Neurobiology of the Trace Amines Analytical, Physiological, Pharmacological, Behavioral, and Clinical Aspects
| Other Authors: | , , , |
|---|---|
| Format: | eBook |
| Language: | English |
| Published: |
Totowa, NJ
Humana
1984, 1984
|
| Edition: | 1st ed. 1984 |
| Series: | Polymer Science and Technology Series
|
| Subjects: | |
| Online Access: | |
| Collection: | Springer Book Archives -2004 - Collection details see MPG.ReNa |
Table of Contents:
- C. Physiology and Pharmacology
- Invited Communications
- Investigation of Trace Amine Metabolism in the Central Nervous System through Measurements on Cerebrospinal Fluid
- Analysis of Trace Amines: Endogenous Levels and the Effects of Various Drugs on Tissue Concentrations in the Rat
- Drug-Induced Changes in the Central Metabolism of Tyramine and Other Trace Monoamines: Their Possible Role in Brain Functions
- Aminergic Control of the Electrocorticogram: A Progress Report
- Neuronal Transport of Trace Amines: An Overview
- Electrophysiological Studies of the Possible Role of Trace Amines in Synaptic Function
- Effects of Octopamine and Serotonin on Neurones of Aplysia Californica
- Free Communications
- Individual Housing Stress Elevates Brain and Adrenal Tryptamine Content
- The Uptake and Release of14C-Tryptamine by Rat Brain Slices
- Tryptamine-Induced Changes in Endogenous 5-Hydroxytryptamine and [3H]-5-HT Release from Mouse Hypothalamic Slices
- Effect of Chronic Haloperidol on the Levels of Blood and Urinary Phenylethylamine and Phenylacetic Acid in Rats
- A Comparison of effects of Acute and Chronic Administration of Phenelzine and Tranylcypromine on Brain Concentrations of 2-Phenylethylamine, p-Tyramine, and Tryptamine in the Rat
- Phenylethylamine Deamination in the Noradrenergic Neurotransmitter System
- Effect of Lignocaine on Tyramine and Serotonin Oxidation in Brain
- Degradation Kinetics by MAO of PEA Derivatives. A Model for the Molecular Basis of Their Analgesic and Behavioral effects?
- The Kinetics of Hydroxylation of Phenylethylamine, Amphetamine, and Phenylalanine in Rodent Tissues
- Chronotropic and Inotropic Selectivity of Substituted Phenylethylamines in the Isolated, Perfused Rabbit Heart
- Trace Amine-Peptide Interactions on Central Neurones: I. Tryptamine and Substance P
- Trace Amine-Peptide Interactions: II. Phenylethylamine and enkephalin; p-Tyramine and enkephalin
- D. Behavior
- A. Introduction
- Trace Amines: The Early Years
- Trace Amines and the Neurosciences: An Overview
- B. Analysis
- Invited Communications
- Quantification of Trace Amines and Their Metabolites by High Resolution or Metastable Analysis Using Double Focussing Mass Spectrometry
- The Use of Enzymatic Radioisotopic Microassays for the Quantification of ?-Phenylethylamine, Phenylethanolamine, Tyramine, and Octopamine
- Gas Chromatography for Analysis of the Trace Amines in Tissues and Body Fluids
- Free Communications
- Studies on Tryptamine Metabolism by GC-MS and HPLC Techniques
- A Rapid and Specific Technique for the Extraction of Tyramine and Octopamine from Biological Tissues for HPLC Analysis
- Analysis of Octopamine, Dopamine, 5-Hydroxtryptamine, and Tryptophan in the Brain and Nerve Cord of the American Cockroach
- Natural Occurrence and Metabolism of the Isomeric Octopamines and Synephrines
- Octopamine is Present in Retinas of Various Mammalian Species
- The Origin, Drug Interaction, Urine, Plasma, and CSF Concentrations of Phenylacetic Acid in Normal and Psychiatric Subjects
- The Catabolism of Trace Amines in Some Psychiatric Disorders
- Tyramine and Depressive Illness
- Phenethylamine, Tyramine, and Other Trace Amines in Patients with Affective Disorders: Associations with Clinical State and Antidepressant Drug Treatment
- Phenylethylamine and Schizophrenia—Clinical and Pharmacological Results
- Urinary Excretion of Tryptamine in Comparison to Normetanephrine and beta-Phenylethylamine in Human Volunteers after Subchronic Treatment with Different Monoamine Oxidase Inhibitors
- Free Communications
- p-Hydroxyphenylacetic Acid Concentration in the CSF of Patients with Neurological and Psychiatric Disorders
- Noncatecholic Phenylethylamines and MAO Activity in Diabetes and Migraine
- Phenylethylamine and Tardive Dyskinesia
- Invited Communications
- Beta-Phenylethylamine: Some Preliminary Chronic Studies
- ?-Phenylethylamine: A Functional Role at the Behavioral Level?
- Differentiation of Phenylethylamine (PE)- and Amphetamine (AMPH)- Induced Behaviors
- Studies on the Mechanism of Action of ?-Phenylethylamine Stereotypy in Rodents: Implications for a ?-Phenylethylamine Animal Model of Schizophrenia
- Free Communications
- Effects of Tryptamine and 5-Hydroxytryptamine on Food Intake in the Rat
- 5-HT Involvement in Tryptamine-Induced Behavior in Mice
- Hypodipsic Effects of ?-Phenylethylamine, Phenylethanolamine, N-Methylphenylethylamine, and d-Amphetamine: A TemporalAnalysis
- Taste-Dependent Effects of Low Doses of ?-Phenylethylamine and d-Amphetamine on Drinking in the Rat
- ?-Phenylethylamine and d-Amphetamine: Differential Potency in the Conditioned Taste Aversion Paradigm
- Locomotor Stimulant Effect of ?-Phenylethylamine-Naloxone
- E. Clinical Studies
- Invited Communications
- Phenylethylamine, Phenylacetic Acid, and Methionine Enkephalin Levels in Humans Following Profound Acute Stress
- 14C-Tryptamine Binding in Parkinson’s Disease and Hepatic Coma
- Biochemical and Antidepressant Mechanisms of L-Deprenyl