009BpJ....96.2532B. 
  8. 8.0 8.1 "Palette of fluorinated voltage-sensitive hemicyanine dyes". Proceedings of the National Academy of Sciences of the United States of America 109 (50): 20443–20448. December 2012. doi:10.1073/pnas.1214850109. PMID 23169660. Bibcode2012PNAS..10920443Y. 
  9. "Di-8-ANEPPS emission spectra in phospholipid/cholesterol membranes: a theoretical study". The Journal of Physical Chemistry B 115 (14): 4160–4167. April 2011. doi:10.1021/jp1111372. PMID 21425824. 
  10. Fiala, Tomas; Wang, Jihang; Dunn, Matthew; Šebej, Peter; Choi, Se Joon; Nwadibia, Ekeoma C.; Fialova, Eva; Martinez, Diana M. et al. (2020-05-20). "Chemical Targeting of Voltage Sensitive Dyes to Specific Cells and Molecules in the Brain" (in en). Journal of the American Chemical Society 142 (20): 9285–9301. doi:10.1021/jacs.0c00861. ISSN 0002-7863. PMID 32395989. 
  11. 11.0 11.1 11.2 11.3 11.4 11.5 11.6 11.7 11.8 11.9 "Imaging brain activity with voltage- and calcium-sensitive dyes". Cellular and Molecular Neurobiology 25 (2): 245–282. March 2005. doi:10.1007/s10571-005-3059-6. PMID 16050036. 
  12. "Multiple spike-initiation zones in single neurons revealed by voltage-sensitive dyes". Nature 381 (6580): 322–325. May 1996. doi:10.1038/381322a0. PMID 8692270. Bibcode1996Natur.381..322Z. 
  13. "Dynamics of action potential backpropagation in basal dendrites of prefrontal cortical pyramidal neurons". The European Journal of Neuroscience 27 (4): 923–936. February 2008. doi:10.1111/j.1460-9568.2008.06075.x. PMID 18279369. 
  14. "Membrane potential changes in dendritic spines during action potentials and synaptic input". The Journal of Neuroscience 29 (21): 6897–6903. May 2009. doi:10.1523/JNEUROSCI.5847-08.2009. PMID 19474316. 
  15. "Single-voxel recording of voltage transients in dendritic spines". Biophysical Journal 101 (2): L11–L13. July 2011. doi:10.1016/j.bpj.2011.06.021. PMID 21767473. Bibcode2011BpJ...101L..11A. 
  16. "EPSPs Measured in Proximal Dendritic Spines of Cortical Pyramidal Neurons". eNeuro 3 (2): ENEURO.0050–15.2016. March 2016. doi:10.1523/ENEURO.0050-15.2016. PMID 27257618. 
  17. "Electrical behaviour of dendritic spines as revealed by voltage imaging". Nature Communications 6 (1): 8436. October 2015. doi:10.1038/ncomms9436. PMID 26436431. Bibcode2015NatCo...6.8436P. 
  18. 18.0 18.1 "In vivo ratiometric optical mapping enables high-resolution cardiac electrophysiology in pig models". Cardiovascular Research 115 (11): 1659–1671. September 2019. doi:10.1093/cvr/cvz039. PMID 30753358. 
  19. "VSDI: a new era in functional imaging of cortical dynamics". Nature Reviews. Neuroscience 5 (11): 874–885. November 2004. doi:10.1038/nrn1536. PMID 15496865. 
  20. "Spatiotemporal dynamics of sensory responses in layer 2/3 of rat barrel cortex measured in vivo by voltage-sensitive dye imaging combined with whole-cell voltage recordings and neuron reconstructions". The Journal of Neuroscience 23 (4): 1298–1309. February 2003. doi:10.1523/JNEUROSCI.23-04-01298.2003. PMID 12598618. 
  21. "Functionally independent columns of rat somatosensory barrel cortex revealed with voltage-sensitive dye imaging". The Journal of Neuroscience 21 (21): 8435–8446. November 2001. doi:10.1523/JNEUROSCI.21-21-08435.2001. PMID 11606632. 
  22. "Salamander olfactory bulb neuronal activity observed by video rate, voltage-sensitive dye imaging. III. Spatial and temporal properties of responses evoked by odorant stimulation". Journal of Neurophysiology 73 (5): 2053–2071. May 1995. doi:10.1152/jn.1995.73.5.2053. PMID 7542699. 
  23. "Salamander olfactory bulb neuronal activity observed by video rate, voltage-sensitive dye imaging. II. Spatial and temporal properties of responses evoked by electric stimulation". Journal of Neurophysiology 73 (5): 2033–2052. May 1995. doi:10.1152/jn.1995.73.5.2033. PMID 7623098. 
  24. "Salamander olfactory bulb neuronal activity observed by video rate, voltage-sensitive dye imaging. I. Characterization of the recording system". Journal of Neurophysiology 73 (5): 2017–2032. May 1995. doi:10.1152/jn.1995.73.5.2017. PMID 7542698. 
  25. "Dynamics of ongoing activity: explanation of the large variability in evoked cortical responses". Science 273 (5283): 1868–1871. September 1996. doi:10.1126/science.273.5283.1868. PMID 8791593. Bibcode1996Sci...273.1868A. 
  26. "Real-time optical imaging of naturally evoked electrical activity in intact frog brain". Nature 308 (5962): 848–850. 1984. doi:10.1038/308848a0. PMID 6717577. Bibcode1984Natur.308..848G. 
  27. "Long-term voltage-sensitive dye imaging reveals cortical dynamics in behaving monkeys". Journal of Neurophysiology 88 (6): 3421–3438. December 2002. doi:10.1152/jn.00194.2002. PMID 12466458. 
  28. "Dynamics of depolarization and hyperpolarization in the frontal cortex and saccade goal". Science 295 (5556): 862–865. February 2002. doi:10.1126/science.1066641. PMID 11823644. Bibcode2002Sci...295..862S. 
  29. "Near-infrared voltage-sensitive fluorescent dyes optimized for optical mapping in blood-perfused myocardium". Heart Rhythm 4 (11): 1441–1451. November 2007. doi:10.1016/j.hrthm.2007.07.012. PMID 17954405. 
  30. "Simultaneous measurement and modulation of multiple physiological parameters in the isolated heart using optical techniques". Pflügers Archiv 464 (4): 403–414. October 2012. doi:10.1007/s00424-012-1135-6. PMID 22886365. 
  31. "Defects in T-tubular electrical activity underlie local alterations of calcium release in heart failure". Proceedings of the National Academy of Sciences of the United States of America 111 (42): 15196–15201. October 2014. doi:10.1073/pnas.1411557111. PMID 25288764. Bibcode2014PNAS..11115196C. 

Further reading

  • "Potentiometric dyes: imaging electrical activity of cell membranes.". Pure and Applied Chemistry 68 (7): 1405–1409. January 1996. doi:10.1351/pac199668071405.