Deutsche Physiologische Gesellschaft Abstracts of the 59th Meeting (Spring Meeting) March 26–30, 1984, Dortmund
Identifieur interne : 000849 ( Istex/Corpus ); précédent : 000848; suivant : 000850Deutsche Physiologische Gesellschaft Abstracts of the 59th Meeting (Spring Meeting) March 26–30, 1984, Dortmund
Auteurs :Source :
- Pflügers Archiv [ 0031-6768 ] ; 1984-03-01.
English descriptors
- Teeft :
- Aachen, Abducens nuclei, Abteilung, Abteilung allgemeine, Abteilung allgemeine physiologie, Abteilung nierenphysiologie, Abteilung physiologie, Acetic acid, Acetylcholine, Acetylcholine receptors, Acta physiol, Actin myosin interaction kinetics, Action potentials, Activity pattern, Acute volume expansion, Adaptive process, Adenosine, Adult heart, Adult heart cells, Afferent, Afferent units, Afterload reduction, Albumin concentration, Aldosterone, Aldosterone application, Alfried krupp krankenhaus, Alpha activity, Althesin, Ambient, Ambient temperature, Ambient temperatures, Amiloride, Ammonium chloride, Amplitude, Anaesthesia, Anaesthetized, Anaesthetized cats, Anaesthetized dogs, Anesthetized, Anesthetized dogs, Anesthetized rats, Angewandte physiologie, Angular displacement, Anion, Anoxia, Anoxic, Anoxic conditions, Antagonist, Antiarrhythmic action, Antidromic stimulation, Apparent cell membrane resistance, Arginine, Arterial blood pressure, Arterial pressure, Arterial wall, Atrial, Atrial fibrillation, Autonomic blockade, Available version, Axon, Basilar membrane, Basolateral, Basolateral membrane, Basolateral membrane vesicles, Basolateral membranes, Bathing medium, Bicarbonate, Bicarbonate concentration, Bicycle ergometer, Bilateral, Bilateral vagotomy, Bilayers, Bile, Bile pancreatic duct, Biol, Biophysik, Blocker, Blood cells, Blood flow, Blood flow rate, Blood pressure, Blood samples, Blood sampling, Blood supply, Blood vessels, Bochum, Body cells, Body fluids, Body temperature, Body temperatures, Body weight, Bolus injections, Brain tissue, Brush border membrane, Brush border membranes, Calcium, Calcium antagonist verapamil, Calcium antagonists, Calcium currents, Calcium transport, Calcium uptake, Calmodulin, Canine, Canine femoral arteries, Canine femoral artery, Canine stomach, Carboxyl groups, Cardiac, Cardiac cycle, Cardiac myocytes, Cardiac output, Carotid, Carotid body cells, Carotid chemodenervated rabbits, Cation, Cell bodies, Cell body, Cell ghosts, Cell membrane, Cell membrane conductance, Cell populations, Cell shape, Cell sizes, Cell types, Cell velocity, Cells show, Cellular functions, Central chemosensitive drive, Central chemosensitivity, Central zones, Cerebral cortex, Channel number, Channel openings, Charge carrier, Chemical sympathectomy, Chemical synapses, Chloride concentration, Choline, Cholinergic, Cholinergic innervation, Cholinergic mechanism, Cholinergic pathways, Circadian rhythms, Cirrhosis, Clozapine, Cluster duration, Cochlear duct, Cold fibre activity, Cold fibres, Cold receptors, Collateral, Condensor discharges, Conductance, Conduction, Conduction velocities, Conductive pathway, Confinement stress, Conscious rats, Contact structures, Continuous work load, Contractile, Contractile response, Contralateral, Control conditions, Control level, Control levels, Control period, Control solution, Control value, Control values, Conventional microelectrodes, Convoluted tubules, Coronary, Coronary arteries, Coronary blood flow, Coronary flow, Coronary reserve, Coronary stenosis, Coronary vasoconstriction, Coronary venous, Cortex, Cortical, Cortical neurons, Cortical surface, Cotransport system, Ctal, Ctal segments, Cuff, Cuff method, Current pulses, Curvature, Cytosolic enzymes, Deafferented parts, Deep tissues, Deeper laminae, Dendrite, Dendritic, Deoxygenated blood, Depolarization, Depolarizing, Deutsche, Deutsche forschungsgemeinschaft, Diastolic blood pressure, Diel rhythm, Different concentrations, Different frequency bands, Different hemodynamic conditions, Different responses, Different sites, Diffraction pattern, Dilation, Direct action, Direct measurement, Discharge activity, Discharge frequency, Discharge pattern, Discharge rate, Dlgn, Donnan ratios, Dorsal, Dorsal border, Dorsal skinfolds, Dos, Dose response curves, Duct, Dynamic response, Dynamic responses, Dynamic rheological properties, Effective concentrations, Egta, Ehrenstein figures, Electrical properties, Electrical response, Electrical stimulation, Electrochemical gradient, Electrode, Electrogenic, Electromagnetic, Electromagnetic field, Electromagnetic fields, Endoplasmic, Endoplasmic reticulum, Endothelial cells, Endothelial removal, Endothelium, Endplate, Endurance performance, Energy deficiency, Enzyme, Epileptiform, Ergometer, Erlangen, Erythrocyte, Erythrocyte deformability, Essen, Ethacrynic acid, Ether stress, Ethoxzolamide concentration, Excretion, Experimental conditions, Experimental medicine, Experimentelle medizin, Exponential, Extracellular, Extracellular space, Fatty acids, Febs lett, Feld, Femoral, Fiber axis, Fibre, Fibrillation, Fibrin, Fibrin layer, Field potentials, First appearance, First half, First week, Flexor, Flexor activity, Flow pulse, Fluid transport, Fluid transport rates, Focal epileptiform discharges, Focal epileptiform potentials, Focal ischemia, Focal plane, Force production, Former studies, Forschungsgemeinschaft, Fractional resistance, Free flow, Freiburg, Freien berlin, Frequency channels, Frequency domain, Frequency response, Frog, Frog kidney, Frog nerve, Frog nodes, Functional integrity, Functional recovery, Functional significance, Further experiments, Fusimotor action, G6ttingen, Gaba, Ganglion, Ganglionic transmission, Gating currents, Geniculate, Geniculate nucleus, Giessen, Glial cells, Glucose, Glutamate, Glutamine resorption, Gradient apparatus, Guinea, Hansastr, Head movements, Heart rate, Heat clearance, Heat loss, Heat production, Heidelberg, Hematocrit, Hemodilution, Hemoglobin oxygenation, High threshold, Higher concentration, Higher concentrations, Higher threshold temperatures, Higher values, Hippocampal, Hippocampal slices, Histogram, Homogenate, Horseradish peroxidase, Human erythrocytes, Hydrodynamic conditions, Hydronephrotic, Hydronephrotic kidney, Hypophysial portal vessels, Hypoxia, Hypoxic, Hypoxic dilatation, Impedance, Important role, Impulse activity, Impulse groups, Impulse rate, Impulse rates, Inactivation, Increment threshold, Incubation medium, Independence principle, Indirect evidence, Infusion, Inhibition, Inhibitor, Inhibitory, Inhibitory postsynaptic currents, Injection, Inner segment, Inorganic sulfate, Inosine, Input resistance, Inst, Institut, Institut fuer physiologie, Institut physiologie, Intact cats, Intact controls, Intermediate area, Intermittent exercise, Intermittent work load, Intracapillary hemoglobin spectra, Intracellular, Intracellular recordings, Intracellular space, Intraluminal hypoxia, Intramyocardial oxygen pressure, Intrapulmonary chemoreceptors, Intravenous injections, Intravesicular, Intravesicular acidification, Ion, Ischemia, Ischemic, Ischemic area, Isoenzyme pattern, Isometric, Isometric conditions, Isometric tension, Isoproterenol, Isotonic solutions, Isovolemic hemodilution, Jggc, Kardiologie, Kardiologie g6ttingen, Kennedyallee, Kidney, Kidney cells, Kidney cortex, Kidney slices, Kiel, Kinetics, Klaus paulat, Klinik, Krebs solution, Lactic acid, Lamina, Large number, Large vessel resistance, Latency, Lateral, Lateral diffusion, Lateral geniculate, Lateral geniculate nucleus, Lehrstuhl, Lehrstuhl zellphysiologie, Lesion, Light chain phosphorylation, Light diffraction, Light intensity, Lipid, Liver cirrhosis, Load reduction, Local application, Local oxygen supply, Looo berlin, Lower activity, Lower values, Lowest values, Lumen, Luminal, Luminal application, Luminal membrane resistance, Luminance, Lung inflation, Lung volume, Main laminae, Mainz, Male wistar rats, Marburg, Maternal side, Mathematical model, Maximal, Maximal isometric force, Maximum response, Mechanical activity, Mechanical properties, Mechanical response, Mechanical thresholds, Mechanosensitive units, Median, Median conduction, Median eminence, Medullary, Membrane, Membrane conductance, Membrane currents, Membrane curvature, Membrane patches, Membrane potentials, Membrane resistance, Membrane vesicles, Menthol, Menthol application, Mesencephalic reticular formation, Metabolism, Microelectrodes, Minimum values, Minor degree, Mmhg, Mongolian gerbils, Mongrel dogs, Monosynaptic connection, More detail, Motor behaviour, Motor function, Mtal segments, Multiwire surface electrode, Muscle cells, Muscle preparations, Myocardial, Myocardial oxygen consumption, Myocytes, Myosin, Myosin light chain phosphorylation, Naci, Naci secretion, Naocn treatment, Necturus gallbladder, Negative direction, Negative membrane curvature, Neon color effect, Nerve, Nerve fibres, Nerve section, Nerve stimulation, Nerve suture, Neuenheimer, Neuenheimer feld, Neural activity, Neural response, Neurologische klinik, Neuron, Neuronal, Neurones, Neuropharmacology research group, Neurosci, Node, Nonlinear behaviour, Normal conditions, Normal sodium, Normothermic anoxia, Normoxic blood, Noxious, Oberer, Oberer eselsberg, Occlusion, Olfactory cortex neurones, Oncotic agents, Open time, Open times, Oscillation frequency, Other authors, Other hand, Ouabain, Overshoot, Oxydative enzymes, Oxygen consumption, Oxygen deficiency, Oxygen distribution, Oxygen lack, Oxygen paradox, Oxygen supply, Oxygen tension, Oxygen uptake, Oxygenated blood, Oxygenation, Pancreatic, Pancreatic acinar cells, Pancreatic duct, Pancreatic proteins, Paracellular, Paracellular pathway, Paracellular resistance, Patch electrode, Patch pipette, Pathway, Pdte, Peak responders, Peptide, Perfusate, Perfused, Perfusion, Perfusion distance, Perfusion resistance, Perfusional diuresis, Perigeniculate, Perigeniculate nucleus, Periphery effect, Peritubular, Peritubular cell membrane, Permeability, Permeabilized cells, Peroneal nerve, Pflogers arch, Pflugers arch, Phasic, Phasic contractions, Phasic type, Phenylalanine, Physiol, Physiological range, Physiologie, Physiologisches, Physiologisches institut, Physiology, Pifc stimuli, Pipette, Placental, Planar bilayers, Plasma membrane, Plasma membranes, Platelet, Platelet aggregation, Positive curvature, Postoperative, Postsynaptic, Potassium activity, Pregnant guinea pigs, Preoptic area, Present experiments, Present study, Previous investigations, Previous studies, Previous study, Prostaglandin, Protein concentration, Proximal, Proximal tubule, Proximal tubules, Pulpal temperature, Pulsatile flow, Pulse, Pursuit neurons, Quantitative information, Quiet breathing, Quinidine, Rabbit aorta, Rabbit kidney, Radiant heat, Radiolabeled urea, Ranvier nodes, Rapid cooling, Rapid decline, Rat, Rate constants, Reabsorption, Reactive hyperemia, Receptor, Receptor layer, Recording site, Rectal gland tubule, Regensburg, Regional function, Regression equations, Regulatory mechanism, Reinnervated tibialis muscle, Relative power, Removal depolarizes, Renal, Renal blood flow, Renal cortex, Renin, Renin release, Repetitive stimulation, Resp, Respiration, Respiration rate, Respiratory system, Response characteristics, Response curves, Results show, Reticular, Reticular formation, Reticulum, Reversal, Reversal stimuli, Reversible diminution, Ringer, Ringer infusion, Ringer solution, Room temperature, Root effect, Rough endoplasmic reticulum, Rwth, Rwth aachen, Same conditions, Same latency, Same time, Sarcoplasmic reticulum, Scalp location, Science foundation, Secondary endings, Segment, Series resistance, Several lines, Short duration, Short pathways, Short period, Shunt characteristics, Significant difference, Significant effect, Significant increase, Silicone membrane, Single cells, Single channel, Single channel currents, Single injection, Single lsras, Sinus, Sinus rhythm, Sinusoidal, Skeletal muscle, Skeletal muscles, Skin blood flow, Skin sites, Skin temperature, Slight enhancement, Slight increase, Small amounts, Smooth muscle, Smooth muscle cells, Smooth pursuit, Sodium channels, Sodium currents, Spatial distribution, Spatial frequencies, Speckmann, Spike, Spinal, Spontaneous activity, Spontaneous hypertension, Stable potentiation, Standard referenced, Steady state, Steady value, Stenosis, Step depolarizations, Stimulation, Stimulus, Stimulus strength, Stretch receptors, Stretch reflex, Stroke volume, Strong evidence, Sulfate, Superfusion, Sural nerve, Surface electrode, Sweet glands, Sympathetic ganglia, Sympathetic preganglionic neurones, Sympathetic stimulation, Synapse, Synaptic, Synaptic transmission, Systolic, Systolic blood pressure, Taainduced liver cirrhosis, Tail artery, Tail currents, Taste receptors, Taste sensations, Technical assistance, Temperature ramps, Temperature range, Thermal gradient, Thermal information transfer, Thermoregulatory system, Theta, Theta activity, Theta changes, Threshold pressure, Threshold temperature, Threshold temperatures, Tibialis, Tibialis muscle, Time constants, Time course, Time courses, Tion, Tissue oxygenation, Tonic, Tonic type, Torr, Tracer, Tracer fraction, Transepithelial, Transepithelial resistance, Transient, Transneuronal atrophy, Transparent chambers, Transport system, Transport systems, Transthoracic puncture, Tubingen, Tubular, Tubular cells, Tubular segments, Tubular wall, Tubule, Tubule fragments, Tubule lumen, Typical marker, Unit activity, Univ, University winterthurerstrasse, Unpleasurable feelings, Untreated, Uptake, Urea, Urine, Vagal reflexes, Valproate, Various types, Vascular, Vascular tone, Velocity components, Venous pressure, Ventral, Ventral medullary surface, Ventricular, Ventricular perfusion, Vesicle, Vessel wall, Vessel walls, Vestibular, Visual cortex, Visual deafferentation, Visual field, Visual functions, Visual system, Visual targets, Vivo, Vulnerable period, Walden, Warm spot, Warm spots, Water temperature, West germany, White matter, Witte, Work load, Zentren physiologie, Zentrum, Zentrum physiologie.
Url:
DOI: 10.1007/BF00586777
Links to Exploration step
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<profileDesc><textClass><keywords scheme="Teeft" xml:lang="en"><term>Aachen</term>
<term>Abducens nuclei</term>
<term>Abteilung</term>
<term>Abteilung allgemeine</term>
<term>Abteilung allgemeine physiologie</term>
<term>Abteilung nierenphysiologie</term>
<term>Abteilung physiologie</term>
<term>Acetic acid</term>
<term>Acetylcholine</term>
<term>Acetylcholine receptors</term>
<term>Acta physiol</term>
<term>Actin myosin interaction kinetics</term>
<term>Action potentials</term>
<term>Activity pattern</term>
<term>Acute volume expansion</term>
<term>Adaptive process</term>
<term>Adenosine</term>
<term>Adult heart</term>
<term>Adult heart cells</term>
<term>Afferent</term>
<term>Afferent units</term>
<term>Afterload reduction</term>
<term>Albumin concentration</term>
<term>Aldosterone</term>
<term>Aldosterone application</term>
<term>Alfried krupp krankenhaus</term>
<term>Alpha activity</term>
<term>Althesin</term>
<term>Ambient</term>
<term>Ambient temperature</term>
<term>Ambient temperatures</term>
<term>Amiloride</term>
<term>Ammonium chloride</term>
<term>Amplitude</term>
<term>Anaesthesia</term>
<term>Anaesthetized</term>
<term>Anaesthetized cats</term>
<term>Anaesthetized dogs</term>
<term>Anesthetized</term>
<term>Anesthetized dogs</term>
<term>Anesthetized rats</term>
<term>Angewandte physiologie</term>
<term>Angular displacement</term>
<term>Anion</term>
<term>Anoxia</term>
<term>Anoxic</term>
<term>Anoxic conditions</term>
<term>Antagonist</term>
<term>Antiarrhythmic action</term>
<term>Antidromic stimulation</term>
<term>Apparent cell membrane resistance</term>
<term>Arginine</term>
<term>Arterial blood pressure</term>
<term>Arterial pressure</term>
<term>Arterial wall</term>
<term>Atrial</term>
<term>Atrial fibrillation</term>
<term>Autonomic blockade</term>
<term>Available version</term>
<term>Axon</term>
<term>Basilar membrane</term>
<term>Basolateral</term>
<term>Basolateral membrane</term>
<term>Basolateral membrane vesicles</term>
<term>Basolateral membranes</term>
<term>Bathing medium</term>
<term>Bicarbonate</term>
<term>Bicarbonate concentration</term>
<term>Bicycle ergometer</term>
<term>Bilateral</term>
<term>Bilateral vagotomy</term>
<term>Bilayers</term>
<term>Bile</term>
<term>Bile pancreatic duct</term>
<term>Biol</term>
<term>Biophysik</term>
<term>Blocker</term>
<term>Blood cells</term>
<term>Blood flow</term>
<term>Blood flow rate</term>
<term>Blood pressure</term>
<term>Blood samples</term>
<term>Blood sampling</term>
<term>Blood supply</term>
<term>Blood vessels</term>
<term>Bochum</term>
<term>Body cells</term>
<term>Body fluids</term>
<term>Body temperature</term>
<term>Body temperatures</term>
<term>Body weight</term>
<term>Bolus injections</term>
<term>Brain tissue</term>
<term>Brush border membrane</term>
<term>Brush border membranes</term>
<term>Calcium</term>
<term>Calcium antagonist verapamil</term>
<term>Calcium antagonists</term>
<term>Calcium currents</term>
<term>Calcium transport</term>
<term>Calcium uptake</term>
<term>Calmodulin</term>
<term>Canine</term>
<term>Canine femoral arteries</term>
<term>Canine femoral artery</term>
<term>Canine stomach</term>
<term>Carboxyl groups</term>
<term>Cardiac</term>
<term>Cardiac cycle</term>
<term>Cardiac myocytes</term>
<term>Cardiac output</term>
<term>Carotid</term>
<term>Carotid body cells</term>
<term>Carotid chemodenervated rabbits</term>
<term>Cation</term>
<term>Cell bodies</term>
<term>Cell body</term>
<term>Cell ghosts</term>
<term>Cell membrane</term>
<term>Cell membrane conductance</term>
<term>Cell populations</term>
<term>Cell shape</term>
<term>Cell sizes</term>
<term>Cell types</term>
<term>Cell velocity</term>
<term>Cells show</term>
<term>Cellular functions</term>
<term>Central chemosensitive drive</term>
<term>Central chemosensitivity</term>
<term>Central zones</term>
<term>Cerebral cortex</term>
<term>Channel number</term>
<term>Channel openings</term>
<term>Charge carrier</term>
<term>Chemical sympathectomy</term>
<term>Chemical synapses</term>
<term>Chloride concentration</term>
<term>Choline</term>
<term>Cholinergic</term>
<term>Cholinergic innervation</term>
<term>Cholinergic mechanism</term>
<term>Cholinergic pathways</term>
<term>Circadian rhythms</term>
<term>Cirrhosis</term>
<term>Clozapine</term>
<term>Cluster duration</term>
<term>Cochlear duct</term>
<term>Cold fibre activity</term>
<term>Cold fibres</term>
<term>Cold receptors</term>
<term>Collateral</term>
<term>Condensor discharges</term>
<term>Conductance</term>
<term>Conduction</term>
<term>Conduction velocities</term>
<term>Conductive pathway</term>
<term>Confinement stress</term>
<term>Conscious rats</term>
<term>Contact structures</term>
<term>Continuous work load</term>
<term>Contractile</term>
<term>Contractile response</term>
<term>Contralateral</term>
<term>Control conditions</term>
<term>Control level</term>
<term>Control levels</term>
<term>Control period</term>
<term>Control solution</term>
<term>Control value</term>
<term>Control values</term>
<term>Conventional microelectrodes</term>
<term>Convoluted tubules</term>
<term>Coronary</term>
<term>Coronary arteries</term>
<term>Coronary blood flow</term>
<term>Coronary flow</term>
<term>Coronary reserve</term>
<term>Coronary stenosis</term>
<term>Coronary vasoconstriction</term>
<term>Coronary venous</term>
<term>Cortex</term>
<term>Cortical</term>
<term>Cortical neurons</term>
<term>Cortical surface</term>
<term>Cotransport system</term>
<term>Ctal</term>
<term>Ctal segments</term>
<term>Cuff</term>
<term>Cuff method</term>
<term>Current pulses</term>
<term>Curvature</term>
<term>Cytosolic enzymes</term>
<term>Deafferented parts</term>
<term>Deep tissues</term>
<term>Deeper laminae</term>
<term>Dendrite</term>
<term>Dendritic</term>
<term>Deoxygenated blood</term>
<term>Depolarization</term>
<term>Depolarizing</term>
<term>Deutsche</term>
<term>Deutsche forschungsgemeinschaft</term>
<term>Diastolic blood pressure</term>
<term>Diel rhythm</term>
<term>Different concentrations</term>
<term>Different frequency bands</term>
<term>Different hemodynamic conditions</term>
<term>Different responses</term>
<term>Different sites</term>
<term>Diffraction pattern</term>
<term>Dilation</term>
<term>Direct action</term>
<term>Direct measurement</term>
<term>Discharge activity</term>
<term>Discharge frequency</term>
<term>Discharge pattern</term>
<term>Discharge rate</term>
<term>Dlgn</term>
<term>Donnan ratios</term>
<term>Dorsal</term>
<term>Dorsal border</term>
<term>Dorsal skinfolds</term>
<term>Dos</term>
<term>Dose response curves</term>
<term>Duct</term>
<term>Dynamic response</term>
<term>Dynamic responses</term>
<term>Dynamic rheological properties</term>
<term>Effective concentrations</term>
<term>Egta</term>
<term>Ehrenstein figures</term>
<term>Electrical properties</term>
<term>Electrical response</term>
<term>Electrical stimulation</term>
<term>Electrochemical gradient</term>
<term>Electrode</term>
<term>Electrogenic</term>
<term>Electromagnetic</term>
<term>Electromagnetic field</term>
<term>Electromagnetic fields</term>
<term>Endoplasmic</term>
<term>Endoplasmic reticulum</term>
<term>Endothelial cells</term>
<term>Endothelial removal</term>
<term>Endothelium</term>
<term>Endplate</term>
<term>Endurance performance</term>
<term>Energy deficiency</term>
<term>Enzyme</term>
<term>Epileptiform</term>
<term>Ergometer</term>
<term>Erlangen</term>
<term>Erythrocyte</term>
<term>Erythrocyte deformability</term>
<term>Essen</term>
<term>Ethacrynic acid</term>
<term>Ether stress</term>
<term>Ethoxzolamide concentration</term>
<term>Excretion</term>
<term>Experimental conditions</term>
<term>Experimental medicine</term>
<term>Experimentelle medizin</term>
<term>Exponential</term>
<term>Extracellular</term>
<term>Extracellular space</term>
<term>Fatty acids</term>
<term>Febs lett</term>
<term>Feld</term>
<term>Femoral</term>
<term>Fiber axis</term>
<term>Fibre</term>
<term>Fibrillation</term>
<term>Fibrin</term>
<term>Fibrin layer</term>
<term>Field potentials</term>
<term>First appearance</term>
<term>First half</term>
<term>First week</term>
<term>Flexor</term>
<term>Flexor activity</term>
<term>Flow pulse</term>
<term>Fluid transport</term>
<term>Fluid transport rates</term>
<term>Focal epileptiform discharges</term>
<term>Focal epileptiform potentials</term>
<term>Focal ischemia</term>
<term>Focal plane</term>
<term>Force production</term>
<term>Former studies</term>
<term>Forschungsgemeinschaft</term>
<term>Fractional resistance</term>
<term>Free flow</term>
<term>Freiburg</term>
<term>Freien berlin</term>
<term>Frequency channels</term>
<term>Frequency domain</term>
<term>Frequency response</term>
<term>Frog</term>
<term>Frog kidney</term>
<term>Frog nerve</term>
<term>Frog nodes</term>
<term>Functional integrity</term>
<term>Functional recovery</term>
<term>Functional significance</term>
<term>Further experiments</term>
<term>Fusimotor action</term>
<term>G6ttingen</term>
<term>Gaba</term>
<term>Ganglion</term>
<term>Ganglionic transmission</term>
<term>Gating currents</term>
<term>Geniculate</term>
<term>Geniculate nucleus</term>
<term>Giessen</term>
<term>Glial cells</term>
<term>Glucose</term>
<term>Glutamate</term>
<term>Glutamine resorption</term>
<term>Gradient apparatus</term>
<term>Guinea</term>
<term>Hansastr</term>
<term>Head movements</term>
<term>Heart rate</term>
<term>Heat clearance</term>
<term>Heat loss</term>
<term>Heat production</term>
<term>Heidelberg</term>
<term>Hematocrit</term>
<term>Hemodilution</term>
<term>Hemoglobin oxygenation</term>
<term>High threshold</term>
<term>Higher concentration</term>
<term>Higher concentrations</term>
<term>Higher threshold temperatures</term>
<term>Higher values</term>
<term>Hippocampal</term>
<term>Hippocampal slices</term>
<term>Histogram</term>
<term>Homogenate</term>
<term>Horseradish peroxidase</term>
<term>Human erythrocytes</term>
<term>Hydrodynamic conditions</term>
<term>Hydronephrotic</term>
<term>Hydronephrotic kidney</term>
<term>Hypophysial portal vessels</term>
<term>Hypoxia</term>
<term>Hypoxic</term>
<term>Hypoxic dilatation</term>
<term>Impedance</term>
<term>Important role</term>
<term>Impulse activity</term>
<term>Impulse groups</term>
<term>Impulse rate</term>
<term>Impulse rates</term>
<term>Inactivation</term>
<term>Increment threshold</term>
<term>Incubation medium</term>
<term>Independence principle</term>
<term>Indirect evidence</term>
<term>Infusion</term>
<term>Inhibition</term>
<term>Inhibitor</term>
<term>Inhibitory</term>
<term>Inhibitory postsynaptic currents</term>
<term>Injection</term>
<term>Inner segment</term>
<term>Inorganic sulfate</term>
<term>Inosine</term>
<term>Input resistance</term>
<term>Inst</term>
<term>Institut</term>
<term>Institut fuer physiologie</term>
<term>Institut physiologie</term>
<term>Intact cats</term>
<term>Intact controls</term>
<term>Intermediate area</term>
<term>Intermittent exercise</term>
<term>Intermittent work load</term>
<term>Intracapillary hemoglobin spectra</term>
<term>Intracellular</term>
<term>Intracellular recordings</term>
<term>Intracellular space</term>
<term>Intraluminal hypoxia</term>
<term>Intramyocardial oxygen pressure</term>
<term>Intrapulmonary chemoreceptors</term>
<term>Intravenous injections</term>
<term>Intravesicular</term>
<term>Intravesicular acidification</term>
<term>Ion</term>
<term>Ischemia</term>
<term>Ischemic</term>
<term>Ischemic area</term>
<term>Isoenzyme pattern</term>
<term>Isometric</term>
<term>Isometric conditions</term>
<term>Isometric tension</term>
<term>Isoproterenol</term>
<term>Isotonic solutions</term>
<term>Isovolemic hemodilution</term>
<term>Jggc</term>
<term>Kardiologie</term>
<term>Kardiologie g6ttingen</term>
<term>Kennedyallee</term>
<term>Kidney</term>
<term>Kidney cells</term>
<term>Kidney cortex</term>
<term>Kidney slices</term>
<term>Kiel</term>
<term>Kinetics</term>
<term>Klaus paulat</term>
<term>Klinik</term>
<term>Krebs solution</term>
<term>Lactic acid</term>
<term>Lamina</term>
<term>Large number</term>
<term>Large vessel resistance</term>
<term>Latency</term>
<term>Lateral</term>
<term>Lateral diffusion</term>
<term>Lateral geniculate</term>
<term>Lateral geniculate nucleus</term>
<term>Lehrstuhl</term>
<term>Lehrstuhl zellphysiologie</term>
<term>Lesion</term>
<term>Light chain phosphorylation</term>
<term>Light diffraction</term>
<term>Light intensity</term>
<term>Lipid</term>
<term>Liver cirrhosis</term>
<term>Load reduction</term>
<term>Local application</term>
<term>Local oxygen supply</term>
<term>Looo berlin</term>
<term>Lower activity</term>
<term>Lower values</term>
<term>Lowest values</term>
<term>Lumen</term>
<term>Luminal</term>
<term>Luminal application</term>
<term>Luminal membrane resistance</term>
<term>Luminance</term>
<term>Lung inflation</term>
<term>Lung volume</term>
<term>Main laminae</term>
<term>Mainz</term>
<term>Male wistar rats</term>
<term>Marburg</term>
<term>Maternal side</term>
<term>Mathematical model</term>
<term>Maximal</term>
<term>Maximal isometric force</term>
<term>Maximum response</term>
<term>Mechanical activity</term>
<term>Mechanical properties</term>
<term>Mechanical response</term>
<term>Mechanical thresholds</term>
<term>Mechanosensitive units</term>
<term>Median</term>
<term>Median conduction</term>
<term>Median eminence</term>
<term>Medullary</term>
<term>Membrane</term>
<term>Membrane conductance</term>
<term>Membrane currents</term>
<term>Membrane curvature</term>
<term>Membrane patches</term>
<term>Membrane potentials</term>
<term>Membrane resistance</term>
<term>Membrane vesicles</term>
<term>Menthol</term>
<term>Menthol application</term>
<term>Mesencephalic reticular formation</term>
<term>Metabolism</term>
<term>Microelectrodes</term>
<term>Minimum values</term>
<term>Minor degree</term>
<term>Mmhg</term>
<term>Mongolian gerbils</term>
<term>Mongrel dogs</term>
<term>Monosynaptic connection</term>
<term>More detail</term>
<term>Motor behaviour</term>
<term>Motor function</term>
<term>Mtal segments</term>
<term>Multiwire surface electrode</term>
<term>Muscle cells</term>
<term>Muscle preparations</term>
<term>Myocardial</term>
<term>Myocardial oxygen consumption</term>
<term>Myocytes</term>
<term>Myosin</term>
<term>Myosin light chain phosphorylation</term>
<term>Naci</term>
<term>Naci secretion</term>
<term>Naocn treatment</term>
<term>Necturus gallbladder</term>
<term>Negative direction</term>
<term>Negative membrane curvature</term>
<term>Neon color effect</term>
<term>Nerve</term>
<term>Nerve fibres</term>
<term>Nerve section</term>
<term>Nerve stimulation</term>
<term>Nerve suture</term>
<term>Neuenheimer</term>
<term>Neuenheimer feld</term>
<term>Neural activity</term>
<term>Neural response</term>
<term>Neurologische klinik</term>
<term>Neuron</term>
<term>Neuronal</term>
<term>Neurones</term>
<term>Neuropharmacology research group</term>
<term>Neurosci</term>
<term>Node</term>
<term>Nonlinear behaviour</term>
<term>Normal conditions</term>
<term>Normal sodium</term>
<term>Normothermic anoxia</term>
<term>Normoxic blood</term>
<term>Noxious</term>
<term>Oberer</term>
<term>Oberer eselsberg</term>
<term>Occlusion</term>
<term>Olfactory cortex neurones</term>
<term>Oncotic agents</term>
<term>Open time</term>
<term>Open times</term>
<term>Oscillation frequency</term>
<term>Other authors</term>
<term>Other hand</term>
<term>Ouabain</term>
<term>Overshoot</term>
<term>Oxydative enzymes</term>
<term>Oxygen consumption</term>
<term>Oxygen deficiency</term>
<term>Oxygen distribution</term>
<term>Oxygen lack</term>
<term>Oxygen paradox</term>
<term>Oxygen supply</term>
<term>Oxygen tension</term>
<term>Oxygen uptake</term>
<term>Oxygenated blood</term>
<term>Oxygenation</term>
<term>Pancreatic</term>
<term>Pancreatic acinar cells</term>
<term>Pancreatic duct</term>
<term>Pancreatic proteins</term>
<term>Paracellular</term>
<term>Paracellular pathway</term>
<term>Paracellular resistance</term>
<term>Patch electrode</term>
<term>Patch pipette</term>
<term>Pathway</term>
<term>Pdte</term>
<term>Peak responders</term>
<term>Peptide</term>
<term>Perfusate</term>
<term>Perfused</term>
<term>Perfusion</term>
<term>Perfusion distance</term>
<term>Perfusion resistance</term>
<term>Perfusional diuresis</term>
<term>Perigeniculate</term>
<term>Perigeniculate nucleus</term>
<term>Periphery effect</term>
<term>Peritubular</term>
<term>Peritubular cell membrane</term>
<term>Permeability</term>
<term>Permeabilized cells</term>
<term>Peroneal nerve</term>
<term>Pflogers arch</term>
<term>Pflugers arch</term>
<term>Phasic</term>
<term>Phasic contractions</term>
<term>Phasic type</term>
<term>Phenylalanine</term>
<term>Physiol</term>
<term>Physiological range</term>
<term>Physiologie</term>
<term>Physiologisches</term>
<term>Physiologisches institut</term>
<term>Physiology</term>
<term>Pifc stimuli</term>
<term>Pipette</term>
<term>Placental</term>
<term>Planar bilayers</term>
<term>Plasma membrane</term>
<term>Plasma membranes</term>
<term>Platelet</term>
<term>Platelet aggregation</term>
<term>Positive curvature</term>
<term>Postoperative</term>
<term>Postsynaptic</term>
<term>Potassium activity</term>
<term>Pregnant guinea pigs</term>
<term>Preoptic area</term>
<term>Present experiments</term>
<term>Present study</term>
<term>Previous investigations</term>
<term>Previous studies</term>
<term>Previous study</term>
<term>Prostaglandin</term>
<term>Protein concentration</term>
<term>Proximal</term>
<term>Proximal tubule</term>
<term>Proximal tubules</term>
<term>Pulpal temperature</term>
<term>Pulsatile flow</term>
<term>Pulse</term>
<term>Pursuit neurons</term>
<term>Quantitative information</term>
<term>Quiet breathing</term>
<term>Quinidine</term>
<term>Rabbit aorta</term>
<term>Rabbit kidney</term>
<term>Radiant heat</term>
<term>Radiolabeled urea</term>
<term>Ranvier nodes</term>
<term>Rapid cooling</term>
<term>Rapid decline</term>
<term>Rat</term>
<term>Rate constants</term>
<term>Reabsorption</term>
<term>Reactive hyperemia</term>
<term>Receptor</term>
<term>Receptor layer</term>
<term>Recording site</term>
<term>Rectal gland tubule</term>
<term>Regensburg</term>
<term>Regional function</term>
<term>Regression equations</term>
<term>Regulatory mechanism</term>
<term>Reinnervated tibialis muscle</term>
<term>Relative power</term>
<term>Removal depolarizes</term>
<term>Renal</term>
<term>Renal blood flow</term>
<term>Renal cortex</term>
<term>Renin</term>
<term>Renin release</term>
<term>Repetitive stimulation</term>
<term>Resp</term>
<term>Respiration</term>
<term>Respiration rate</term>
<term>Respiratory system</term>
<term>Response characteristics</term>
<term>Response curves</term>
<term>Results show</term>
<term>Reticular</term>
<term>Reticular formation</term>
<term>Reticulum</term>
<term>Reversal</term>
<term>Reversal stimuli</term>
<term>Reversible diminution</term>
<term>Ringer</term>
<term>Ringer infusion</term>
<term>Ringer solution</term>
<term>Room temperature</term>
<term>Root effect</term>
<term>Rough endoplasmic reticulum</term>
<term>Rwth</term>
<term>Rwth aachen</term>
<term>Same conditions</term>
<term>Same latency</term>
<term>Same time</term>
<term>Sarcoplasmic reticulum</term>
<term>Scalp location</term>
<term>Science foundation</term>
<term>Secondary endings</term>
<term>Segment</term>
<term>Series resistance</term>
<term>Several lines</term>
<term>Short duration</term>
<term>Short pathways</term>
<term>Short period</term>
<term>Shunt characteristics</term>
<term>Significant difference</term>
<term>Significant effect</term>
<term>Significant increase</term>
<term>Silicone membrane</term>
<term>Single cells</term>
<term>Single channel</term>
<term>Single channel currents</term>
<term>Single injection</term>
<term>Single lsras</term>
<term>Sinus</term>
<term>Sinus rhythm</term>
<term>Sinusoidal</term>
<term>Skeletal muscle</term>
<term>Skeletal muscles</term>
<term>Skin blood flow</term>
<term>Skin sites</term>
<term>Skin temperature</term>
<term>Slight enhancement</term>
<term>Slight increase</term>
<term>Small amounts</term>
<term>Smooth muscle</term>
<term>Smooth muscle cells</term>
<term>Smooth pursuit</term>
<term>Sodium channels</term>
<term>Sodium currents</term>
<term>Spatial distribution</term>
<term>Spatial frequencies</term>
<term>Speckmann</term>
<term>Spike</term>
<term>Spinal</term>
<term>Spontaneous activity</term>
<term>Spontaneous hypertension</term>
<term>Stable potentiation</term>
<term>Standard referenced</term>
<term>Steady state</term>
<term>Steady value</term>
<term>Stenosis</term>
<term>Step depolarizations</term>
<term>Stimulation</term>
<term>Stimulus</term>
<term>Stimulus strength</term>
<term>Stretch receptors</term>
<term>Stretch reflex</term>
<term>Stroke volume</term>
<term>Strong evidence</term>
<term>Sulfate</term>
<term>Superfusion</term>
<term>Sural nerve</term>
<term>Surface electrode</term>
<term>Sweet glands</term>
<term>Sympathetic ganglia</term>
<term>Sympathetic preganglionic neurones</term>
<term>Sympathetic stimulation</term>
<term>Synapse</term>
<term>Synaptic</term>
<term>Synaptic transmission</term>
<term>Systolic</term>
<term>Systolic blood pressure</term>
<term>Taainduced liver cirrhosis</term>
<term>Tail artery</term>
<term>Tail currents</term>
<term>Taste receptors</term>
<term>Taste sensations</term>
<term>Technical assistance</term>
<term>Temperature ramps</term>
<term>Temperature range</term>
<term>Thermal gradient</term>
<term>Thermal information transfer</term>
<term>Thermoregulatory system</term>
<term>Theta</term>
<term>Theta activity</term>
<term>Theta changes</term>
<term>Threshold pressure</term>
<term>Threshold temperature</term>
<term>Threshold temperatures</term>
<term>Tibialis</term>
<term>Tibialis muscle</term>
<term>Time constants</term>
<term>Time course</term>
<term>Time courses</term>
<term>Tion</term>
<term>Tissue oxygenation</term>
<term>Tonic</term>
<term>Tonic type</term>
<term>Torr</term>
<term>Tracer</term>
<term>Tracer fraction</term>
<term>Transepithelial</term>
<term>Transepithelial resistance</term>
<term>Transient</term>
<term>Transneuronal atrophy</term>
<term>Transparent chambers</term>
<term>Transport system</term>
<term>Transport systems</term>
<term>Transthoracic puncture</term>
<term>Tubingen</term>
<term>Tubular</term>
<term>Tubular cells</term>
<term>Tubular segments</term>
<term>Tubular wall</term>
<term>Tubule</term>
<term>Tubule fragments</term>
<term>Tubule lumen</term>
<term>Typical marker</term>
<term>Unit activity</term>
<term>Univ</term>
<term>University winterthurerstrasse</term>
<term>Unpleasurable feelings</term>
<term>Untreated</term>
<term>Uptake</term>
<term>Urea</term>
<term>Urine</term>
<term>Vagal reflexes</term>
<term>Valproate</term>
<term>Various types</term>
<term>Vascular</term>
<term>Vascular tone</term>
<term>Velocity components</term>
<term>Venous pressure</term>
<term>Ventral</term>
<term>Ventral medullary surface</term>
<term>Ventricular</term>
<term>Ventricular perfusion</term>
<term>Vesicle</term>
<term>Vessel wall</term>
<term>Vessel walls</term>
<term>Vestibular</term>
<term>Visual cortex</term>
<term>Visual deafferentation</term>
<term>Visual field</term>
<term>Visual functions</term>
<term>Visual system</term>
<term>Visual targets</term>
<term>Vivo</term>
<term>Vulnerable period</term>
<term>Walden</term>
<term>Warm spot</term>
<term>Warm spots</term>
<term>Water temperature</term>
<term>West germany</term>
<term>White matter</term>
<term>Witte</term>
<term>Work load</term>
<term>Zentren physiologie</term>
<term>Zentrum</term>
<term>Zentrum physiologie</term>
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<json:string>renin</json:string>
<json:string>postoperative</json:string>
<json:string>phenylalanine</json:string>
<json:string>collateral</json:string>
<json:string>tubingen</json:string>
<json:string>althesin</json:string>
<json:string>overshoot</json:string>
<json:string>neuronal</json:string>
<json:string>cuff</json:string>
<json:string>cell membrane</json:string>
<json:string>atrial fibrillation</json:string>
<json:string>basolateral membrane</json:string>
<json:string>membrane curvature</json:string>
<json:string>spike</json:string>
<json:string>sinus</json:string>
<json:string>canine</json:string>
<json:string>median</json:string>
<json:string>proximal</json:string>
<json:string>duct</json:string>
<json:string>infusion</json:string>
<json:string>exponential</json:string>
<json:string>previous study</json:string>
<json:string>incubation medium</json:string>
<json:string>pancreatic proteins</json:string>
<json:string>oxygen consumption</json:string>
<json:string>intermittent exercise</json:string>
<json:string>root effect</json:string>
<json:string>cell types</json:string>
<json:string>skin blood flow</json:string>
<json:string>visual cortex</json:string>
<json:string>channel openings</json:string>
<json:string>cold fibre activity</json:string>
<json:string>zentrum physiologie</json:string>
<json:string>peritubular cell membrane</json:string>
<json:string>liver cirrhosis</json:string>
<json:string>tibialis muscle</json:string>
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<json:string>uptake</json:string>
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<json:string>anaesthesia</json:string>
<json:string>kidney</json:string>
<json:string>rat</json:string>
<json:string>lumen</json:string>
<json:string>intracellular recordings</json:string>
<json:string>same time</json:string>
<json:string>blood supply</json:string>
<json:string>discharge pattern</json:string>
<json:string>arterial blood pressure</json:string>
<json:string>ambient temperature</json:string>
<json:string>cold receptors</json:string>
<json:string>discharge rate</json:string>
<json:string>bicycle ergometer</json:string>
<json:string>cold fibres</json:string>
<json:string>membrane vesicles</json:string>
<json:string>intravesicular acidification</json:string>
<json:string>body temperature</json:string>
<json:string>sinus rhythm</json:string>
<json:string>proximal tubules</json:string>
<json:string>anesthetized dogs</json:string>
<json:string>multiwire surface electrode</json:string>
<json:string>electrical properties</json:string>
<json:string>hypoxic dilatation</json:string>
<json:string>intracellular space</json:string>
<json:string>ventral medullary surface</json:string>
<json:string>alpha activity</json:string>
<json:string>proximal tubule</json:string>
<json:string>intermittent work load</json:string>
<json:string>transport system</json:string>
<json:string>small amounts</json:string>
<json:string>erythrocyte deformability</json:string>
<json:string>heat clearance</json:string>
<json:string>normal conditions</json:string>
<json:string>ctal segments</json:string>
<json:string>transepithelial resistance</json:string>
<json:string>inorganic sulfate</json:string>
<json:string>median eminence</json:string>
<json:string>rwth aachen</json:string>
<json:string>cell ghosts</json:string>
<json:string>pflogers arch</json:string>
<json:string>rate constants</json:string>
<json:string>visual system</json:string>
<json:string>single cells</json:string>
<json:string>geniculate nucleus</json:string>
<json:string>body weight</json:string>
<json:string>extracellular space</json:string>
<json:string>neural activity</json:string>
<json:string>cell bodies</json:string>
<json:string>frequency response</json:string>
<json:string>cardiac output</json:string>
<json:string>nerve fibres</json:string>
<json:string>oberer eselsberg</json:string>
<json:string>peptide</json:string>
<json:string>tonic</json:string>
<json:string>anesthetized</json:string>
<json:string>amplitude</json:string>
<json:string>dilation</json:string>
<json:string>electrode</json:string>
<json:string>stimulation</json:string>
<json:string>urea</json:string>
<json:string>untreated</json:string>
<json:string>urine</json:string>
<json:string>dos</json:string>
<json:string>excretion</json:string>
<json:string>pulse</json:string>
<json:string>dynamic response</json:string>
<json:string>arterial pressure</json:string>
<json:string>respiration rate</json:string>
<json:string>intermediate area</json:string>
<json:string>oncotic agents</json:string>
<json:string>tubular wall</json:string>
<json:string>sarcoplasmic reticulum</json:string>
<json:string>kidney slices</json:string>
<json:string>maximal isometric force</json:string>
<json:string>dorsal border</json:string>
<json:string>lower values</json:string>
<json:string>smooth muscle cells</json:string>
<json:string>input resistance</json:string>
<json:string>paracellular pathway</json:string>
<json:string>rabbit kidney</json:string>
<json:string>control period</json:string>
<json:string>dynamic responses</json:string>
<json:string>skin temperature</json:string>
<json:string>anoxic conditions</json:string>
<json:string>fractional resistance</json:string>
<json:string>fibrin layer</json:string>
<json:string>isotonic solutions</json:string>
<json:string>slight enhancement</json:string>
<json:string>plasma membrane</json:string>
<json:string>more detail</json:string>
<json:string>apparent cell membrane resistance</json:string>
<json:string>lateral diffusion</json:string>
<json:string>lehrstuhl zellphysiologie</json:string>
<json:string>transthoracic puncture</json:string>
<json:string>permeabilized cells</json:string>
<json:string>naci secretion</json:string>
<json:string>bilateral vagotomy</json:string>
<json:string>single channel</json:string>
<json:string>naocn treatment</json:string>
<json:string>steady state</json:string>
<json:string>minimum values</json:string>
<json:string>lung volume</json:string>
<json:string>acta physiol</json:string>
<json:string>membrane currents</json:string>
<json:string>series resistance</json:string>
<json:string>head movements</json:string>
<json:string>abducens nuclei</json:string>
<json:string>impulse rate</json:string>
<json:string>pursuit neurons</json:string>
<json:string>significant increase</json:string>
<json:string>reversal stimuli</json:string>
<json:string>stimulus strength</json:string>
<json:string>renin release</json:string>
<json:string>kidney cortex</json:string>
<json:string>transneuronal atrophy</json:string>
<json:string>canine femoral arteries</json:string>
<json:string>threshold pressure</json:string>
<json:string>normal sodium</json:string>
<json:string>cell velocity</json:string>
<json:string>response curves</json:string>
<json:string>coronary flow</json:string>
<json:string>visual functions</json:string>
<json:string>physiological range</json:string>
<json:string>control level</json:string>
<json:string>cochlear duct</json:string>
<json:string>brush border membranes</json:string>
<json:string>angular displacement</json:string>
<json:string>body temperatures</json:string>
<json:string>recording site</json:string>
<json:string>gating currents</json:string>
<json:string>body fluids</json:string>
<json:string>open time</json:string>
<json:string>control solution</json:string>
<json:string>coronary arteries</json:string>
<json:string>open times</json:string>
<json:string>institut physiologie</json:string>
<json:string>membrane conductance</json:string>
<json:string>diel rhythm</json:string>
<json:string>regulatory mechanism</json:string>
<json:string>negative direction</json:string>
<json:string>independence principle</json:string>
<json:string>oxygen lack</json:string>
<json:string>reticular formation</json:string>
<json:string>cuff method</json:string>
<json:string>actin myosin interaction kinetics</json:string>
<json:string>ventricular perfusion</json:string>
<json:string>frequency domain</json:string>
<json:string>results show</json:string>
<json:string>reinnervated tibialis muscle</json:string>
<json:string>electromagnetic field</json:string>
<json:string>important role</json:string>
<json:string>respiratory system</json:string>
<json:string>central chemosensitivity</json:string>
<json:string>ringer solution</json:string>
<json:string>control conditions</json:string>
<json:string>membrane resistance</json:string>
<json:string>cell body</json:string>
<json:string>isovolemic hemodilution</json:string>
<json:string>intramyocardial oxygen pressure</json:string>
<json:string>ganglionic transmission</json:string>
<json:string>platelet aggregation</json:string>
<json:string>lactic acid</json:string>
<json:string>systolic blood pressure</json:string>
<json:string>ischemic area</json:string>
<json:string>ether stress</json:string>
<json:string>work load</json:string>
<json:string>cortex</json:string>
<json:string>conduction</json:string>
<json:string>transient</json:string>
<json:string>vivo</json:string>
<json:string>injection</json:string>
<json:string>inactivation</json:string>
<json:string>reversal</json:string>
<json:string>metabolism</json:string>
<json:string>coronary</json:string>
<json:string>stimulus</json:string>
<json:string>inhibitor</json:string>
<json:string>fibrin</json:string>
<json:string>maximal</json:string>
<json:string>guinea</json:string>
<json:string>tubular</json:string>
<json:string>calcium</json:string>
<json:string>antagonist</json:string>
<json:string>cortical</json:string>
<json:string>lesion</json:string>
<json:string>respiration</json:string>
<json:string>sinusoidal</json:string>
<json:string>myocardial</json:string>
<json:string>nerve</json:string>
<json:string>contact structures</json:string>
<json:string>neurologische klinik</json:string>
<json:string>lowest values</json:string>
<json:string>hemoglobin oxygenation</json:string>
<json:string>calcium antagonists</json:string>
<json:string>muscle preparations</json:string>
<json:string>abteilung nierenphysiologie</json:string>
<json:string>acute volume expansion</json:string>
<json:string>surface electrode</json:string>
<json:string>ethacrynic acid</json:string>
<json:string>direct measurement</json:string>
<json:string>coronary venous</json:string>
<json:string>renal blood flow</json:string>
<json:string>oxygen supply</json:string>
<json:string>slight increase</json:string>
<json:string>paracellular resistance</json:string>
<json:string>cytosolic enzymes</json:string>
<json:string>phasic contractions</json:string>
<json:string>oxygen paradox</json:string>
<json:string>zentren physiologie</json:string>
<json:string>lower activity</json:string>
<json:string>adaptive process</json:string>
<json:string>mtal segments</json:string>
<json:string>single injection</json:string>
<json:string>direct action</json:string>
<json:string>ringer infusion</json:string>
<json:string>perfusion resistance</json:string>
<json:string>perfusional diuresis</json:string>
<json:string>deep tissues</json:string>
<json:string>kardiologie g6ttingen</json:string>
<json:string>cardiac myocytes</json:string>
<json:string>mechanosensitive units</json:string>
<json:string>fatty acids</json:string>
<json:string>hydronephrotic kidney</json:string>
<json:string>thermal information transfer</json:string>
<json:string>short pathways</json:string>
<json:string>febs lett</json:string>
<json:string>focal plane</json:string>
<json:string>median conduction</json:string>
<json:string>secondary endings</json:string>
<json:string>human erythrocytes</json:string>
<json:string>membrane patches</json:string>
<json:string>transport systems</json:string>
<json:string>maternal side</json:string>
<json:string>spontaneous hypertension</json:string>
<json:string>cell membrane conductance</json:string>
<json:string>necturus gallbladder</json:string>
<json:string>deeper laminae</json:string>
<json:string>canine stomach</json:string>
<json:string>electrical response</json:string>
<json:string>indirect evidence</json:string>
<json:string>cotransport system</json:string>
<json:string>tissue oxygenation</json:string>
<json:string>calcium uptake</json:string>
<json:string>rough endoplasmic reticulum</json:string>
<json:string>preoptic area</json:string>
<json:string>pancreatic acinar cells</json:string>
<json:string>typical marker</json:string>
<json:string>freien berlin</json:string>
<json:string>strong evidence</json:string>
<json:string>hydrodynamic conditions</json:string>
<json:string>rectal gland tubule</json:string>
<json:string>velocity components</json:string>
<json:string>further experiments</json:string>
<json:string>conductive pathway</json:string>
<json:string>room temperature</json:string>
<json:string>patch electrode</json:string>
<json:string>brush border membrane</json:string>
<json:string>patch pipette</json:string>
<json:string>chloride concentration</json:string>
<json:string>conscious rats</json:string>
<json:string>calcium transport</json:string>
<json:string>higher concentration</json:string>
<json:string>planar bilayers</json:string>
<json:string>minor degree</json:string>
<json:string>university winterthurerstrasse</json:string>
<json:string>science foundation</json:string>
<json:string>radiolabeled urea</json:string>
<json:string>charge carrier</json:string>
<json:string>intraluminal hypoxia</json:string>
<json:string>temperature ramps</json:string>
<json:string>transparent chambers</json:string>
<json:string>quantitative information</json:string>
<json:string>different responses</json:string>
<json:string>cluster duration</json:string>
<json:string>single channel currents</json:string>
<json:string>receptor layer</json:string>
<json:string>inner segment</json:string>
<json:string>contractile response</json:string>
<json:string>canine femoral artery</json:string>
<json:string>steady value</json:string>
<json:string>protein concentration</json:string>
<json:string>mongrel dogs</json:string>
<json:string>alfried krupp krankenhaus</json:string>
<json:string>endothelial cells</json:string>
<json:string>smooth pursuit</json:string>
<json:string>functional integrity</json:string>
<json:string>impulse activity</json:string>
<json:string>several lines</json:string>
<json:string>activity pattern</json:string>
<json:string>increment threshold</json:string>
<json:string>pulsatile flow</json:string>
<json:string>scalp location</json:string>
<json:string>periphery effect</json:string>
<json:string>mechanical activity</json:string>
<json:string>temperature range</json:string>
<json:string>rapid cooling</json:string>
<json:string>cardiac cycle</json:string>
<json:string>phasic type</json:string>
<json:string>menthol application</json:string>
<json:string>tonic type</json:string>
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<json:string>vulnerable period</json:string>
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<json:string>short duration</json:string>
<json:string>mechanical response</json:string>
<json:string>spatial frequencies</json:string>
<json:string>significant difference</json:string>
<json:string>ehrenstein figures</json:string>
<json:string>neon color effect</json:string>
<json:string>pifc stimuli</json:string>
<json:string>isoenzyme pattern</json:string>
<json:string>visual deafferentation</json:string>
<json:string>oscillation frequency</json:string>
<json:string>cell sizes</json:string>
<json:string>deafferented parts</json:string>
<json:string>impulse groups</json:string>
<json:string>male wistar rats</json:string>
<json:string>warm spot</json:string>
<json:string>lateral geniculate nucleus</json:string>
<json:string>stretch reflex</json:string>
<json:string>stretch receptors</json:string>
<json:string>unit activity</json:string>
<json:string>anesthetized rats</json:string>
<json:string>isometric tension</json:string>
<json:string>mesencephalic reticular formation</json:string>
<json:string>time courses</json:string>
<json:string>cholinergic mechanism</json:string>
<json:string>lateral geniculate</json:string>
<json:string>skin sites</json:string>
<json:string>autonomic blockade</json:string>
<json:string>cholinergic pathways</json:string>
<json:string>cholinergic innervation</json:string>
<json:string>main laminae</json:string>
<json:string>tail artery</json:string>
<json:string>dynamic rheological properties</json:string>
<json:string>silicone membrane</json:string>
<json:string>vessel wall</json:string>
<json:string>visual field</json:string>
<json:string>cortical neurons</json:string>
<json:string>cells show</json:string>
<json:string>maximum response</json:string>
<json:string>peak responders</json:string>
<json:string>conventional microelectrodes</json:string>
<json:string>cell populations</json:string>
<json:string>mechanical properties</json:string>
<json:string>basilar membrane</json:string>
<json:string>endothelial removal</json:string>
<json:string>different concentrations</json:string>
<json:string>plasma membranes</json:string>
<json:string>spontaneous activity</json:string>
<json:string>standard referenced</json:string>
<json:string>bile pancreatic duct</json:string>
<json:string>spatial distribution</json:string>
<json:string>load reduction</json:string>
<json:string>large vessel resistance</json:string>
<json:string>potassium activity</json:string>
<json:string>sympathetic ganglia</json:string>
<json:string>oxygen tension</json:string>
<json:string>frog nodes</json:string>
<json:string>frog nerve</json:string>
<json:string>sodium currents</json:string>
<json:string>carboxyl groups</json:string>
<json:string>chemical sympathectomy</json:string>
<json:string>reversible diminution</json:string>
<json:string>stable potentiation</json:string>
<json:string>repetitive stimulation</json:string>
<json:string>bathing medium</json:string>
<json:string>synaptic transmission</json:string>
<json:string>afterload reduction</json:string>
<json:string>calcium currents</json:string>
<json:string>olfactory cortex neurones</json:string>
<json:string>basolateral membranes</json:string>
<json:string>step depolarizations</json:string>
<json:string>membrane potentials</json:string>
<json:string>other authors</json:string>
<json:string>neuropharmacology research group</json:string>
<json:string>tail currents</json:string>
<json:string>taste receptors</json:string>
<json:string>acetic acid</json:string>
<json:string>different sites</json:string>
<json:string>abteilung allgemeine</json:string>
<json:string>blood sampling</json:string>
<json:string>chemical synapses</json:string>
<json:string>neural response</json:string>
<json:string>taste sensations</json:string>
<json:string>ammonium chloride</json:string>
<json:string>inhibitory postsynaptic currents</json:string>
<json:string>electrochemical gradient</json:string>
<json:string>basolateral membrane vesicles</json:string>
<json:string>acetylcholine receptors</json:string>
<json:string>antiarrhythmic action</json:string>
<json:string>technical assistance</json:string>
<json:string>discharge activity</json:string>
<json:string>condensor discharges</json:string>
<json:string>normoxic blood</json:string>
<json:string>oxygen deficiency</json:string>
<json:string>sural nerve</json:string>
<json:string>glial cells</json:string>
<json:string>cerebral cortex</json:string>
<json:string>coronary vasoconstriction</json:string>
<json:string>field potentials</json:string>
<json:string>dose response curves</json:string>
<json:string>different hemodynamic conditions</json:string>
<json:string>myocardial oxygen consumption</json:string>
<json:string>frog kidney</json:string>
<json:string>looo berlin</json:string>
<json:string>sodium channels</json:string>
<json:string>channel number</json:string>
<json:string>pflugers arch</json:string>
<json:string>previous investigations</json:string>
<json:string>local application</json:string>
<json:string>higher concentrations</json:string>
<json:string>brain tissue</json:string>
<json:string>anaesthetized dogs</json:string>
<json:string>antidromic stimulation</json:string>
<json:string>significant effect</json:string>
<json:string>abteilung allgemeine physiologie</json:string>
<json:string>isometric conditions</json:string>
<json:string>vascular tone</json:string>
<json:string>force production</json:string>
<json:string>myosin light chain phosphorylation</json:string>
<json:string>light diffraction</json:string>
<json:string>diffraction pattern</json:string>
<json:string>fiber axis</json:string>
<json:string>light intensity</json:string>
<json:string>skeletal muscles</json:string>
<json:string>light chain phosphorylation</json:string>
<json:string>calcium antagonist verapamil</json:string>
<json:string>monosynaptic connection</json:string>
<json:string>single lsras</json:string>
<json:string>lung inflation</json:string>
<json:string>focal epileptiform discharges</json:string>
<json:string>tubule lumen</json:string>
<json:string>focal epileptiform potentials</json:string>
<json:string>cortical surface</json:string>
<json:string>previous studies</json:string>
<json:string>functional significance</json:string>
<json:string>functional recovery</json:string>
<json:string>peroneal nerve</json:string>
<json:string>nerve suture</json:string>
<json:string>water temperature</json:string>
<json:string>motor function</json:string>
<json:string>nerve stimulation</json:string>
<json:string>coronary blood flow</json:string>
<json:string>nerve section</json:string>
<json:string>control levels</json:string>
<json:string>flexor activity</json:string>
<json:string>first appearance</json:string>
<json:string>rapid decline</json:string>
<json:string>fusimotor action</json:string>
<json:string>experimental medicine</json:string>
<json:string>electromagnetic fields</json:string>
<json:string>luminal membrane resistance</json:string>
<json:string>visual targets</json:string>
<json:string>motor behaviour</json:string>
<json:string>anaesthetized cats</json:string>
<json:string>luminal application</json:string>
<json:string>deoxygenated blood</json:string>
<json:string>coronary reserve</json:string>
<json:string>large number</json:string>
<json:string>former studies</json:string>
<json:string>unpleasurable feelings</json:string>
<json:string>oxygen uptake</json:string>
<json:string>theta changes</json:string>
<json:string>rabbit aorta</json:string>
<json:string>various types</json:string>
<json:string>short period</json:string>
<json:string>bolus injections</json:string>
<json:string>central chemosensitive drive</json:string>
<json:string>sympathetic preganglionic neurones</json:string>
<json:string>horseradish peroxidase</json:string>
<json:string>arterial wall</json:string>
<json:string>white matter</json:string>
<json:string>sweet glands</json:string>
<json:string>convoluted tubules</json:string>
<json:string>reactive hyperemia</json:string>
<json:string>effective concentrations</json:string>
<json:string>tubule fragments</json:string>
<json:string>perfusion distance</json:string>
<json:string>intact cats</json:string>
<json:string>pregnant guinea pigs</json:string>
<json:string>first half</json:string>
<json:string>circadian rhythms</json:string>
<json:string>conduction velocities</json:string>
<json:string>diastolic blood pressure</json:string>
<json:string>radiant heat</json:string>
<json:string>first week</json:string>
<json:string>pulpal temperature</json:string>
<json:string>nonlinear behaviour</json:string>
<json:string>angewandte physiologie</json:string>
<json:string>mongolian gerbils</json:string>
<json:string>glutamine resorption</json:string>
<json:string>confinement stress</json:string>
<json:string>coronary stenosis</json:string>
<json:string>blood cells</json:string>
<json:string>afferent units</json:string>
<json:string>flow pulse</json:string>
<json:string>klaus paulat</json:string>
<json:string>intracapillary hemoglobin spectra</json:string>
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