Virtual Electrode Polarization-Induced Reentrant Activity

Nakagawa, Harumichi, Yamazaki, Masatoshi, Nihei, Motoki, Niwa, Ryoko, Arafune, Tatsuhiko, Mishima, Akira, Nashimoto, Shiho, Shibata, Nitaro, Honjo, Haruo, Sakuma, Ichiro, Kamiya, Kaichiro, Kodama, Itsuo

12 1900

国立情報学研究所で電子化したコンテンツを使用している。

membrane potential

electric field stimulation

optical mapping

reentry

Immuunregulerende, anti-mikrobiese en anti-tumor aktiwiteit van nuwe riminofenasiene (Afrikaans)

Durandt, Chrisna

18 August 2005

The full text of this thesis/dissertation is not available online. Please <a href="mailto:upetd@up.ac.za">contact us</a> if you need access. Read the abstract in the section 00front of this document. / Dissertation (MSc (Medical Immunology))--University of Pretoria, 2006. / Immunology / unrestricted

P-glycoprotein

Riminophenazines

Drug resistance

Membrane potential

Lipophilicity

UCTD

Ethanol Increases Hepatocyte Water Volume

Wondergem, Robert, Davis, Janet

01 January 1994

Mouse hepatocytes respond to osmotic stress with adaptive changes in transmembrane potential, Vm, such that hypotonic stress hyperpolarizes cells and hypertonic stress depolarizes them. These changes in Vm provide electromotive force for redistribution of ions such as CI−, and this comprises part of the mechanism of hepatocyte volume regulation. We conducted the present study to determine whether ethanol administered in vitro to mouse liver slices increases hepatocyte water volume, and whether this swelling triggers adaptive changes in the Vm. Cells in mouse liver slices were loaded with tetramethylammonium ion (TMA). Changes in hepatocyte water volume were computed from measurements with Ion sensitive micro‐electrodes of changes in intracellular activity of TMA (a1TMA) that resulted from water fluxes. Ethanol (70 mM) increased hepatocyte water volume Immediately, and this peaked at 17% by 7 to 8 min, by which time a plateau was reached. Liver slices also were obtained from mice treated 12 hr prior with 4‐methylpyrazole (4 mM). The effect of ethanol on their hepatocyte water volume was identical to that from untreated mice, except that the onset and peak were delayed 2 min. Hepatocyte Vm showed no differences between control or ethanol‐treated cells during the course of volume changes. In contrast, hyposmotic stress, created by dropping external osmolality 50 mosm, increased Vm from –30 mV to –46 mV. Ethanol did not inhibit this osmotic stress‐induced hyperpolarization, except partially at high concentrations of 257 mM or greater. We infer that ethanol‐induced swelling of hepatocytes differs from that resulting from hyposmotic stress. Cellular events associated with increased activity of intracellular water most likely trigger the hyperpolarization of Vm that accompanies the latter. We conclude, therefore, that ethanol‐induced swelling occurs without change in cell water activity. This may result from the retention of macromolecules by ethanol in cells that constitutively secrete protein.

cell volume

electrophysiology

hepatocytes

membrane potential

mouse liver

An Electrophysiological Technique to Measure Change in Hepatocyte Water Volume

Khalbuss, Walid E., Wondergem, Robert

02 November 1990

We have applied an electrophysiologic technique (Reuss L.(1985) Proc. Natl. Acad. Sci. USA 82, 6014) to measure changes in steady-state hepatocyte volume during osmotic stress. Hepatocytes in mouse liver slices were loaded with tetramethylammonium ion (TMA+) during transient exposure of cell to nystatin. Intracellular TMA+ activity (αiTMA) was measured with TMA+ -sensitive, double-barrelled microelectrodes. Loading hepatocytes with TMA+ did not change their membrane potential (Vm), and under steady-state conditions αiTMA remained constant over 4 min in a single impalement. Hyperosmotic solutions (50, 100 and 150 mM sucrose added to media) and hyposmotic solutions (sucrose in media reduced by 50 and 100 mM) increased and decreased αiTMA, respectively, which demonstrated transmembrane water movements. The slope of the plot of change in steady-state cell water volume, [(αiTMA)O/(αiTMA)4min] - 1, on the relative osmolality of media, (experimental mosmol/control mosmol) -1, was less than predicted for a perfect osmometer. Corresponding measurements of Vm showed that its magnitude increased with hyposmolality and decreased with hyperosmolality. When Ba2+ (2 mM) was present during hyposmotic stress of 0.66 × 286 mosmol (control), cell water volume increased by a factor of 1.44 ± 0.02 compared with that of hyposmotic stress alone, which increased cell water volume by a factor of only 1.12 ± 0.02, P< 0.001. Ba2+ also decreased the hyperpolarization of hyposmotic stress from a factor of 1.62 ± 0.04 to 1.24 ± 0.09, P < 0.01. We conclude that hepatocytes partially regulate their steady-state volume during hypo- and hyperosmotic stress. However, volume regulation during hyposmotic stress diminished along with hyperpolarization of Vm in the presence of the K+ -channel blocker, Ba2+. This shows that variation in Vm during osmotic stress provides an intercurrent, electromotive force for hepatocyte volume regulation.

(mouse liver)

barium

cell volume

membrane potential

microelectrode

nystatin

tetramethylammonium

Hepatocyte Water Volume and Potassium Activity During Hypotonic Stress

Wang, Kening, Wondergem, Robert

01 August 1993

Hepatocytes exhibit a regulatory volume decrease (RVD) during hypotonic shock, which comprises loss of intracellular K+ and Cl- accompanied by hyperpolarization of transmembrane potential (Vm) due to an increase in membrane K+ conductance, (GK). To examine hepatocyte K+ homeostasis during RVD, double-barrel, K+-selective microelectrodes were used to measure changes in steady-state intracellular K+ activity (aKi) and Vm during hyposmotic stress. Cell water volume change was evaluated by measuring changes in intracellular tetramethylammonium (TMA+). Liver slices were superfused with modified Krebs physiological salt solution. Hyposmolality (0.8×300 mosm) was created by a 50 m m step-decrease of external sucrose concentration. Hepatocyte Vm hyperpolarized by 19 mV from -27 ± 1 to -46 ± 1 mV and aKidecreased by 14% from 91 ± 4 to 78 ± 4 m m when slices were exposed to hyposmotic stress for 4-5 min. Both Vm and aKireturned to control level after restoring isosmotic solution. In paired measurements, hypotonic stress induced similar changes in Vm and aKiboth control and added ouabain (1 m m) conditions, and these values returned to their control level after the osmotic stress. In another paired measurement, hypotonic shock first induced an 18-mV increase in Vm and a 15% decrease in aKiin control condition. After loading hepatocytes with TMA+, the same hypotonic shock induced a 14-mV increase in Vm and a 14% decrease in aTMAi. This accounted for a 17% increase of intracellular water volume, which was identical to the cell water volume change obtained when aKiwas used as the marker. Nonetheless, hyposmotic stress-induced changes in Vm and aKiwere blocked partly by Ba2+ (2 m m). We conclude that (i) hepatocyte Vm increases and aKidecreases during hypotonic shock; (ii) the changes in hepatocyte Vm and aKiduring and after hypotonic shock are independent of the Na+-K+ pump; (iii) the decrease in aKiduring hypotonic stress results principally from hepatocyte swelling.

intracellular K +

ion-sensitive microelectrodes

membrane potential

osmotic stress

quabain

Ion selectivity and membrane potential effects of two scorpion pore-forming peptides / D. Elgar

Elgar, Dale

January 2005

Parabutoporin (PP) and opistoporin 1 (OP1) are cation, a-helical antimicrobial peptides isolated from the southern African scorpion species, Parabuthus schlechteri and Opistophthalmus carinatus, respectively. Along with their antimicrobial action against bacteria and fungi, these peptides show pore-forming properties in the membranes of mammalian cells. Pore-formation and ion selectivity in cardiac myocytes were investigated by measuring the whole cell leak current by means of the patch clamp technique. Pore-formation was observed as the induction of leak currents. Ion selectivity of the pores was indicated by the shift of the reversal potential (E,,,) upon substitution of intra (K' with CS' and CI- with aspartate) and extracellular (Na' with NMDG') ions. Results were compared with the effect of gramicidin A used as a positive control for monovalent cation selective pores. PP and OP I induced a fluctuating leak current and indicate non-selectivity of PP and OP1-induced pores. An osmotic protection assay to determine estimated pore size was performed on the cardiac myocytes. PP and OP1-induced pores had an estimate pore size of 1.38-1.78 nm in diameter. The effect of PP and OP1 on the membrane potential (MP) of a neuroblastoma cell line and cardiac myocytes was investigated. TMRM was used to mark the MP fluorescently and a confocal microscope used to record the data digitally. The resting membrane potential (RMP) of the neuroblastoma cells was calculated at -38.3 f 1.9 mV. PP (0.5 uM) and OP1 (0.5-1 uM) depolarized the entire cell uniformly to a MP of -1 1.9 k 3.9 mV and -9.4 k 1.9 mV, respectively. This occurred after 20-30 min of peptide exposure. In the case of the cardiac myocytes depolarization was induced to -39.7 f 8.4 mV and -32.6 f 5.2 mV by 0.5-1 uM PP and 1.5-2.5 uM OPl, respectively. / Thesis (M.Sc. (Physiology))--North-West University, Potchefstroom Campus, 2006.

Scorpion toxins

Antimicrobial peptides

Pore-formation

Ion selectivity

Pore size

Membrane potential

Metaboloptics: In Vivo Optical Imaging to Enable Simultaneous Measurement of Glucose Uptake, Mitochondrial Membrane Potential, and Vascular Features in Cancer

Martinez, Amy Frees

January 2016

<p>Altered metabolism is a hallmark of almost all cancers. A tumor’s metabolic phenotype can drastically change its ability to proliferate and to survive stressors such as hypoxia or therapy. Metabolism can be used as a diagnostic marker, by differentiating neoplastic and normal tissue, and as a prognostic marker, by providing information about tumor metastatic potential. Metabolism can further be used to guide treatment selection and monitoring, as cancer treatments can influence metabolism directly by targeting a specific metabolic dysfunction or indirectly by altering upstream signaling pathways. Repeated measurement of metabolic changes during the course of treatment can therefore indicate a tumor’s response or resistance. Recently, well-supported theories indicate that the ability to modulate metabolic phenotype underpins some cancer cells’ ability to remain dormant for decades and recur with an aggressive phenotype. It follows that accurate identification and repeated monitoring of a tumor’s metabolic phenotype can bolster understanding and prediction of a tumor’s behavior from diagnosis, through treatment, and (sadly) sometimes back again.</p><p>The two primary axes of metabolism are glycolysis and mitochondrial metabolism (OXPHOS), and alteration of either can promote unwanted outcomes in cancer. In particular, increased glucose uptake independent of oxygenation is a well-known mark of aggressive cancers that are more likely to metastasize and evade certain therapies. Lately, mitochondria are also gaining recognition as key contributors in tumor metabolism, and mitochondrial metabolism has been shown to promote metastasis in a variety of cell types. Most tumor types rely on a combination of both aerobic glycolysis and mitochondrial metabolism, but the two axes’ relative contributions to ATP production can vary wildly. Knowledge of both glycolytic and mitochondrial endpoints is required for actionable, systems-level understanding of tumor metabolic preference. </p><p>Several technologies exist that can measure endpoints informing on glycolytic and/or mitochondrial metabolism. However, these technologies suffer from a combination of prohibitive cost, low resolution, and lack of repeatability due to destructive sample treatments.</p><p>There is a critical need to bridge the gap in pre-clinical studies between single-endpoint whole body imaging and destructive ex vivo assays that provide multiple metabolic properties, neither of which can provide adequate spatiotemporal information for repeated tumor monitoring. Optical technologies are well-suited to non-destructive, high resolution imaging of tumor metabolism. A carefully chosen set of endpoints can be measured across a variety of length scales and resolutions to obtain a complete picture of a tumor’s metabolic state. First, the fluorescent glucose analog 2-(N-(7-Nitrobenz-2-oxa-1,3-diazol-4-yl)Amino)-2-Deoxyglucose (2-NBDG) can be used to report on glucose uptake. The fluorophore tetramethylrhodamine, ethyl ester (TMRE) reports on mitochondrial membrane potential, which provides information regarding capacity for oxidative phosphorylation. Vascular oxygenation (SO2) and morphological features, which are critical for interpretation of 2-NBDG and TMRE uptake, can be obtained using only endogenous contrast from hemoglobin. </p><p>Three specific aims were proposed toward the ultimate goal of developing an optical imaging toolbox that utilizes exogenous fluorescence and endogenous absorption contrast to characterize cancer metabolic phenotype in vivo. </p><p>In Aim 1, we optimized the fluorescent glucose analog 2-(N-(7-Nitrobenz-2-oxa-1,3-diazol-4-yl)Amino)-2-Deoxyglucose (2-NBDG) to report on glycolytic demand in vivo. Our primary goal was to demonstrate that correcting 2-NBDG uptake (NBDG60) by the rate of delivery (RD) showed improved contrast between distinct tumor phenotypes. We showed that the ratio 2-NBDG60/RD served as a delivery-corrected measure of glucose uptake in the dorsal skin flap window chamber models containing normal tissues and tumors. Delivery correction was able to minimize the effects of a large change in the injected 2-NBDG dose. Further, the endpoint showed a significant inverse correlation with blood glucose levels. Since glucose has been shown to competitively inhibit 2-NBDG transport into cells, this finding indicating that we were indeed reporting on glucose uptake. Importantly, the ratio was able to distinguish specific uptake of 2-NBDG from accumulation of a fluorescent control, 2-NBDLG, which is identical to 2-NBDG in molecular weight and fluorescent spectrum, but is unable to undergo active transport into the cell. </p><p>The ratio 2-NBDG60/RD was then leveraged to compare different tumor phenotypes and to characterize the dependence of glucose uptake on vascular oxygenation within these tumors. Our results showed that 2-NBDG60/RD was an effective endpoint for comparing in vivo glucose uptake of metastatic 4T1 and nonmetastatic 4T07 murine mammary adenocarcinomas. Further, the addition of vascular information revealed metabolic heterogeneity within the tumors. The primary conclusion of Aim 1 was that delivery-corrected 2-NBDG uptake (2-NBDG60/RD) is an appropriate indicator of glucose demand in both normal and tumor tissues.</p><p>In Aim 2, we optimized fluorescent tetramethyl rhodamine, ethyl ester (TMRE) for measurement of mitochondrial membrane potential (MMP). We then leveraged the relationships between MMP, glucose uptake, and vascular endpoints to characterize the in vivo metabolic landscapes of three distinct and extensively studied murine breast cancer lines: metastatic 4T1 and non-metastatic 67NR and 4T07. </p><p>Using two-photon microscopy, we confirmed that TMRE localizes to mitochondrial-sized features in the window chamber when delivered via tail vein. The kinetics of TMRE uptake were robust across both normal and tumor tissues, with a stable temporal window for measurement from 40-75 minutes after injection. We saw that TMRE uptake decreased as expected in response to hypoxia in non-tumor tissue, and in response to chemical inhibition with a mitochondrial uncoupler in both non-tumor and 4T1 tissue. MMP was increased in all tumor types relative to non-tumor (p<0.05), giving further confirmation that TMRE was reporting on mitochondrial activity.</p><p>We leveraged the relationships between the now-optimized endpoints of MMP (Aim 2), glucose uptake (Aim 1) and vascular endpoints (Aims 1 and 2) to characterize the in vivo metabolic landscapes of three distinct and extensively studied murine breast cancer lines: metastatic 4T1 and non-metastatic 67NR and 4T07. Imaging the combination of endpoints revealed a classic “Warburg effect” coupled with hyperpolarized mitochondria in 4T1; 4T1 maintained vastly increased glucose uptake and comparable MMP relative to 4T07 or 67NR across all SO2. We also showed that imaging trends were concordant with independent metabolomics analysis, though the lack of spatial and vascular data from metabolomics obscured a more detailed comparison of the technologies.</p><p>We observed that vascular features in tumor peritumoral areas (PA) were equally or more aberrant than vessels in the tumor regions that they neighbored. This prompted consideration of the metabolic phenotype of the PA. Regional metabolic cooperation between the tumor region and the PA was seen only in 4T1, where MMP was greater in 4T1 tumors and glucose uptake was greater in 4T1 PAs. </p><p>Because of their regional metabolic coupling as well as their demonstrated capacity for glycolysis and mitochondrial activity, we hypothesized that the 4T1 tumors would have an increased ability to maintain robust MMP during hypoxia. 67NR and 4T07 tumors showed expected shifts toward decreased MMP and increased glucose uptake during hypoxia, similar to the trends we observed in normal tissue. Surprisingly, 4T1 tumors appeared to increase mitochondrial metabolism during hypoxia, since MMP increased and SO2 dramatically decreased. Overall, this aim demonstrated two key findings: 1. TMRE is a suitable marker of mitochondrial membrane potential in vivo in normal tissue and tumors, and 2. imaging of multiple metabolic and vascular endpoints is crucial for the appropriate interpretation of a metabolic behavior. </p><p>Finally, in Aim 3 we evaluated the feasibility of combined 2-NBDG and TMRE imaging. The primary objective was to enable simultaneous imaging of the two fluorophores by minimizing sources of “cross-talk”: chemical reaction, optical overlap, and confounding biological effects. A secondary objective was to transition our imaging method to a new platform, a reflectance-mode, high-resolution fluorescence imaging system built in our lab, which would expand the use of our technique beyond the dorsal window chamber model. We first used liquid chromatography- mass spectrometry to confirm that the chemical properties of the two fluorophores were compatible for simultaneous use, and indeed saw that the mixing of equimolar 2-NBDG and TMRE did not form any new chemical species. </p><p>We also performed a phantom study on the hyperspectral imaging system, used for all animal imaging in Aim 1 and Aim 2, to estimate the range of 2-NBDG and TMRE concentrations that are seen at the tissue level in normal and tumor window chambers. We created a new phantom set that spanned the range of estimated in vivo concentrations, and imaged them with the reflectance-mode fluorescence imaging system. The phantom experiments gave us two important findings. First, we saw that fluorescence intensity increased linearly with fluorophore concentration, allowing for accurate quantification of concentration changes between samples. Most importantly, we found that we could exploit the optical properties of the fluorophores and our system’s spectral detection capability to excite the two fluorophores independently. Specifically, we could excite 2-NBDG with a 488nm laser without detectable emission from TMRE, and could excite TMRE with a 555nm laser without detectable emission from 2-NBDG. With this characterization, the optical properties of the two fluorophores were considered compatible for simultaneous imaging. </p><p>Next, we sought to determine whether biological or delivery interactions would affect uptake of the two fluorophores. Surprisingly, both in vitro and in vivo imaging suggested that simultaneous dosing of the 2-NBDG and TMRE caused significant changes in uptake of both probes. Since we previously found that TMRE equilibrates rapidly at the tissue site, we hypothesized that staggering the injections to allow delivery of TMRE to tissue before injecting 2-NBDG would restore the full uptake of both fluorophores. Two sequential injection protocols were used: in the first group, TMRE was injected first followed by injection of 2-NBDG after only 1-5 minutes, and in the second group, TMRE was injected first followed by injection of 2-NBDG after 10-15 minutes. Both sequential injection strategies were sufficient to restore the final fluorescence of both fluorophores to that seen in the separate TMRE or 2-NBDG imaging cohorts; however, the shorter time delay caused changes to the initial delivery kinetics of 2-NBDG. We concluded that sequential imaging of TMRE followed by 2-NBDG with a 10-15 minute delay was therefore the optimal imaging strategy to enable simultaneous quantification of glucose uptake and mitochondrial membrane potential in vivo. </p><p>Applying the sequential imaging protocol to 4T1 tumors demonstrated a highly glycolytic phenotype compared to the normal animals, as we had seen in Aim 2. However, mitochondrial membrane potential was comparable for the normal and tumor groups. The next study will test an extended delay between the injections to allow more time for TMRE delivery to tumors prior to 2-NBDG injection. Overall, the key finding of Aim 3 was that a carefully chosen delivery strategy for 2-NBDG and TMRE enabled simultaneous imaging of the two endpoints, since chemical and optical cross-talk were negligible.</p><p>The work presented here indicates that an optical toolbox of 2-NBDG, TMRE, and vascular endpoints is well poised to reveal interesting and distinct metabolic phenomena in normal tissue and tumors. Future work will focus on the integration of optical spectroscopy with the microscopy toolbox presented here, to enable long-term studies of the unknown metabolic changes underlying a tumor’s response to therapy, its escape into dormancy, and ultimately, its recurrence.</p> / Dissertation

Biomedical engineering

Oncology

Pharmacology

Cancer

Fluorescence Imaging

Glycolysis

Metabolism

Mitochondrial membrane potential

Optical Microscopy

Does Thermotolerance in Daphnia Depend on the Mitochondrial Function?

Hasan, Rajib

01 August 2019

Thermotolerance limit in aquatic organism is set by the ability to sustain aerobic scope to sudden temperature shifts. This study tested the genetic and plastic differences in thermotolerance of Daphnia that can be explained by the differences in the ability to retain mitochondrial integrity at high temperatures. Five genotypes with different biogeographic origins were acclimated to 18ᵒC and 25ᵒC. We developed a rhodamine 123 in-vivo assay to measure mitochondrial membrane potential and observed higher fluorescent in heat damaged tissues as the disruption of the mitochondrial membrane potential. Significant effects on temperature tolerance were observed with CCCP and DNP but not with NaN3. Effects of toxins were significant in temperature sensitive genotype and high concentration of lactate was observed in 18ᵒC acclimated genotype only. We conclude that genetic and physiological differences are intricately linked to the ability of sustaining aerobic respiration at high temperatures which sets limit to the thermotolerance.

Mitochondrial function

Daphnia

Thermotolerance

Mitotoxins

Acclimation

Membrane potential

Biochemistry

Integrative Biology

Molecular Biology

Efeito da deformação mecânica no transporte iônico em filmes poliméricos. / Effect of mechanical deformation on ionic transport in polimeric films.

Sakamoto, Walter Katsumi

10 December 1990

Recentemente um efeito piezoelétrico foi encontrado quando um filme polimérico, separando duas soluções de eletrólitos em diferentes concentrações, foi deformado. Este efeito foi atribuído à modulação da mobilidade dos íons no polímero. Foi observado que o efeito diminui com o aumento da concentração de eletrólitos. Para entender mais profundamente este último efeito, foram realizados estudos sobre o transporte de água e sal através do polímero, com e sem deformação, e os resultados podem ser resumidos como segue: a) O aumento da hidratação acarreta um aumento na porosidade e um decréscimo na cristalinidade do polímero. b) O aumento da concentração de sal, no interior do polímero acarreta um aumento na permeabilidade, sendo mais pronunciado na presença de deformação. Esses efeitos tornam mais difícil a modulação dos íons, diminuindo o sinal piezoelétrico observado. / Recently a piezoelectric effect was found when a polymeric film, separating two electrolyte solutions at different concentrations, was deformed. This effect was attributed to the modulation of the mobility of the íons in the polymer. It was observed that the effect decreases as the electrolyte concentrations increases. In order to understand more deeply this last effect a study on water and salt transport through the polymer with and without deformation was carried out, and the results may be summarized as follows: a) An increase in hydration of the polymer leads to an increase in porosity and a decrease in cristallinity. b) An increase in the concentration of the salt leads to an increase in permeability, which is more pronounced in the presence of deformation. The effects make more difficult the modulation of the íons, so lower piezoelectric signals are observed.

Absorção

Absorption

Difusão

Difusion

Ionic pair

Membrane potential

Pares iônicos

Permeabilidade

Permeability

Potencial de membrana

Striated muscle action potential assessment as an indicator of cellular energetic state

Burnett, Colin Michael-Lee

01 May 2012

Action potentials of striated muscle are created through movement of ions through membrane ion channels. ATP-sensitive potassium (KATP) channels are the only known channels that are gated by the intracellular energetic level ([ATP]/[ADP] ratio). KATP channels are both effectors and indicators of cellular metabolism as part of a negative feedback system. Decreased intracellular energetic level alters the gating of KATP channels, which is reflected in alterations of the action potential morphology. These changes protect the cell from exhaustion or injury by altering energy-consuming processes that are driven by membrane potential. Assessing the effects of KATP channel activation on resting membrane potential and action potential morphology, and the relationship to cellular stress is important to the understanding of normal cellular function. To better understand how muscle cells adapt to energetic stress, the monophasic action potential (MAP) electrode and floating microelectrode were used to record action potentials in intact hearts and skeletal muscles, respectively. Intact organs provide a more physiological environment for the study of energetics and membrane electrical phenomena. Utilizing these techniques, a stress on the intracellular energetic state resulted in greater and faster shortening of the duration of cardiac action potentials, and hyperpolarization of the membrane of skeletal muscle in a KATP channel dependent manner. Motion artifacts are a limitation to studying transmembrane action potentials, but the MAP and floating microelectrode techniques uniquely allow for reading of action potential morphology uncoupled from motion artifacts. The use of the floating microelectrode in skeletal muscles is a novel approach that provides previously unavailable data on skeletal muscle membrane potentials in situ.

action potential

cardiac muscle

floating microelectrode

KATP channel

membrane potential

skeletal muscle