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Publication DateGlia, ISSN 0894-1491, 12/2016, Volume 64, Issue 12, pp. 2166 - 2180
Multiple sclerosis is a chronic inflammatory, demyelinating degenerative disease of the central nervous system. Current treatments target pathological immune...
cuprizone | TRPA1 | MAPK | demyelination | oligodendrocyte | ION-CHANNEL TRPA1 | WHITE-MATTER | CNS DEMYELINATION | NEUROSCIENCES | BREAST-CANCER | MULTIPLE-SCLEROSIS | NOCICEPTIVE NEURONS | MOUSE MODEL | GENE-EXPRESSION | RECEPTOR POTENTIAL A1 | HYDROGEN-PEROXIDE | Apoptosis - drug effects | Demyelinating Diseases - genetics | Body Weight - drug effects | Gliosis - chemically induced | TRPA1 Cation Channel - deficiency | Apoptosis - genetics | bcl-2 Homologous Antagonist-Killer Protein - metabolism | Brain - metabolism | Oligodendroglia - drug effects | Fibroblast Growth Factor 2 - metabolism | Demyelinating Diseases - chemically induced | Demyelinating Diseases - pathology | Disease Models, Animal | Cuprizone - toxicity | Gliosis - genetics | Myelin Basic Protein - metabolism | Gene Expression Regulation - genetics | Adenomatous Polyposis Coli - metabolism | Mice, Knockout | Brain - drug effects | Gene Expression Regulation - drug effects | Nerve Tissue Proteins - metabolism | Monoamine Oxidase Inhibitors - toxicity | Animals | Signal Transduction - drug effects | Brain - pathology | Signal Transduction - physiology | TRPA1 Cation Channel - genetics | Mice | TRPA1 Cation Channel - metabolism | Multiple sclerosis | Nervous system diseases | Permeability | Analysis | Apoptosis | Nervous system | Kinases
cuprizone | TRPA1 | MAPK | demyelination | oligodendrocyte | ION-CHANNEL TRPA1 | WHITE-MATTER | CNS DEMYELINATION | NEUROSCIENCES | BREAST-CANCER | MULTIPLE-SCLEROSIS | NOCICEPTIVE NEURONS | MOUSE MODEL | GENE-EXPRESSION | RECEPTOR POTENTIAL A1 | HYDROGEN-PEROXIDE | Apoptosis - drug effects | Demyelinating Diseases - genetics | Body Weight - drug effects | Gliosis - chemically induced | TRPA1 Cation Channel - deficiency | Apoptosis - genetics | bcl-2 Homologous Antagonist-Killer Protein - metabolism | Brain - metabolism | Oligodendroglia - drug effects | Fibroblast Growth Factor 2 - metabolism | Demyelinating Diseases - chemically induced | Demyelinating Diseases - pathology | Disease Models, Animal | Cuprizone - toxicity | Gliosis - genetics | Myelin Basic Protein - metabolism | Gene Expression Regulation - genetics | Adenomatous Polyposis Coli - metabolism | Mice, Knockout | Brain - drug effects | Gene Expression Regulation - drug effects | Nerve Tissue Proteins - metabolism | Monoamine Oxidase Inhibitors - toxicity | Animals | Signal Transduction - drug effects | Brain - pathology | Signal Transduction - physiology | TRPA1 Cation Channel - genetics | Mice | TRPA1 Cation Channel - metabolism | Multiple sclerosis | Nervous system diseases | Permeability | Analysis | Apoptosis | Nervous system | Kinases
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Loading RightsPain, ISSN 0304-3959, 09/2012, Volume 153, Issue 9, pp. 1949 - 1958
TRPA1 is expressed on dural afferent neurons and activation of dural TRPA1 produces behavioral responses consistent with headache. Activation of transient...
Allodynia | Dura | Headache | TRPA1 | Migraine | Umbellulone | Mustard oil | ION-CHANNEL TRPA1 | NEUROGENIC INFLAMMATION | STIMULATION | ACID | RECEPTOR | NEUROSCIENCES | CLINICAL NEUROLOGY | NOCICEPTIVE NEURONS | SENSITIZATION | ANESTHESIOLOGY | ANKYRIN 1 TRPA1 | EXPRESSION | Mustard Plant | Neurons, Afferent - drug effects | Plant Oils - pharmacology | TRPC Cation Channels - agonists | Headache - metabolism | Rats | Trigeminal Ganglion - metabolism | Irritants - pharmacology | Male | Trigeminal Ganglion - drug effects | Rats, Sprague-Dawley | Monoterpenes - pharmacology | Patch-Clamp Techniques | Animals | TRPA1 Cation Channel | TRPC Cation Channels - metabolism | Dura Mater - drug effects | Dura Mater - metabolism | Neurons, Afferent - metabolism | In Vitro Techniques | Medical colleges | mustard oil | allodynia | migraine | umbellulone | headache | dura
Allodynia | Dura | Headache | TRPA1 | Migraine | Umbellulone | Mustard oil | ION-CHANNEL TRPA1 | NEUROGENIC INFLAMMATION | STIMULATION | ACID | RECEPTOR | NEUROSCIENCES | CLINICAL NEUROLOGY | NOCICEPTIVE NEURONS | SENSITIZATION | ANESTHESIOLOGY | ANKYRIN 1 TRPA1 | EXPRESSION | Mustard Plant | Neurons, Afferent - drug effects | Plant Oils - pharmacology | TRPC Cation Channels - agonists | Headache - metabolism | Rats | Trigeminal Ganglion - metabolism | Irritants - pharmacology | Male | Trigeminal Ganglion - drug effects | Rats, Sprague-Dawley | Monoterpenes - pharmacology | Patch-Clamp Techniques | Animals | TRPA1 Cation Channel | TRPC Cation Channels - metabolism | Dura Mater - drug effects | Dura Mater - metabolism | Neurons, Afferent - metabolism | In Vitro Techniques | Medical colleges | mustard oil | allodynia | migraine | umbellulone | headache | dura
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Loading RightsArthritis Research and Therapy, ISSN 1478-6354, 2016, Volume 18, Issue 1, p. 185
Background: Transient receptor potential ankyrin 1 (TRPA1) is a membrane-associated cation channel, widely expressed in neuronal cells and involved in...
Inflammation | Matrix metalloproteinase | Chondrocyte | TRPA1 | Osteoarthritis | ION-CHANNEL TRPA1 | INTRACELLULAR CALCIUM | INDUCED INFLAMMATION | RHEUMATOLOGY | HYPOXIA | A1 TRPA1 | PAIN | NOCICEPTIVE NEURONS | CULTURED HUMAN | GENE-EXPRESSION | SENSORY NERVES | Humans | Cells, Cultured | Nerve Tissue Proteins - analysis | Osteoarthritis - metabolism | Male | Transient Receptor Potential Channels - biosynthesis | Blotting, Western | Mice, Knockout | Calcium Channels - analysis | Transient Receptor Potential Channels - analysis | Animals | Cartilage, Articular - metabolism | TRPA1 Cation Channel | Nerve Tissue Proteins - biosynthesis | Polymerase Chain Reaction | Calcium Channels - biosynthesis | Mice | Chondrocytes - metabolism | Physiological aspects | Development and progression | Genetic aspects | Research | Cartilage cells
Inflammation | Matrix metalloproteinase | Chondrocyte | TRPA1 | Osteoarthritis | ION-CHANNEL TRPA1 | INTRACELLULAR CALCIUM | INDUCED INFLAMMATION | RHEUMATOLOGY | HYPOXIA | A1 TRPA1 | PAIN | NOCICEPTIVE NEURONS | CULTURED HUMAN | GENE-EXPRESSION | SENSORY NERVES | Humans | Cells, Cultured | Nerve Tissue Proteins - analysis | Osteoarthritis - metabolism | Male | Transient Receptor Potential Channels - biosynthesis | Blotting, Western | Mice, Knockout | Calcium Channels - analysis | Transient Receptor Potential Channels - analysis | Animals | Cartilage, Articular - metabolism | TRPA1 Cation Channel | Nerve Tissue Proteins - biosynthesis | Polymerase Chain Reaction | Calcium Channels - biosynthesis | Mice | Chondrocytes - metabolism | Physiological aspects | Development and progression | Genetic aspects | Research | Cartilage cells
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Loading RightsNeuron, ISSN 0896-6273, 06/2010, Volume 66, Issue 5, pp. 671 - 680
Human monogenic pain syndromes have provided important insights into the molecular mechanisms that underlie normal and pathological pain states. We describe an...
HUMDISEASE | MOLNEURO | SIGNALING | Signaling | Humdisease | Molneuro | MULTILOCUS LINKAGE ANALYSIS | IN-VITRO | ION-CHANNEL TRPA1 | COVALENT MODIFICATION | INFLAMMATORY PAIN | IRRITANT RECEPTOR TRPA1 | DIRECT ACTIVATION | COLD | MOLECULAR-BASIS | NEUROSCIENCES | SENSORY NEURONS | Amino Acid Sequence | Cell Line | Humans | Molecular Sequence Data | Nerve Tissue Proteins - genetics | Syndrome | Point Mutation - genetics | Pain Measurement - methods | Pain - genetics | Pain - physiopathology | Pedigree | Transient Receptor Potential Channels - genetics | TRPA1 Cation Channel | Calcium Channels - genetics | Neurosciences | Gene mutations | Analysis | Genes | Medical genetics | Genetic research | Genetic aspects | Sensors | Studies | Skin | Genomes | Mutation | Cold | Chromosomes | Clinical Study
HUMDISEASE | MOLNEURO | SIGNALING | Signaling | Humdisease | Molneuro | MULTILOCUS LINKAGE ANALYSIS | IN-VITRO | ION-CHANNEL TRPA1 | COVALENT MODIFICATION | INFLAMMATORY PAIN | IRRITANT RECEPTOR TRPA1 | DIRECT ACTIVATION | COLD | MOLECULAR-BASIS | NEUROSCIENCES | SENSORY NEURONS | Amino Acid Sequence | Cell Line | Humans | Molecular Sequence Data | Nerve Tissue Proteins - genetics | Syndrome | Point Mutation - genetics | Pain Measurement - methods | Pain - genetics | Pain - physiopathology | Pedigree | Transient Receptor Potential Channels - genetics | TRPA1 Cation Channel | Calcium Channels - genetics | Neurosciences | Gene mutations | Analysis | Genes | Medical genetics | Genetic research | Genetic aspects | Sensors | Studies | Skin | Genomes | Mutation | Cold | Chromosomes | Clinical Study
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Loading RightsJournal of Neuroscience, ISSN 0270-6474, 03/2008, Volume 28, Issue 10, pp. 2485 - 2494
Transient receptor potential A1 (TRPA1) is expressed in a subset of nociceptive sensory neurons where it acts as a sensor for environmental irritants,...
DRG | Oxidative stress | Hydrogen peroxide | TRPA1 | 15d-PGJ | 4-hydroxynonenal | ION-CHANNEL TRPA1 | LIPID OXIDATION | hydrogen peroxide | CARDIAC VAGAL AFFERENTS | 15D-PROSTAGLANDIN J | NEUROSCIENCES | FREE-RADICALS | REACTIVE OXYGEN | ISOPROSTANE PATHWAY | CYCLOPENTENONE PROSTAGLANDINS | COVALENT MODIFICATION | HYDROGEN-PEROXIDE | oxidative stress | Cricetinae | Cricetulus | Rats, Wistar | Humans | Oxidative Stress - physiology | Cells, Cultured | Ganglia, Spinal - physiology | Rats | Male | Transient Receptor Potential Channels - biosynthesis | Mice, Knockout | Dose-Response Relationship, Drug | Animals | Sensory Receptor Cells - physiology | Transient Receptor Potential Channels - genetics | Aldehydes - pharmacology | TRPA1 Cation Channel | Female | Mice | Oxidative Stress - drug effects | Transient Receptor Potential Channels - metabolism | Ganglia, Spinal - drug effects | CHO Cells | 15d-PGJ2
DRG | Oxidative stress | Hydrogen peroxide | TRPA1 | 15d-PGJ | 4-hydroxynonenal | ION-CHANNEL TRPA1 | LIPID OXIDATION | hydrogen peroxide | CARDIAC VAGAL AFFERENTS | 15D-PROSTAGLANDIN J | NEUROSCIENCES | FREE-RADICALS | REACTIVE OXYGEN | ISOPROSTANE PATHWAY | CYCLOPENTENONE PROSTAGLANDINS | COVALENT MODIFICATION | HYDROGEN-PEROXIDE | oxidative stress | Cricetinae | Cricetulus | Rats, Wistar | Humans | Oxidative Stress - physiology | Cells, Cultured | Ganglia, Spinal - physiology | Rats | Male | Transient Receptor Potential Channels - biosynthesis | Mice, Knockout | Dose-Response Relationship, Drug | Animals | Sensory Receptor Cells - physiology | Transient Receptor Potential Channels - genetics | Aldehydes - pharmacology | TRPA1 Cation Channel | Female | Mice | Oxidative Stress - drug effects | Transient Receptor Potential Channels - metabolism | Ganglia, Spinal - drug effects | CHO Cells | 15d-PGJ2
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Loading RightsCellular Physiology and Biochemistry, ISSN 1015-8987, 10/2017, Volume 42, Issue 6, pp. 2307 - 2317
Background/Aims: Transient receptor potential channel A1 (TRPA1) is engaged in amplified autonomic responses evoked by stimulation of muscle afferent nerves in...
Peripheral arterial disease | Hindlimb ischemia | Muscle afferent nerve | TRPA1 | COLD HYPERALGESIA | PHYSIOLOGY | ION-CHANNEL TRPA1 | EXERCISE PRESSOR REFLEX | ARTERIOSCLEROSIS OBLITERANS | GARLIC ACTIVATE | TRPV1 | CELL BIOLOGY | RESPONSES | PAIN | CONTRIBUTES | BRADYKININ | Acetanilides - pharmacology | Capsaicin - pharmacology | Purines - pharmacology | Rats | Male | Ganglia, Spinal - physiopathology | Rats, Sprague-Dawley | Arterial Occlusive Diseases - etiology | Patch-Clamp Techniques | Animals | Sensory Receptor Cells - drug effects | Arterial Occlusive Diseases - metabolism | Muscle, Skeletal - physiopathology | TRPA1 Cation Channel - agonists | Sensory Receptor Cells - metabolism | TRPA1 Cation Channel - antagonists & inhibitors | Ganglia, Spinal - drug effects | Femoral Artery - surgery | Action Potentials - drug effects | Isothiocyanates - pharmacology | TRPA1 Cation Channel - metabolism | Heart | Musculoskeletal system | Cats | Pain | Ischemia | Neurons | Rodents | Metabolism
Peripheral arterial disease | Hindlimb ischemia | Muscle afferent nerve | TRPA1 | COLD HYPERALGESIA | PHYSIOLOGY | ION-CHANNEL TRPA1 | EXERCISE PRESSOR REFLEX | ARTERIOSCLEROSIS OBLITERANS | GARLIC ACTIVATE | TRPV1 | CELL BIOLOGY | RESPONSES | PAIN | CONTRIBUTES | BRADYKININ | Acetanilides - pharmacology | Capsaicin - pharmacology | Purines - pharmacology | Rats | Male | Ganglia, Spinal - physiopathology | Rats, Sprague-Dawley | Arterial Occlusive Diseases - etiology | Patch-Clamp Techniques | Animals | Sensory Receptor Cells - drug effects | Arterial Occlusive Diseases - metabolism | Muscle, Skeletal - physiopathology | TRPA1 Cation Channel - agonists | Sensory Receptor Cells - metabolism | TRPA1 Cation Channel - antagonists & inhibitors | Ganglia, Spinal - drug effects | Femoral Artery - surgery | Action Potentials - drug effects | Isothiocyanates - pharmacology | TRPA1 Cation Channel - metabolism | Heart | Musculoskeletal system | Cats | Pain | Ischemia | Neurons | Rodents | Metabolism
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Loading RightsEuropean Journal of Medicinal Chemistry, ISSN 0223-5234, 05/2019, Volume 170, pp. 141 - 156
The transient receptor potential ankyrin 1 (TRPA1) channel is a non-selective cation channel, which detects noxious stimuli leading to pain, itch and cough....
Calcium signaling | Tranilast | TRP | TRPA1 | N-Cinnamoylanthranilic acid | Transient receptor potential ankyrin 1 | Binding site | Non-covalent | ACTIVATION | CHEMISTRY, MEDICINAL | SENSITIVITY | RECEPTOR | IDENTIFICATION | RESPONSES | MOLECULAR DETERMINANT | POTENTIAL ANKYRIN 1 | COLD | TRPM8 | Guinea Pigs | ortho-Aminobenzoates - chemistry | ortho-Aminobenzoates - pharmacology | Humans | ortho-Aminobenzoates - chemical synthesis | Male | Structure-Activity Relationship | Cinnamates - pharmacology | Animals | Calcium Signaling - drug effects | TRPA1 Cation Channel - agonists | HEK293 Cells | Cinnamates - chemical synthesis | Molecular Docking Simulation | Cinnamates - chemistry | TRPA1 Cation Channel - antagonists & inhibitors | TRPA1 Cation Channel - metabolism | Aldehydes
Calcium signaling | Tranilast | TRP | TRPA1 | N-Cinnamoylanthranilic acid | Transient receptor potential ankyrin 1 | Binding site | Non-covalent | ACTIVATION | CHEMISTRY, MEDICINAL | SENSITIVITY | RECEPTOR | IDENTIFICATION | RESPONSES | MOLECULAR DETERMINANT | POTENTIAL ANKYRIN 1 | COLD | TRPM8 | Guinea Pigs | ortho-Aminobenzoates - chemistry | ortho-Aminobenzoates - pharmacology | Humans | ortho-Aminobenzoates - chemical synthesis | Male | Structure-Activity Relationship | Cinnamates - pharmacology | Animals | Calcium Signaling - drug effects | TRPA1 Cation Channel - agonists | HEK293 Cells | Cinnamates - chemical synthesis | Molecular Docking Simulation | Cinnamates - chemistry | TRPA1 Cation Channel - antagonists & inhibitors | TRPA1 Cation Channel - metabolism | Aldehydes
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Loading RightsJournal of Medicinal Chemistry, ISSN 0022-2623, 04/2018, Volume 61, Issue 8, pp. 3641 - 3659
Transient receptor potential ankyrin 1 (TRPA1) is a non-selective cation channel expressed in sensory neurons where it functions as an irritant sensor for a...
ACTIVATE | CHEMISTRY, MEDICINAL | ION-CHANNEL TRPA1 | PAIN | NERVES | INFLAMMATION | COVALENT MODIFICATION | BIOLOGICAL EVALUATION | OPTIMIZATION | A1 TRPA1 ANTAGONISTS | SENSORY NEURONS | Humans | Microsomes, Liver - metabolism | Molecular Conformation | Proline - chemical synthesis | Prodrugs - chemistry | Structure-Activity Relationship | Madin Darby Canine Kidney Cells | Proline - pharmacology | TRPA1 Cation Channel - antagonists & inhibitors | Proline - analogs & derivatives | Sulfonamides - chemistry | Drug Stability | TRPA1 Cation Channel - chemistry | Solubility | Models, Molecular | Rats | Sulfonamides - pharmacology | Drug Discovery | Sulfonamides - pharmacokinetics | Proline - pharmacokinetics | Sulfonamides - chemical synthesis | Animals | Prodrugs - pharmacokinetics | Dogs | Prodrugs - chemical synthesis | Ligands | Prodrugs - pharmacology
ACTIVATE | CHEMISTRY, MEDICINAL | ION-CHANNEL TRPA1 | PAIN | NERVES | INFLAMMATION | COVALENT MODIFICATION | BIOLOGICAL EVALUATION | OPTIMIZATION | A1 TRPA1 ANTAGONISTS | SENSORY NEURONS | Humans | Microsomes, Liver - metabolism | Molecular Conformation | Proline - chemical synthesis | Prodrugs - chemistry | Structure-Activity Relationship | Madin Darby Canine Kidney Cells | Proline - pharmacology | TRPA1 Cation Channel - antagonists & inhibitors | Proline - analogs & derivatives | Sulfonamides - chemistry | Drug Stability | TRPA1 Cation Channel - chemistry | Solubility | Models, Molecular | Rats | Sulfonamides - pharmacology | Drug Discovery | Sulfonamides - pharmacokinetics | Proline - pharmacokinetics | Sulfonamides - chemical synthesis | Animals | Prodrugs - pharmacokinetics | Dogs | Prodrugs - chemical synthesis | Ligands | Prodrugs - pharmacology
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Loading RightsBiochemistry (Moscow), ISSN 0006-2979, 2/2019, Volume 84, Issue 2, pp. 101 - 118
TRPA1 is a cation channel located on the plasma membrane of many types of human and animal cells, including skin sensory neurons and epithelial cells of the...
Life Sciences | Biochemistry, general | Biomedicine, general | ligands | pain | Microbiology | TRPA1 | low-molecular-weight modulators | inflammation | peptides | transient receptor potential ankyrin channel | Bioorganic Chemistry | CRYSTAL-STRUCTURE | PHARMACOLOGICAL CHARACTERIZATION | BIOCHEMISTRY & MOLECULAR BIOLOGY | RECEPTOR | GARLIC ACTIVATE | TRPV1 | MECHANICAL HYPERSENSITIVITY | MUSTARD OIL | TRANSMEMBRANE DOMAINS | ANKYRIN 1 TRPA1 | NOCICEPTOR ION-CHANNEL | Analgesics - pharmacology | Neurogenic Inflammation - drug therapy | Humans | TRPA1 Cation Channel - chemistry | Anti-Inflammatory Agents, Non-Steroidal - chemistry | Pain - metabolism | Anti-Inflammatory Agents, Non-Steroidal - pharmacology | Animals | Analgesics - chemistry | Pain - drug therapy | Ligands | Neurogenic Inflammation - metabolism | Molecular Structure | TRPA1 Cation Channel - antagonists & inhibitors | TRPA1 Cation Channel - metabolism | Pain | Ligands (Biochemistry) | Physiological aspects | Development and progression | Ion channels | Inflammation | Biological control systems | Observations | Health aspects | Chemical sensors | Cinnamaldehyde | Epithelial cells | Bladder | Mucus | Smoke | Pruritus | Dermatitis | Acrolein | Sneezing | Urinary bladder | Intestine | Sensory neurons | Cinnamon | Organosulfur compounds | Irritation | Secretion | Hypersensitivity | Pharmacology | Chemical compounds | Cough | Hereditary diseases | Burning | Lungs | Incineration | Skin | Garlic | Mustard | Mechanical stimuli | Chemoreceptors | Cigarette smoke | Structure-function relationships
Life Sciences | Biochemistry, general | Biomedicine, general | ligands | pain | Microbiology | TRPA1 | low-molecular-weight modulators | inflammation | peptides | transient receptor potential ankyrin channel | Bioorganic Chemistry | CRYSTAL-STRUCTURE | PHARMACOLOGICAL CHARACTERIZATION | BIOCHEMISTRY & MOLECULAR BIOLOGY | RECEPTOR | GARLIC ACTIVATE | TRPV1 | MECHANICAL HYPERSENSITIVITY | MUSTARD OIL | TRANSMEMBRANE DOMAINS | ANKYRIN 1 TRPA1 | NOCICEPTOR ION-CHANNEL | Analgesics - pharmacology | Neurogenic Inflammation - drug therapy | Humans | TRPA1 Cation Channel - chemistry | Anti-Inflammatory Agents, Non-Steroidal - chemistry | Pain - metabolism | Anti-Inflammatory Agents, Non-Steroidal - pharmacology | Animals | Analgesics - chemistry | Pain - drug therapy | Ligands | Neurogenic Inflammation - metabolism | Molecular Structure | TRPA1 Cation Channel - antagonists & inhibitors | TRPA1 Cation Channel - metabolism | Pain | Ligands (Biochemistry) | Physiological aspects | Development and progression | Ion channels | Inflammation | Biological control systems | Observations | Health aspects | Chemical sensors | Cinnamaldehyde | Epithelial cells | Bladder | Mucus | Smoke | Pruritus | Dermatitis | Acrolein | Sneezing | Urinary bladder | Intestine | Sensory neurons | Cinnamon | Organosulfur compounds | Irritation | Secretion | Hypersensitivity | Pharmacology | Chemical compounds | Cough | Hereditary diseases | Burning | Lungs | Incineration | Skin | Garlic | Mustard | Mechanical stimuli | Chemoreceptors | Cigarette smoke | Structure-function relationships
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Loading RightsProceedings of the National Academy of Sciences of the United States of America, ISSN 0027-8424, 04/2017, Volume 114, Issue 14, pp. 3762 - 3767
General anesthetics suppress CNS activity by modulating the function of membrane ion channels, in particular, by enhancing activity of GABA(A) receptors. In...
Propofol | General anesthetic | TRPA1 | Isoflurane | A-967079 | propofol | MULTIDISCIPLINARY SCIENCES | MECHANISMS | general anesthetic | GABA(A) | PAIN | COVALENT MODIFICATION | ION-CHANNEL | TRANSMEMBRANE DOMAINS | RECEPTOR POTENTIAL A1 | isoflurane | MOLECULAR-BASIS | TRANSIENT | Isoflurane - pharmacology | Humans | TRPA1 Cation Channel - chemistry | Models, Molecular | Propofol - pharmacology | Drosophila Proteins - chemistry | Drosophila Proteins - metabolism | Molecular Dynamics Simulation | Animals | Hydrogen Bonding | Mutagenesis | Anesthetics, General - pharmacology | HEK293 Cells | Oximes - pharmacology | TRPA1 Cation Channel - genetics | Mice | Drosophila - metabolism | Drosophila Proteins - genetics | TRPA1 Cation Channel - metabolism | Drosophila - genetics | General anesthetics | Dosage and administration | Observations | Health aspects | Drug interactions | Binding sites (Biochemistry) | Biological Sciences
Propofol | General anesthetic | TRPA1 | Isoflurane | A-967079 | propofol | MULTIDISCIPLINARY SCIENCES | MECHANISMS | general anesthetic | GABA(A) | PAIN | COVALENT MODIFICATION | ION-CHANNEL | TRANSMEMBRANE DOMAINS | RECEPTOR POTENTIAL A1 | isoflurane | MOLECULAR-BASIS | TRANSIENT | Isoflurane - pharmacology | Humans | TRPA1 Cation Channel - chemistry | Models, Molecular | Propofol - pharmacology | Drosophila Proteins - chemistry | Drosophila Proteins - metabolism | Molecular Dynamics Simulation | Animals | Hydrogen Bonding | Mutagenesis | Anesthetics, General - pharmacology | HEK293 Cells | Oximes - pharmacology | TRPA1 Cation Channel - genetics | Mice | Drosophila - metabolism | Drosophila Proteins - genetics | TRPA1 Cation Channel - metabolism | Drosophila - genetics | General anesthetics | Dosage and administration | Observations | Health aspects | Drug interactions | Binding sites (Biochemistry) | Biological Sciences
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N-Acetyl-l-cysteine inhibits sulfur mustard-induced and TRPA1-dependent calcium influx
Archives of Toxicology, ISSN 0340-5761, 05/2017, Volume 91, Issue 5, pp. 2179 - 2189
Transient receptor potential family channels (TRPs) have been identified as relevant targets in many pharmacological as well as toxicological studies. TRP...
Calcium signaling | NAC | HEK293 | TRPA1 | GSH | Sulfur mustard | CELLS | OXIDATIVE STRESS | ACTIVATION | ANKTM1 | ANTIOXIDANTS | ION-CHANNEL | TOXICOLOGY | CHANNEL TRPA1 | EXPRESSION | OXIDANTS | Calcium - metabolism | Humans | Antioxidants - pharmacology | Mustard Gas - administration & dosage | Dose-Response Relationship, Drug | Mustard Gas - toxicity | Glutathione - pharmacology | Glutathione - analysis | Spectrometry, Mass, Electrospray Ionization - methods | Acetylcysteine - pharmacology | HEK293 Cells | Oximes - pharmacology | Chemical Warfare Agents - toxicity | TRPA1 Cation Channel - antagonists & inhibitors | Tandem Mass Spectrometry - methods | TRPA1 Cation Channel - metabolism | Toxicology | Calcium | Sulfur | Neurons | Index Medicus
Calcium signaling | NAC | HEK293 | TRPA1 | GSH | Sulfur mustard | CELLS | OXIDATIVE STRESS | ACTIVATION | ANKTM1 | ANTIOXIDANTS | ION-CHANNEL | TOXICOLOGY | CHANNEL TRPA1 | EXPRESSION | OXIDANTS | Calcium - metabolism | Humans | Antioxidants - pharmacology | Mustard Gas - administration & dosage | Dose-Response Relationship, Drug | Mustard Gas - toxicity | Glutathione - pharmacology | Glutathione - analysis | Spectrometry, Mass, Electrospray Ionization - methods | Acetylcysteine - pharmacology | HEK293 Cells | Oximes - pharmacology | Chemical Warfare Agents - toxicity | TRPA1 Cation Channel - antagonists & inhibitors | Tandem Mass Spectrometry - methods | TRPA1 Cation Channel - metabolism | Toxicology | Calcium | Sulfur | Neurons | Index Medicus
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Loading RightsNEUROSCIENCE, ISSN 0306-4522, 06/2017, Volume 353, pp. 76 - 86
The molecular sensor of innocuous (painless) cold sensation is well-established to be transient receptor potential cation channel, subfamily M, member 8...
K(v)1.2 | TRPA1 | cold pain | RECEPTOR | TRANSDUCTION | NEUROSCIENCES | SENSORY NEURONS | CONSTELLATION PHARMACOLOGY | TEMPERATURE | ion channel | pharmacology | MENTHOL | ION-CHANNEL | MOLECULAR DETERMINANT | TRPM8 | HYPERSENSITIVITY | Potassium Channels, Voltage-Gated - physiology | Humans | Isothiocyanates - administration & dosage | Nociception - physiology | Male | Thermosensing | Thermoreceptors - physiology | HEK293 Cells | Neurons - physiology | Female | Neurons - metabolism | Menthol - administration & dosage | Neurons - drug effects | Cold Temperature | TRPA1 Cation Channel - physiology | Mice, Inbred C57BL | Cells, Cultured | Ganglia, Spinal - physiology | Potassium Channels, Voltage-Gated - antagonists & inhibitors | TRPM Cation Channels - physiology | Mice, Knockout | Animals | TRPM Cation Channels - genetics | TRPA1 Cation Channel - genetics | TRPM Cation Channels - metabolism | Ganglia, Spinal - drug effects | TRPA1 Cation Channel - metabolism | Ganglia, Spinal - metabolism
K(v)1.2 | TRPA1 | cold pain | RECEPTOR | TRANSDUCTION | NEUROSCIENCES | SENSORY NEURONS | CONSTELLATION PHARMACOLOGY | TEMPERATURE | ion channel | pharmacology | MENTHOL | ION-CHANNEL | MOLECULAR DETERMINANT | TRPM8 | HYPERSENSITIVITY | Potassium Channels, Voltage-Gated - physiology | Humans | Isothiocyanates - administration & dosage | Nociception - physiology | Male | Thermosensing | Thermoreceptors - physiology | HEK293 Cells | Neurons - physiology | Female | Neurons - metabolism | Menthol - administration & dosage | Neurons - drug effects | Cold Temperature | TRPA1 Cation Channel - physiology | Mice, Inbred C57BL | Cells, Cultured | Ganglia, Spinal - physiology | Potassium Channels, Voltage-Gated - antagonists & inhibitors | TRPM Cation Channels - physiology | Mice, Knockout | Animals | TRPM Cation Channels - genetics | TRPA1 Cation Channel - genetics | TRPM Cation Channels - metabolism | Ganglia, Spinal - drug effects | TRPA1 Cation Channel - metabolism | Ganglia, Spinal - metabolism
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