Catalogue
Articles
RSS feedX
Search Filters
Format
Subjects
Language
Publication DateDrug Development Research, ISSN 0272-4391, 08/2013, Volume 74, Issue 5, pp. 332 - 338
Preclinical Research The aim of the present study was to evaluate the antinociceptive activity of the main metamizol (MET) metabolites, 4‐methylaminoantipyrine...
synthesis | metamizol | antinociception | PIFIR model | metabolites | CHEMISTRY, MEDICINAL | MECHANISM | DIPYRONE | MORPHINE | INHIBITION | ACETAMINOPHEN | PHARMACOKINETICS | PHARMACOLOGY & PHARMACY | INSIGHTS | PIFIR | Metabolites | Arthritis | Medical research
synthesis | metamizol | antinociception | PIFIR model | metabolites | CHEMISTRY, MEDICINAL | MECHANISM | DIPYRONE | MORPHINE | INHIBITION | ACETAMINOPHEN | PHARMACOKINETICS | PHARMACOLOGY & PHARMACY | INSIGHTS | PIFIR | Metabolites | Arthritis | Medical research
Journal Article
Details 
Digital rights
Loading RightsBrain Research, ISSN 0006-8993, 2010, Volume 1349, pp. 11 - 20
Abstract Rationale : The antinociceptive actions of diazepam and other benzodiazepines are partly due to their anxiolytic-like properties. Objective : This...
Neurology | Anterior basolateral amygdala | Anxiety–nociception relationship | Dorsal periaqueductal gray | Pain-induced functional impairment in the rat (PIFIR) | Diazepam | Rat defensive burying behaviour | Anxiety-nociception relationship | BENZODIAZEPINE RECEPTORS | CONCURRENT NOCICEPTIVE STIMULATION | PERSISTENT PAIN | in the rat (PIFIR) | Pain-induced functional impairment | BRAIN-STEM | MALE-MICE | ELEVATED PLUS-MAZE | NEUROSCIENCES | INDUCED ANALGESIA | INDUCED HYPERALGESIA | ANIMAL-MODELS | ANXIETY-INDUCED ANTINOCICEPTION | Amygdala - drug effects | Rats, Wistar | Area Under Curve | Periaqueductal Gray - drug effects | Anti-Anxiety Agents - pharmacology | Rats | Male | Anxiety - drug therapy | Pain - chemically induced | Diazepam - pharmacology | Animals | Pain - drug therapy | Reaction Time - drug effects | Statistics, Nonparametric | Behavior, Animal - drug effects | Uric Acid - adverse effects | Disease Models, Animal | Analysis | Uric acid | Amygdala
Neurology | Anterior basolateral amygdala | Anxiety–nociception relationship | Dorsal periaqueductal gray | Pain-induced functional impairment in the rat (PIFIR) | Diazepam | Rat defensive burying behaviour | Anxiety-nociception relationship | BENZODIAZEPINE RECEPTORS | CONCURRENT NOCICEPTIVE STIMULATION | PERSISTENT PAIN | in the rat (PIFIR) | Pain-induced functional impairment | BRAIN-STEM | MALE-MICE | ELEVATED PLUS-MAZE | NEUROSCIENCES | INDUCED ANALGESIA | INDUCED HYPERALGESIA | ANIMAL-MODELS | ANXIETY-INDUCED ANTINOCICEPTION | Amygdala - drug effects | Rats, Wistar | Area Under Curve | Periaqueductal Gray - drug effects | Anti-Anxiety Agents - pharmacology | Rats | Male | Anxiety - drug therapy | Pain - chemically induced | Diazepam - pharmacology | Animals | Pain - drug therapy | Reaction Time - drug effects | Statistics, Nonparametric | Behavior, Animal - drug effects | Uric Acid - adverse effects | Disease Models, Animal | Analysis | Uric acid | Amygdala
Journal Article
Details
Digital rights
Loading RightsJournal of Pharmacy and Pharmacology, ISSN 0022-3573, 06/2017, Volume 69, Issue 6, pp. 642 - 651
Objective To investigate the relationship between metamizol pharmacokinetics and the antinociceptive effect produced after subcutaneous administration of...
pharmacokinetics | metamizol | pharmacodynamics | tolerance | morphine | PAG-MICROINJECTED DIPYRONE | METABOLITES | TRAMADOL | ENDOGENOUS OPIOIDS | ADMINISTERED MORPHINE | ANTINOCICEPTION | ENHANCEMENT | PHARMACOLOGY & PHARMACY | TOLERANCE DEVELOPMENT | ANALGESIA | PIFIR | Analgesics - pharmacology | Dipyrone - pharmacology | Morphine - pharmacology | Rats, Wistar | Drug Tolerance | Analgesics, Opioid - pharmacology | Rats | Male | Dose-Response Relationship, Drug | Drug Synergism | Drug Therapy, Combination - methods | Pain Measurement - methods | Animals | Pain - drug therapy | Potentiation | Drugs | Pharmacodynamics | Pain perception | Morphine | Pharmacology | Drug development | Pain | Metabolites | Drug tolerance | Rodents | Dipyrone | Pharmacokinetics
pharmacokinetics | metamizol | pharmacodynamics | tolerance | morphine | PAG-MICROINJECTED DIPYRONE | METABOLITES | TRAMADOL | ENDOGENOUS OPIOIDS | ADMINISTERED MORPHINE | ANTINOCICEPTION | ENHANCEMENT | PHARMACOLOGY & PHARMACY | TOLERANCE DEVELOPMENT | ANALGESIA | PIFIR | Analgesics - pharmacology | Dipyrone - pharmacology | Morphine - pharmacology | Rats, Wistar | Drug Tolerance | Analgesics, Opioid - pharmacology | Rats | Male | Dose-Response Relationship, Drug | Drug Synergism | Drug Therapy, Combination - methods | Pain Measurement - methods | Animals | Pain - drug therapy | Potentiation | Drugs | Pharmacodynamics | Pain perception | Morphine | Pharmacology | Drug development | Pain | Metabolites | Drug tolerance | Rodents | Dipyrone | Pharmacokinetics
Journal Article
Details
Digital rights
Loading RightsPharmaceutics, ISSN 1999-4923, 03/2018, Volume 10, Issue 1, p. 20
The purpose of the present study was to determine whether caffeine modifies the pharmacokinetics and pharmacodynamics of (S)-ketoprofen following oral...
Pharmacodynamics | Pharmacokinetics | PIFIR model | (S)-ketoprofen | Caffeine | EFFICACY | pharmacodynamics | ENANTIOMERS | INDUCED FUNCTIONAL IMPAIRMENT | PARACETAMOL | MODEL | ANTINOCICEPTION | caffeine | PAIN | NONSTEROIDAL ANTIINFLAMMATORY DRUGS | PLASMA-LEVELS | pharmacokinetics | PHARMACOLOGY & PHARMACY | Pain | Kinetics | Rodents
Pharmacodynamics | Pharmacokinetics | PIFIR model | (S)-ketoprofen | Caffeine | EFFICACY | pharmacodynamics | ENANTIOMERS | INDUCED FUNCTIONAL IMPAIRMENT | PARACETAMOL | MODEL | ANTINOCICEPTION | caffeine | PAIN | NONSTEROIDAL ANTIINFLAMMATORY DRUGS | PLASMA-LEVELS | pharmacokinetics | PHARMACOLOGY & PHARMACY | Pain | Kinetics | Rodents
Journal Article
Details
Digital rights
Loading RightsPlanta Medica, ISSN 0032-0943, 04/2009, Volume 75, Issue 5, pp. 508 - 511
Abstract The rationale of this investigation was to examine the antinociceptive properties of the essential oil obtained from ROSMARINUS OFFICINALIS aerial...
Pharmacology | PIFIR assay | receptors | Rosmarinus officinalis L | Antinociception | Endogenous opioids | Lamiaceae | 5-HT | CHEMISTRY, MEDICINAL | RODENTS | antinociception | LEAVES | 1,8-CINEOLE | ANALGESIC ACTIVITY | CINNAMOMUM-OSMOPHLOEUM | PLANT SCIENCES | PAIN | endogenous opioids | INTEGRATIVE & COMPLEMENTARY MEDICINE | MENTHOL | PHARMACOLOGY & PHARMACY | 5-HT1A receptors | Gas chromatography | Usage | Nociceptors | Physiological aspects | Rosemary | Chemical properties | Research | Health aspects | Essences and essential oils | Identification and classification | Mass spectrometry | Index Medicus
Pharmacology | PIFIR assay | receptors | Rosmarinus officinalis L | Antinociception | Endogenous opioids | Lamiaceae | 5-HT | CHEMISTRY, MEDICINAL | RODENTS | antinociception | LEAVES | 1,8-CINEOLE | ANALGESIC ACTIVITY | CINNAMOMUM-OSMOPHLOEUM | PLANT SCIENCES | PAIN | endogenous opioids | INTEGRATIVE & COMPLEMENTARY MEDICINE | MENTHOL | PHARMACOLOGY & PHARMACY | 5-HT1A receptors | Gas chromatography | Usage | Nociceptors | Physiological aspects | Rosemary | Chemical properties | Research | Health aspects | Essences and essential oils | Identification and classification | Mass spectrometry | Index Medicus
Journal Article
Details
Digital rights
Loading RightsJournal of Ethnopharmacology, ISSN 0378-8741, 2007, Volume 111, Issue 3, pp. 476 - 482
The rationale of this investigation was to examine the antinociceptive effect of an ethanol extract of (RO) aerial parts, using three different experimental...
Antinociception | Traditional medicine | PIFIR model | Writhing | Formalin test | Rosmarinus officinalis | CHEMISTRY, MEDICINAL | antinociception | RAT | MORPHINE | traditional medicine | FLAVONOIDS | PROSTAGLANDIN HYPERALGESIA | PLANT SCIENCES | writhing | PAIN | ROSEMARY | INTEGRATIVE & COMPLEMENTARY MEDICINE | PHARMACOLOGY & PHARMACY | MICE | RECEPTORS | formalin test | EXTRACT | Analgesics - pharmacology | Rats, Wistar | Plant Extracts - pharmacology | Tramadol - pharmacology | Male | Pain - chemically induced | Aspirin - administration & dosage | Dose-Response Relationship, Drug | Plant Extracts - administration & dosage | Arthritis - chemically induced | Inflammation - drug therapy | Pain - drug therapy | Anti-Inflammatory Agents - administration & dosage | Aspirin - pharmacology | Disease Models, Animal | Plant Components, Aerial | Anti-Inflammatory Agents - pharmacology | Analgesics - administration & dosage | Rats | Animals | Rosmarinus | Tramadol - administration & dosage | Arthritis - drug therapy | Mice | Pain Measurement | Plants, Medicinal | Acetic acid | Analysis | Models
Antinociception | Traditional medicine | PIFIR model | Writhing | Formalin test | Rosmarinus officinalis | CHEMISTRY, MEDICINAL | antinociception | RAT | MORPHINE | traditional medicine | FLAVONOIDS | PROSTAGLANDIN HYPERALGESIA | PLANT SCIENCES | writhing | PAIN | ROSEMARY | INTEGRATIVE & COMPLEMENTARY MEDICINE | PHARMACOLOGY & PHARMACY | MICE | RECEPTORS | formalin test | EXTRACT | Analgesics - pharmacology | Rats, Wistar | Plant Extracts - pharmacology | Tramadol - pharmacology | Male | Pain - chemically induced | Aspirin - administration & dosage | Dose-Response Relationship, Drug | Plant Extracts - administration & dosage | Arthritis - chemically induced | Inflammation - drug therapy | Pain - drug therapy | Anti-Inflammatory Agents - administration & dosage | Aspirin - pharmacology | Disease Models, Animal | Plant Components, Aerial | Anti-Inflammatory Agents - pharmacology | Analgesics - administration & dosage | Rats | Animals | Rosmarinus | Tramadol - administration & dosage | Arthritis - drug therapy | Mice | Pain Measurement | Plants, Medicinal | Acetic acid | Analysis | Models
Journal Article
Details
Digital rights
Loading RightsJournal of Ethnopharmacology, ISSN 0378-8741, 08/2012, Volume 142, Issue 3, pp. 700 - 705
is a plant that has long been used in large demand in Mexican folk medicine to treat pain, among others affections. Nevertheless, no scientific data confirming...
Agastache mexicana (H. B. K.) Lint & Epling subsp. xolocotziana | Antinociception | Lamiaceae | Writhing test | PIFIR model | Formalin test | CHEMISTRY, MEDICINAL | RAT | MOUSE | Agastache mexicana (H. B. K.) Lint & Epling subsp xolocotziana | PAW FORMALIN TEST | PLANT SCIENCES | URSOLIC ACID | INHIBITION | INTEGRATIVE & COMPLEMENTARY MEDICINE | GLUTAMATE | TILIANIN | PHARMACOLOGY & PHARMACY | MICE | NOCICEPTION | ABDOMINAL CONSTRICTION | Analgesics - therapeutic use | Rats, Wistar | Solvents - chemistry | Stomach Ulcer - drug therapy | Rats | Acetates - chemistry | Male | Animals | Pain - drug therapy | Agastache | Anti-Inflammatory Agents - therapeutic use | Inflorescence - chemistry | Hexanes - chemistry | Mice | Phytotherapy | Methanol - chemistry | Plant Extracts - therapeutic use | Disease Models, Animal | Care and treatment | Pain | Anti-inflammatory drugs | Rodents | Analysis | Formaldehyde
Agastache mexicana (H. B. K.) Lint & Epling subsp. xolocotziana | Antinociception | Lamiaceae | Writhing test | PIFIR model | Formalin test | CHEMISTRY, MEDICINAL | RAT | MOUSE | Agastache mexicana (H. B. K.) Lint & Epling subsp xolocotziana | PAW FORMALIN TEST | PLANT SCIENCES | URSOLIC ACID | INHIBITION | INTEGRATIVE & COMPLEMENTARY MEDICINE | GLUTAMATE | TILIANIN | PHARMACOLOGY & PHARMACY | MICE | NOCICEPTION | ABDOMINAL CONSTRICTION | Analgesics - therapeutic use | Rats, Wistar | Solvents - chemistry | Stomach Ulcer - drug therapy | Rats | Acetates - chemistry | Male | Animals | Pain - drug therapy | Agastache | Anti-Inflammatory Agents - therapeutic use | Inflorescence - chemistry | Hexanes - chemistry | Mice | Phytotherapy | Methanol - chemistry | Plant Extracts - therapeutic use | Disease Models, Animal | Care and treatment | Pain | Anti-inflammatory drugs | Rodents | Analysis | Formaldehyde
Journal Article
Details
Digital rights
Loading RightsEUROPEAN JOURNAL OF PHARMACOLOGY, ISSN 0014-2999, 08/2006, Volume 544, Issue 1-3, pp. 31 - 38
It has been observed that caffeine improves antinociceptive efficacy of some non-steroidal antiinflammatory drugs (NSAIDs) in several experimental models,...
ACID | antinociception | MORPHINE | analgesia | INDUCED FUNCTIONAL IMPAIRMENT | ibuprofen | MODEL | ASPIRIN | caffeine | PAIN | PHARMACOKINETICS | ACETAMINOPHEN | potentiation | DRUGS | PHARMACOLOGY & PHARMACY | ANALGESIC ADJUVANT | PIFIR model
ACID | antinociception | MORPHINE | analgesia | INDUCED FUNCTIONAL IMPAIRMENT | ibuprofen | MODEL | ASPIRIN | caffeine | PAIN | PHARMACOKINETICS | ACETAMINOPHEN | potentiation | DRUGS | PHARMACOLOGY & PHARMACY | ANALGESIC ADJUVANT | PIFIR model
Journal Article
Details
Digital rights
Loading RightsPharmacology, Biochemistry and Behavior, ISSN 0091-3057, 2008, Volume 91, Issue 1, pp. 128 - 133
The mechanism of action underlying the “analgesic activity” of diazepam remains unclear. In this study, the possible participation of the GABA/benzodiazepine...
Flumazenil | L-NAME | Nitric oxide | Cyclic GMP | 7-nitroindazole | Antinociception | PIFIR model | L-arginine | Diazepam | Methylene blue
Flumazenil | L-NAME | Nitric oxide | Cyclic GMP | 7-nitroindazole | Antinociception | PIFIR model | L-arginine | Diazepam | Methylene blue
Journal Article
Details
Digital rights
Loading RightsEuropean Journal of Pharmacology, ISSN 0014-2999, 2006, Volume 544, Issue 1, pp. 31 - 38
It has been observed that caffeine improves antinociceptive efficacy of some non-steroidal antiinflammatory drugs (NSAIDs) in several experimental models,...
Potentiation | Analgesia | Antinociception | PIFIR model | Ibuprofen | Caffeine | Analgesics - pharmacology | Caffeine - administration & dosage | Rats, Wistar | Rats | Ibuprofen - administration & dosage | Male | Dose-Response Relationship, Drug | Animals | Time Factors | Anti-Inflammatory Agents, Non-Steroidal - administration & dosage | Arthritis - drug therapy | Drug Therapy, Combination | Central Nervous System Stimulants - administration & dosage | Disease Models, Animal | Morphine | Arthritis | Uric acid | Nonsteroidal anti-inflammatory drugs
Potentiation | Analgesia | Antinociception | PIFIR model | Ibuprofen | Caffeine | Analgesics - pharmacology | Caffeine - administration & dosage | Rats, Wistar | Rats | Ibuprofen - administration & dosage | Male | Dose-Response Relationship, Drug | Animals | Time Factors | Anti-Inflammatory Agents, Non-Steroidal - administration & dosage | Arthritis - drug therapy | Drug Therapy, Combination | Central Nervous System Stimulants - administration & dosage | Disease Models, Animal | Morphine | Arthritis | Uric acid | Nonsteroidal anti-inflammatory drugs
Journal Article
Details
Digital rights
Loading RightsArchives of Medical Research, ISSN 0188-4409, 2013, Volume 44, Issue 7, pp. 495 - 503
Background and Aims The use of a combination of analgesics could provide an optimal pain treatment with minimal side effects. Combinations of tramadol and some...
Internal Medicine | Antinociception | Metamizole | PIFIR model | Synergism | Constipation | Tramadol | MEDICINE, RESEARCH & EXPERIMENTAL | PAG-MICROINJECTED DIPYRONE | ENDOGENOUS OPIOIDS | PERIAQUEDUCTAL GRAY | MORPHINE | INVOLVEMENT | MODEL | ANALGESIC INTERACTION | SYNERGISTIC INTERACTION | PAIN | SURFACE | Arthritis, Experimental - drug therapy | Rats, Wistar | Dipyrone - administration & dosage | Analgesics - administration & dosage | Rats | Male | Tramadol - adverse effects | Constipation - chemically induced | Dipyrone - adverse effects | Dose-Response Relationship, Drug | Drug Synergism | Animals | Anti-Inflammatory Agents, Non-Steroidal - adverse effects | Pain - drug therapy | Tramadol - administration & dosage | Anti-Inflammatory Agents, Non-Steroidal - administration & dosage | Nociception - drug effects | Drug Therapy, Combination | Analgesics - adverse effects | Arthritis
Internal Medicine | Antinociception | Metamizole | PIFIR model | Synergism | Constipation | Tramadol | MEDICINE, RESEARCH & EXPERIMENTAL | PAG-MICROINJECTED DIPYRONE | ENDOGENOUS OPIOIDS | PERIAQUEDUCTAL GRAY | MORPHINE | INVOLVEMENT | MODEL | ANALGESIC INTERACTION | SYNERGISTIC INTERACTION | PAIN | SURFACE | Arthritis, Experimental - drug therapy | Rats, Wistar | Dipyrone - administration & dosage | Analgesics - administration & dosage | Rats | Male | Tramadol - adverse effects | Constipation - chemically induced | Dipyrone - adverse effects | Dose-Response Relationship, Drug | Drug Synergism | Animals | Anti-Inflammatory Agents, Non-Steroidal - adverse effects | Pain - drug therapy | Tramadol - administration & dosage | Anti-Inflammatory Agents, Non-Steroidal - administration & dosage | Nociception - drug effects | Drug Therapy, Combination | Analgesics - adverse effects | Arthritis
Journal Article
Details
Digital rights
Loading RightsPharmacology, Biochemistry and Behavior, ISSN 0091-3057, 2008, Volume 91, Issue 1, pp. 196 - 201
The purpose of this work was to evaluate the antinociceptive efficacy of an optimal morphine and metamizol combination on different levels of nociception...
Nociception | Metamizol | Morphine | Pain | PIFIR model | Synergism | DIRECT ANTAGONISM | pain | TRAMADOL | ENDOGENOUS OPIOIDS | DIPYRONE | DICLOFENAC | INDUCED FUNCTIONAL IMPAIRMENT | ARTHRITIC NOCICEPTION | NEUROSCIENCES | morphine | metamizol | ACETAMINOPHEN | PHARMACOLOGY | synergism | BEHAVIORAL SCIENCES | PHARMACOLOGY & PHARMACY | ANALGESIC INTERACTIONS | Inflammation - chemically induced | Rats, Wistar | Rats | Analgesics, Opioid - therapeutic use | Male | Pain Measurement - drug effects | Pain - chemically induced | Dipyrone - therapeutic use | Dose-Response Relationship, Drug | Drug Synergism | Inflammation - complications | Animals | Anti-Inflammatory Agents, Non-Steroidal - therapeutic use | Pain - drug therapy | Pain - etiology | Uric Acid | Aspirin - therapeutic use | Drug Therapy, Combination | Morphine - therapeutic use | Aspirin | Models | Salicylates | Polybrominated biphenyls | Index Medicus
Nociception | Metamizol | Morphine | Pain | PIFIR model | Synergism | DIRECT ANTAGONISM | pain | TRAMADOL | ENDOGENOUS OPIOIDS | DIPYRONE | DICLOFENAC | INDUCED FUNCTIONAL IMPAIRMENT | ARTHRITIC NOCICEPTION | NEUROSCIENCES | morphine | metamizol | ACETAMINOPHEN | PHARMACOLOGY | synergism | BEHAVIORAL SCIENCES | PHARMACOLOGY & PHARMACY | ANALGESIC INTERACTIONS | Inflammation - chemically induced | Rats, Wistar | Rats | Analgesics, Opioid - therapeutic use | Male | Pain Measurement - drug effects | Pain - chemically induced | Dipyrone - therapeutic use | Dose-Response Relationship, Drug | Drug Synergism | Inflammation - complications | Animals | Anti-Inflammatory Agents, Non-Steroidal - therapeutic use | Pain - drug therapy | Pain - etiology | Uric Acid | Aspirin - therapeutic use | Drug Therapy, Combination | Morphine - therapeutic use | Aspirin | Models | Salicylates | Polybrominated biphenyls | Index Medicus
Journal Article
Details
Digital rights
Loading RightsPharmacology Biochemistry and Behavior, ISSN 0091-3057, 11/2008, Volume 91, Issue 1, pp. 128 - 133
The mechanism of action underlying the "analgesic activity" of diazepam remains unclear. In this study, the possible participation of the GABA/benzodiazepine...
Flumazenil | L-NAME | Cyclic GMP | Nitric oxide | 7-nitroindazole | Antinociception | PIFIR model | L-arginine | Diazepam | Methylene blue | nitric oxide | BENZODIAZEPINE RECEPTORS | antinociception | diazepam | NITRIC-OXIDE SYNTHASE | cyclic GMP | MALE-MICE | ELEVATED PLUS-MAZE | NEUROSCIENCES | GUANYLATE-CYCLASE | INDUCED PAW EDEMA | methylene blue | BRAIN GABA(A) RECEPTORS | INDUCED ANALGESIA | IN-VIVO | BEHAVIORAL SCIENCES | PHARMACOLOGY & PHARMACY | RAT-BRAIN | flumazenil | NG-Nitroarginine Methyl Ester - pharmacology | Nitric Oxide - biosynthesis | Cyclic GMP - physiology | Rats, Wistar | Enzyme Inhibitors - pharmacology | Rats | Male | Nitric Oxide - physiology | Pain Measurement - drug effects | Guanylate Cyclase - antagonists & inhibitors | Diazepam - pharmacology | Indazoles - pharmacology | Animals | Analgesics | Signal Transduction - drug effects | Arginine - pharmacology | Receptors, GABA-A - drug effects | Hypnotics and Sedatives - pharmacology | Nitric Oxide Donors - pharmacology | Nitric Oxide Synthase Type I - drug effects | Cyclic GMP - biosynthesis | Analysis | Guanosine | Polybrominated biphenyls | GABA | Uric acid | Guanylate cyclase | Dyes and dyeing
Flumazenil | L-NAME | Cyclic GMP | Nitric oxide | 7-nitroindazole | Antinociception | PIFIR model | L-arginine | Diazepam | Methylene blue | nitric oxide | BENZODIAZEPINE RECEPTORS | antinociception | diazepam | NITRIC-OXIDE SYNTHASE | cyclic GMP | MALE-MICE | ELEVATED PLUS-MAZE | NEUROSCIENCES | GUANYLATE-CYCLASE | INDUCED PAW EDEMA | methylene blue | BRAIN GABA(A) RECEPTORS | INDUCED ANALGESIA | IN-VIVO | BEHAVIORAL SCIENCES | PHARMACOLOGY & PHARMACY | RAT-BRAIN | flumazenil | NG-Nitroarginine Methyl Ester - pharmacology | Nitric Oxide - biosynthesis | Cyclic GMP - physiology | Rats, Wistar | Enzyme Inhibitors - pharmacology | Rats | Male | Nitric Oxide - physiology | Pain Measurement - drug effects | Guanylate Cyclase - antagonists & inhibitors | Diazepam - pharmacology | Indazoles - pharmacology | Animals | Analgesics | Signal Transduction - drug effects | Arginine - pharmacology | Receptors, GABA-A - drug effects | Hypnotics and Sedatives - pharmacology | Nitric Oxide Donors - pharmacology | Nitric Oxide Synthase Type I - drug effects | Cyclic GMP - biosynthesis | Analysis | Guanosine | Polybrominated biphenyls | GABA | Uric acid | Guanylate cyclase | Dyes and dyeing
Journal Article
Details
Digital rights
Loading RightsEuropean Journal of Pharmacology, ISSN 0014-2999, 2004, Volume 503, Issue 1, pp. 43 - 48
The role of nitric oxide (NO) in the antinociceptive effect of indomethacin was assessed in the pain-induced functional impairment model in the rat (PIFIR...
Antinociception | Indomethacin | Rat | PIFIR model | Nitric oxide | nitric oxide | ACTIVATION | antinociception | rat | MECHANISM | NOCICEPTOR SENSITIZATION | indomethacin | PAIN | ROFECOXIB | PHARMACOLOGY & PHARMACY | CYCLIC GMP PATHWAY | HYPERALGESIA | KETOROLAC | PARTICIPATION | ANALGESIA | Cyclic GMP - physiology | Gout - psychology | Rats, Wistar | Nitric Oxide Synthase - antagonists & inhibitors | Nitroprusside - pharmacology | Pain - chemically induced | Anti-Inflammatory Agents, Non-Steroidal - pharmacology | Nitric Oxide Synthase Type I | Pain - drug therapy | Female | Nitric Oxide Donors - pharmacology | Disease Models, Animal | NG-Nitroarginine Methyl Ester - pharmacology | Nerve Tissue Proteins - antagonists & inhibitors | Enzyme Inhibitors - pharmacology | Rats | Nitric Oxide - physiology | Pain Measurement - drug effects | Gout - chemically induced | Indomethacin - pharmacology | Animals | Gout - complications | Uric Acid | Signal Transduction - physiology | Chronic Disease | Arginine - metabolism | Peripheral Nervous System - drug effects
Antinociception | Indomethacin | Rat | PIFIR model | Nitric oxide | nitric oxide | ACTIVATION | antinociception | rat | MECHANISM | NOCICEPTOR SENSITIZATION | indomethacin | PAIN | ROFECOXIB | PHARMACOLOGY & PHARMACY | CYCLIC GMP PATHWAY | HYPERALGESIA | KETOROLAC | PARTICIPATION | ANALGESIA | Cyclic GMP - physiology | Gout - psychology | Rats, Wistar | Nitric Oxide Synthase - antagonists & inhibitors | Nitroprusside - pharmacology | Pain - chemically induced | Anti-Inflammatory Agents, Non-Steroidal - pharmacology | Nitric Oxide Synthase Type I | Pain - drug therapy | Female | Nitric Oxide Donors - pharmacology | Disease Models, Animal | NG-Nitroarginine Methyl Ester - pharmacology | Nerve Tissue Proteins - antagonists & inhibitors | Enzyme Inhibitors - pharmacology | Rats | Nitric Oxide - physiology | Pain Measurement - drug effects | Gout - chemically induced | Indomethacin - pharmacology | Animals | Gout - complications | Uric Acid | Signal Transduction - physiology | Chronic Disease | Arginine - metabolism | Peripheral Nervous System - drug effects
Journal Article
Details
Digital rights
Loading RightsPsychopharmacology, ISSN 0033-3158, 7/2005, Volume 180, Issue 3, pp. 399 - 407
The effect of anxiety on nociception has been evaluated but not that of nociception on anxiety.The study was conducted to analyse the influence of nociception...
Medicine | Rat burying behaviour | Elevated plus maze | Buspirone | Acetylsalicylic acid | PIFIR model | Diazepam | diazepam | ANXIETY | PSYCHIATRY | GUIDELINES | buspirone | MALE-MICE | elevated plus maze | ANTINOCICEPTION | rat burying behaviour | ELEVATED PLUS-MAZE | NEUROSCIENCES | acetylsalicylic acid | BURYING BEHAVIOR | FATTY-ACID LEVELS | PAIN | PHARMACOLOGY & PHARMACY | AGENTS | STRESS | Anti-Anxiety Agents - administration & dosage | Inflammation - chemically induced | Rats, Wistar | Diazepam - administration & dosage | Anxiety - physiopathology | Motor Activity - drug effects | Rats | Male | Anxiety - drug therapy | Pain - chemically induced | Maze Learning - drug effects | Dose-Response Relationship, Drug | Buspirone - administration & dosage | Animals | Analysis of Variance | Pain - physiopathology | Injections, Intra-Articular | Uric Acid | Behavior, Animal - drug effects | Anti-Anxiety Agents - therapeutic use | Aspirin - pharmacology | Diazepam - therapeutic use | Buspirone - therapeutic use | Inflammation - physiopathology
Medicine | Rat burying behaviour | Elevated plus maze | Buspirone | Acetylsalicylic acid | PIFIR model | Diazepam | diazepam | ANXIETY | PSYCHIATRY | GUIDELINES | buspirone | MALE-MICE | elevated plus maze | ANTINOCICEPTION | rat burying behaviour | ELEVATED PLUS-MAZE | NEUROSCIENCES | acetylsalicylic acid | BURYING BEHAVIOR | FATTY-ACID LEVELS | PAIN | PHARMACOLOGY & PHARMACY | AGENTS | STRESS | Anti-Anxiety Agents - administration & dosage | Inflammation - chemically induced | Rats, Wistar | Diazepam - administration & dosage | Anxiety - physiopathology | Motor Activity - drug effects | Rats | Male | Anxiety - drug therapy | Pain - chemically induced | Maze Learning - drug effects | Dose-Response Relationship, Drug | Buspirone - administration & dosage | Animals | Analysis of Variance | Pain - physiopathology | Injections, Intra-Articular | Uric Acid | Behavior, Animal - drug effects | Anti-Anxiety Agents - therapeutic use | Aspirin - pharmacology | Diazepam - therapeutic use | Buspirone - therapeutic use | Inflammation - physiopathology
Journal Article
Details
Digital rights
Loading RightsLatin American Journal of Pharmacy, ISSN 0326-2383, 2017, Volume 36, Issue 7, pp. 1349 - 1354
To find a possible synergistic antinociceptive interaction, several doses of (S)-ketoprofen and caffeine were administered in an arthritic-pain model. To...
Antinociception | PIFIR model | (S)-ketoprofen | NSAIDs | Caffeine | SURGERY | antinociception | RAT | KETOPROFEN | INDUCED FUNCTIONAL IMPAIRMENT | PARACETAMOL | ASPIRIN | DEXKETOPROFEN | caffeine | PHARMACOLOGY & PHARMACY | ANALGESIA
Antinociception | PIFIR model | (S)-ketoprofen | NSAIDs | Caffeine | SURGERY | antinociception | RAT | KETOPROFEN | INDUCED FUNCTIONAL IMPAIRMENT | PARACETAMOL | ASPIRIN | DEXKETOPROFEN | caffeine | PHARMACOLOGY & PHARMACY | ANALGESIA
Journal Article
Details