Summary
Synopsis
Piracetam is the first of the socalled ‘nootropic’ drugs, a unique class of drugs which affect mental function. In animal models and in healthy volunteers, the drug improves the efficiency of the higher telencephalic functions of the brain involved in cognitive processes such as learning and memory.
The pharmacology of piracetam is unusual because it protects against various physical and chemical insults applied to the brain. It facilitates learning and memory in healthy animals and in animals whose brain function has been compromised, and it enhances interhemispheric transfer of information via callosal transmission. At the same time, even in relatively high dosages it is devoid of any sedative, analeptic or autonomic activities. How piracetam exerts its effects on memory disorders is still under investigation, although among other proposed mechanisms of action it is thought to facilitate central nervous system efficiency of cholinergic neurotransmission.
Results from trials involving elderly patients with senile cognitive disorders have been equivocal, as have the results obtained when piracetam has been combined with acetylcholine precursors. Piracetam seems to be almost completely devoid of adverse effects, and is extremely well tolerated.
In conclusion, opinion is divided as to the benefits of piracetam in the treatment of senile cognitive decline. Although double-blind studies in the elderly have produced mixed results, some such trials (particularly those involving larger numbers of patients) have reported favourable findings, thus offering some reason for cautious optimism in a notoriously difficult area of therapeutics. However, further investigations of piracetam alone and in combination therapy are required before any absolute conclusions can be drawn.
Pharmacological Properties
Piracetam is a cyclic derivative of γ-aminobutyric acid (GABA), and the first representative of what are commonly known as the ‘nootropic’ drugs. It has a protective effect on brain functions against externally applied brain ‘aggressions’, which include hypoxia, electroconvulsive treatment and barbiturate intoxication in experimental animals. It has been reported to facilitate learning and memory in several animal models as well as in aged animals. In electrophysiological and behavioural models, the drug facilitates cerebral inter- and intrahemispheric connectivity, indicating that it may enhance information transfer in the brain. Piracetam enhances microcirculation by reducing platelet activity, enhancing red blood cell deformability and reducing adherence of damaged erythrocytes to endothelial cells. In healthy volunteers, the drug enhances recall of learned information, increases verbal capacity and improves mental functioning under certain conditions. Piracetam stimulates glucose degradation in rat cortex slices, enhances 32P incorporation into brain phospholipids and stimulates adenylate cyclase. Although structurally related to GABA, it does not appear to have any similar GABA-like effects in animals. Its mechanism of action appears to be via stimulation of central cholinergic activity, although a number of other neurotransmitters may also be involved.
Pharmacokinetic Studies
Piracetam is completely absorbed after oral administration: peak plasma concentrations are reached after 30 to 40 minutes, and oral bioavailability is close to 100%. The elimination half-life of the drug in healthy volunteers is about 5 to 6 hours, but this may be increased in elderly patients, particularly those with multiple disease states. Piracetam is excreted unchanged in the urine, urinary excretion accounting for more than 98% of the administered dose. Distribution studies have shown that the drug is rapidly distributed in most essential organs. It crosses the blood-brain barrier, and is preferentially concentrated in the grey matter of the cerebrum and cerebellum, caudate nucleus, hippocampus, lateral geniculate body and chorioid plexus. Half-life in cerebrospinal fluid is greater than plasma half-life, indicating a tropism for brain tissue.
Therapeutic Trials
Double-blind controlled studies have produced mixed results with piracetam in the treatment of learning and memory disorders of the elderly. Comparison between different trials is difficult because of lack of standardisation of patient groups or assessment protocols. Although some improvements in memory and learning as a result of piracetam administration have been noted, these have been small and inconsistent. Because memory impairment in senile dementia is highly correlated with brain cholinergic function, trials have been carried out using piracetam and the acetylcholine precursors lecithin and choline. Although experiments in rats have shown that piracetam plus choline has a superior effect to either agent administered alone, results in human trials have been equivocal.
Adverse Effects
Piracetam is extremely well tolerated and generally free from adverse effects. Side effects which have been reported occasionally include mild dizziness, insomnia and nausea, but none of these have necessitated stopping therapy.
Dosage and Administration
Piracetam can be administered orally or intravenously in dosages ranging from 20 to 150 mg/ kg daily in divided doses. For long term treatment of senility, it is recommended that 2.4 to 4.8g orally be given daily, depending on the severity of the symptoms. In patients with impaired renal function, dosage regimens should be adjusted according to the manufacturer’s recommendations.
This is a preview of subscription content, access via your institution.
References
Aantaa E, Meurman OH. The effect of piracetam (nootropil, UCB-6215) upon the late symptoms of patients with head injuries. Journal of International Medical Research 3: 352–355, 1975
Abuzzahab Sr FS, Merwin GE, Zimmermann RL, Sherman MC. A double-blind investigation of piracetam (nootropil) versus placebo in the memory of geriatric inpatients. Psychopharmacology Bulletin 14: 23–26, 1978
Armstrong A. Recent trends in research on Alzheimer’s disease. Scrip, 1986
Bartus RT, Dean 3rd RL, Beer B, Lippa A. The cholinergic hypothesis of geriatric memory dysfunction. Science 217: 408–417, 1982
Bartus RT, Dean RL, Sherman KA, Friedman E, Beer B. Profound effects of combining choline and piracetam on memory enhancement and cholinergic function in aged rats. Neurobiology of Aging 2(2): 105–111, 1981
Bente D, Glatthaar G, Ulrich G, Lewinsky M. Piracetam und Vigilanz. Elektroenzephalographische und klinische Ergebnisse einer Langzeitmedikation bei gerontopsychiatrischen Patienten. Arzneimittel-Forschung 28: 1529–1530, 1978
Berga P, Beckett PR, Roberts DJ, Llenas J, Massingham R. Synergistic interactions between piracetam and dihydroergocristine in some animal models of cerebral hypoxia and ischaemia. Arzneimittel-Forschung 36(2): 1314, 1986
Bering B, Müller WE. Interaction of piracetam with several neurotransmitter receptors in the central nervous system. Relative specificity for 3H-glutamate sites. Arzneimittel-Forschung 35(2): 1350–1352, 1985
Bick RL, Fareed J, Skondia V. Piracetam: a new platelet suppressing drug. Abstract. Thrombosis and Haemostasis 46: 67, 1981
Bryant RC, Petty F, Byrne WL. Effects of piracetam (SKF 38462) on acquisition, retention and activity in the goldfish. Pharmacologia 29(2): 121–130, 1973
Burešová O, Bureš J. Mechanisms of interhemispheric transfer of visual information in rats. Acta Neurobiologiae Experimentalis 33: 673–688, 1973
Burešová O, Bureš J. Piracetam-induced facilitation of interhemispheric transfer of visual information in rats. Psychopharmacologia 46: 93–102, 1976
Cavazzuti L, Bertoldin T, Volpe D, Crepaldi G. Influence of treatment with piracetam on psychocognitive decline in elderly hospitalized patients. In Symposium on Piracetam: 5 years’ progress in pharmacology and clinics, pp. 67–74, Technicas Graficas Forma, Madrid, 1990
Chouinard G, Annable L, Ross-Chouinard A, Olivier M, Fontaine F. Piracetam in elderly pyschiatric patients with mild diffuse cerebral impairment. Psychopharmacology 81: 100–106, 1983
Comely M, Henkel E, Künzel W, Zimmermann P. Pharmacokinetic of piracetam during labour influence to acid-base-status in material and fetal blood. Zeitschrift für Geburtshilfe und Perinatologie 181: 199–205, 1977
Demay F, Bande J. The effect of piracetam on volunteers in a low-pressure tank. Journal of International Medical Research 8: 90–94, 1980
Dimond SJ. Use of a nootropic substance to increase the capacity for verbal learning and memory in normal man. 3rd Congress of the International College of Psychosomatic Medicine, 1975
Dimov S, Moyanova S, Nikolov R, Nikolova M. Piracetam and brain excitability: an electrophysiological study in cats. Methods and Findings in Experimental and Clinical Pharmacology 6(2): 83–89, 1984
Dimov S, Nikolov R, Nikolov M, Moyanova S. Effect of piracetam in some models of general and local depression of the cortical bioelectrical activity in cats. Archives Internationales de Pharmacodynamie et de Thérapie 262: 13–23, 1983
Domańska-Janik K, Zaleska M. The action of piracetam on 14C-glucose metabolism in normal and posthypoxic rat cerebral cortex slices. Polish Journal of Pharmacology and Pharmacy 29: 111–116, 1977
Ennaceur A, Delacour J. Effect of combined or separate administration of piracetam and choline on learning and memory in the rat. Psychopharmacology 92: 58–67, 1987
Ezzat DH, Ibraheem MM, Makhawy B. The effect of piracetam on ECT-induced memory disturbances. British Journal of Psychiatry 147: 720–721, 1985
Fcrnandes CMC, Samuel J. The use of piracetam in vertigo. South African Medical Journal 11: 806–808, 1985
Ferris SH, Sathananthan G, Reisberg B, Gershan S. Long term treatment of memory impaired elderly patients. Science 205: 1039–1040, 1979
Friedman E, Sherman KA, Ferris KA, Reisberg B, Bartus R, et al. Clinical response to choline plus piracetam in senile dementia: relation to red-cell choline levels. New England Journal of Medicine 304: 1490–1491, 1981
Gedye JL, Ibrahimi GS, McDonald C. Double blind controlled trial of piracetam (2-pyrrolidone acetamide) on two groups of psychogeriatric patients. IRCS Medical Science: Clinical Medicine; Clinical Pharmacology and Therapeutics; Psychology and Psychiatry; Social and Occupational Medicine 2: 202, 1978
Gianello P, Janssen T, Chatzopoulos C, Kartheuser A, Lambotte L, et al. Beneficial effect of piracetam on renal blood flow in ischemically injured kidneys in the rat. Transplantation Proceedings 20: 914–916, 1988
Giurgea C, Lefevre D, Lescrenier C, David-Remacle M. Pharmacological protection against hypoxia-induced amnesia in rats. Psychopharmacologia (Berl) 20: 160–168, 1971
Giurgea C, Mourarieff-Lesuisse F, Leemans R. Correlations electro-pharmacologiques all cavs de l’anoxie exyprive chez le lapin en respiration libre ou artificielle. Revue Neurologique 122: 484–486, 1970
Giurgea C, Moyersoons F. Differential pharmacological reactivity of three types of cortical evoked potentials. Archives Internationals de Pharmacodynamie et de Thérapie 188: 401–404, 1970
Giurgea C, Moyersoons F. On the pharmacology of cortical evoked potentials. Archives Internationales de Pharmacodynamie et de Thérapie 199(1): 67–68, 1972
Giurgea C, Moyersoons F. Contribution to the experimental pharmacotherapy of acute drug intoxications. Journal of Pharmacology 5 (Suppl. 2): 37, 1974
Giurgea C, Salama M. Nootropic drugs. Progress in Neuro-Psychopharmacology and Biological Psychiatry 1: 235–247, 1977
Gobert JG. Gènese d’un medicament: le piracetam métabolisation et recherche biochimique. Journal de Pharmacie de Belgique 27: 281–304, 1972
Gobert JG, Baltes EL. Availability and plasma clearance of piracetam in man. Farmaco 2: 83–91, 1977
Growdon JH, Corkin S, Huff FJ, Rosen TJ. Piracetam combined with lecithin in the treatment of Alzheimer’s disease. Neurobiology of Aging 7: 269–276, 1986
Gustafson L, Risberg J, Johanson M, Fransson M, Maximilian VA. Effects of piracetam on regional cerebral blood flow and mental functions in patients with organic dementia. Psychopharmacology 56: 115–117, 1978
Hakkarainen H, Hakamies L. Piracetam in the treatment of post-concussional syndrome: a double-blind study. European Neurology 17: 50–55, 1978
Hall ED, von Voigtlander PF. Facilitatory effects of piracetam on excitability of motor nerve terminals and neuromuscular transmission. Neuropharmacology 26(11): 1573–1579, 1987
Hassmannová J, Mysliveček J, Romoliniovà A. Learning and memory in the ontogeny of rats given piracetam. Activitas Nervosa Superior 22: 95–96, 1980
Henry RL, Nalbandian RM, Dzandu JK. Effect of membrane-bound protein phosphorylation of intact normal and diabetic human erythrocytes: enhanced membrane deformability. Diabetes 30 (Suppl. 1): 83a, 1981
Herrmann WM, Kern U. Nootropic drugs — effects and therapeutic efficacy: a phase II study with piracetam as a model. Nervenarzt 58: 358–364, 1987
Herrschaft H. The effect of piracetam on global and regional cerebral blood flow in acute cerebral ischemia of man. Medizinische Klinik 73: 195–202, 1978
Hronek J. Drahokoupil L, Fait V, Hudeovà T, Laciga Z, et al. Clinical experience with piracetam therapy in gerontology. Comm. 21st Annual Psychopharmacology Meeting, Tchécoslovaquie, Jesenir, pp. 121–129, 1979
Israel L. Memory training programs (MTPs) combined with drug therapy in primary care, including patients with age-associated memory impairment. In Symposium on Piracetam: 5 years’ progress in pharmacology and clinics, pp. 17–22, Technicas Graficas Forma, Madrid, 1990
Kabes J, Erban L, Hanzlicer L, Skondia V. Biological correlates of piracetam clinical effects in psychotic patients. Journal of International Medical Research 7: 277–284, 1979
Koupilová M, Fusek J, Hrdina V, Herink J. Piracetam effect on learning and memory in rats. Activitas Nervosa Superior 22: 193–194, 1980
Krug M, Ott T, Schulzeck K, Matthies H. Effects of orotic acid and pirazetam on cortical bioelectrical activity in rabbits. Psychopharmacology 53: 73–78, 1977
Kruse H, Konler H. Memory enhancing effects of piracetam in aged rats. Abstract. Federation Proceedings 37: 888, 1978
Kuribara H, Tadokoro S. Facilitating effect of oxiracetam and piracetam on acquisition of discrete two-way shuttle avoidance in normal mice. Japanese Journal of Pharmacology 48: 494–498, 1988
Lenègre A, Chermat R, Avril I, Stéru L, Porsolt RD. Specificity of piracetam’s anti-amnesic activity in three models of amnesia in the mouse. Pharmacology, Biochemistry and Behavior 29: 625–629, 1988
Lloyd-Evans S, Brocklehurst JC, Palmer MK. Piracetam in chronic brain failure. Current Medical Research and Opinion 6: 351–357, 1979
Macchione C, Molaschi M, Fabris F, Feruglio FS. Results with piracetam in the management of senile psycho-organic syndromes. Acta Therapeutica 2: 261–269, 1976
Mares P, Marešová D. Effect of piracetam on excitability cycle of cortical interhemispheric responses in the rat. Activitas Nervosa Superior (Praha) 27(4): 285–286, 1985
Marešová D, Mareš P. Effect of piracetam on cortical epileptogenic foci in the rat. Activitas Nervosa Superior 26: 67–68, 1984
Marin Perez GM. Evaluation of the clinical effects of piracetam in the deterioration of the intellectual functions of a geriatric population: a double-blind study. 2nd International Symposium on Nootropic Drugs, Mexico, May 21–22, 1981
Means LW, Franklin RD, Cliett CE. Failure of piracetam to facilitate acquisition or retention in younger or older rats. Experimental Aging Research 6: 175–180, 1980
Mindus P, Cronholm B, Levander SE, Schalling D. Piracetam-induced improvement of mental performance: a controlled study on normally aging individuals. Acta Psychiatrica Scandinavica 54: 150–160, 1976
Mondadori C, Petschke F. Do piracetam-like compounds act centrally via peripheral mechanisms? Brain Research 435: 310–314, 1987
Moos WH, Hershenson FM. Potential therapeutic strategies for senile cognitive disorders. Drug News and Perspectives 2: 397–409, 1989
Moyanova S, Nikolov R. Dimov S. Effect of piracetam on the electrocardiogram after traumatic brain oedema in cats. Methods and Findings in Experimental and Clinical Pharmacology 7(12): 623–626, 1985
Moyersoons F, Everard A, Dauloy J, Giurgea C. A particular pharmacological effect on the propagation of experimental strychnine and penicillin epilepsy. Archives Internationales de Pharmacodynamie et de Thérapie 179(2): 388–400, 1969
Moyersoons F, Giurgea CE. Protective effect of piracetam in experimental barbiturate intoxication: EEG and behavio.ural studies. Archives Internationales de Pharmacodynamie et de Thérapie 210: 38–48, 1974
Müller WE, Pilch H, Stoll L, Schubert T. Piracetam as a possible cell communication modulator — focus on central M-cholinoceptors. Pharmazeutische Zeitung 3: 1–8, 1990
Mysliveček J, Hassmannová J. An electrophysiological analysis of action of piracetam in rats. Activitas Nervosa Superior 16: 242–244, 1974
Mysliveček J, Hassmannová J. Effect of piracetam on learning and brain potentials in rats with early sensory deprivation. Risks of Psychotropic Drugs 19: 171–175, 1975
Nalbandian RM, Henry RL, Burek CL, Diglio CA, Goldman AI, et al. Diminished adherence of sickle erythrocytes to cultured vascular endothelium by piracetam. American Journal of Hematology 15: 147–151, 1983
Nickolson VJ, Wolthuis OL. Differential effects of the acquisition enhancing drug pyrrolidone acetamide (piracetam) on the release of proline from visual and parietal rat cerebral cortex in vitro. Brain Research 113: 616–619, 1976
Nikolova M, Nikolov R, Milanova D. Anti-hypoxic effect of piracetam and its interaction with prostacyclin. Methods and Findings in Experimental and Clinical Pharmacology 6(7): 367–371, 1984
Nikolova M, Nikolov R, Tsikalova R, Popivanov D. Piracetam effect on the visual evoked potentials in cats. Drugs Under Experimental and Clinical Research 6(7): 33–37, 1980
Olpe H-R, Lynch GS. The action of piracetam on the electrical activity of the hippocampal slice preparation: a field potential analysis. European Journal of Pharmacology 80: 415–419, 1982
Olpe H-R, Pozza MF, Jones RSG, Haas HL. Comparative electrophysiological investigations on oxiracetam and piracetam. Clinical Neuropharmacology 9 (Suppl. 3): 48–55, 1986
Olpe H-R, Steinmann MW. The effect of vincamine, hydergine and piracetam on the firing rate of locus coeruleus neurons. Journal of Neural Transmission 55: 101–109, 1982
Oosterveld WJ. The efficacy of piracetam in vertigo. Arzneimittel-Forschung 30(2): 1947–1948, 1980
Parrisius HW. Doppelblindstudie mit Piracetam in der Geriatrie. Geriatrie 7(1): 32–37, 1977
Passeri M. A multicentre study of piracetam in patients with late-onset senile dementia. In Symposium on Piracetam: 5 years’ progress in pharmacology and clinics, pp. 75–80, Technicas Graficas Formas, Madrid, 1990
Pede JP, Schimpfessel L, Grokaert R. The action of piracetam on the oxidative phosphorylation. Archives Internationales de Physiologie et de Biochimie 79: 1036–1037, 1971
Piercey MF, Vogelsang GD, Franklin SR, Tang AH. Reversal of scopolamine-induced amnesia and alterations in energy metabolism by the nootropic piracetam: implications regarding identification of brain structures involved in consolidation of memory traces. Brain Research 424: 1–9, 1987
Pilch H, Müller WE. Piracetam elevates muscarinic cholinergic receptor density in the frontal cortex of aged but not of young mice. Psychopharmacology 94: 74–78, 1988
Platt D, Mühlberg W, Rieck W. The effect of age on clinical pharmacokinetics of piracetam. Arzneimittel-Forschung 35(1): 533–535, 1985
Pomara N, Block R, Moore N, Rhiew HB, Berchou R, et al. Combined piracetam and cholinergic precursor treatment for primary degenerative dementia. IRCS Medical Science 12: 388–389, 1984
Pomara N, Reisberg B, Ferris SH, Gershan S. Drug treatment in cognitive decline. In Maletta GJ, Pirozzolo FJ(Eds) Advances in neurogerontology, Praeger, New York, 1981
Rägo LK, Allikmets LH, Zarkovsky AM. Effects of piracetam on the central dopaminergic transmission. Naunyn-Schmiedeberg’s Archives of Pharmacology 318: 36–37, 1981
Reisberg B, Ferris SH, Schneck MK, Corwin J, Mir P, et al. Piracetam in the treatment of cognitive impairment in the elderly. Drug Development Research 2: 475–480, 1982
Reuse-Blom S, Polderman J. Influence of piracetam upon the pial micro-circulation. In Loose & Loose(Eds) 6th International Angiography and Angiology Seminar, Baden-Baden, March 15–17, 1979. Verlag-Gerhard Witzstrock, Köln, 1980
Richardson AE, Bereen FJ. Effect of piracetam on level of consciousness after neurosurgery. Lancet 2: 1110, 1977
Rochus L, Reuse JJ. Chlorpromazine and phospholipid metabolism in the rat hypothalamus. Effect of pretreatment with piracetam. Archives Internationales de Physiologie et de Biochimie 82: 1010–1011, 1974
Saletu B, Grunberger J. Memory dysfunction and vigilance: neurophysiological and pharmacological aspects. Annals of the New York Academy of Sciences 444: 406–427, 1985
Sannita WG, Balestra V, Rosadini G, Salama M, Timitilli C. Quantitative EEG and neuropsychological effects of piracetam and of the association piracetam-lecithin in healthy volunteers. Neuropsychobiology 14: 203–209, 1985
Sara SJ, David-Remacle M, Lefevre D. Passive avoidance behaviour in rats after electroconvulsive shock: facilitative effect of response retardation. Journal of Comparative and Physiological Psychology 89: 489–407, 1975
Sara SJ, David-Remacle M, Weyers M, Giurgea C. Piracetam facilitates retrieval but does not impair extinction of bar-pressing in rats. Psychopharmacology 61: 71–75, 1979
Sara SJ, Lefevre D. Hypoxia-induced amnesia in one-trial learning and pharmacological protection by piracetam. Psychopharmacologia 25: 32–40, 1972
Sato M, Heiss W-D. Effect of piracetam on cerebral blood flow and somatosensory evoked potential during normotension and hypotensive ischemia in cats. Arzneimittel-Forschung 35: 790–792, 1985
Schmidt U, Brendemühl D, Engels K, Sehenk N, Ludemann E. Piracetam and the driving behaviour of elderly motorists in standardized test runs under road traffic conditions. Symposium on Piracetam: 5 years’ progress in pharmacology and clinics, pp. 47–60, Technicas Graficas Formas, Madrid, 1990
Schulz H-U, Wittler Th. Age-related changes in pharmacokinetics of 2-oxo-pyrrolidine-l-acetamide (piracetam) in man. Abstract 211. Naunyn-Schmiedeberg’s Archives of Pharmacology 313 (Suppl.): R53, 1980
Serby M, Corwin J, Rotrosen J, Ferris SH, Reisberg B, et al. Lecithin and piracetam in Alzheimer’s disease. Psychopharmacology Bulletin 19: 126–129, 1983
Smith RC, Vroulis G, Johnson R, Morgan R. Comparison of therapeutic response to long-term treatment with lecithin versus piracetam plus lecithin in patients with Alzheimer’s disease. Psychopharmacology Bulletin 20(3): 542–545, 1984
Stegink AJ. The clinical use of piracetam, a new nootropic drug. The treatment of symptoms of senile involution. Arzneimittel-Forschung 22: 975–977, 1972
Valzelli L, Baiguerra G, Giraud O. Difference in learning and retention by albino Swiss mice. Part III. Effect of some brain stimulants. Methods and Findings in Experimental and Clinical Pharmacology 8(6): 337–341, 1986
Valzelli L, Bernasconi S, Sala A. Piracetam activity may differ according to the age of the recipient mouse. International Pharmacopsychiatry 15: 150–156, 1980
von Dorn M. Piracetam bei vorzeitiger biologischer Alterung: doppelblind-prüfung nach medikamentöser Vorselektion. Fortschritte der Medizin 96: 1525–1530, 1978
von Kretschmar JH, Kretschmar L. On the dose-effect relationship in the therapy with piracetam. Arzneimittel-Forschung 26: 1158–1159, 1976
von Ostrowski J, Keil M. Autoradiographische Untersuchungen zur Verteilung von 14C-Piracetam im Affengehirn. Arzneimittel-Forschung 28(1): 29–35, 1978
von Ostrowski J, Keil M, Schraven E. Autoradiographische Untersuchungen zur Verteilung von Piracetam-14C bei Ratte und Hund. Arzneimittel-Forschung 25: 589–596, 1975
von Woelk H. Zum Einfluss von Piracetam auf die neuronale und synaptosomale Phospholipase-A2-Aktivität. Arzneimittel-Forschung 29(1): 615–618, 1979
Voronina TA, Krapivin SV, Nerobkova LN. Specificity of action of pyracetam, pyritinol, and cleregil on the transcallosal evoked potential. Bulletin of Experimental Biology and Medicine 101: 326–329, 1986
Wahl M, Kuschinsky W. Report on the study of the direct vaso-active action of piracetam upon the cerebral vascular system of the cat. In Loose & Loose (Eds) 6th International Angiography and Angiology Seminar, Baden-Baden, March 15–17, 1979. Verlag Gerhard Witzstrock, Köln, 1980
Weth G. The influence of piracetam on the cyclic adenosine monophosphate (cAMP) concentration in the brain and colon of guinea pigs. Arzneimittel-Forschung 33(1): 812–814, 1983
Wolthuis OL. Experiments with UCB 6215, a drug which enhances acquisition in rats: its effects compared with those of metamphetamine. European Journal of Pharmacology 16: 283–297, 1971
Wolthuis OL, Nickolson VJ. Piracetam and acquisition behaviour in rats: electrophysiological and biochemical effects. 3rd Congress International College of Psychosomatic Medicine, Rome: 135–149, 1975
Wurtman RJ, Magic SG, Reinstein DK. Piracetam diminishes hippocampal ACh levels in rats. Life Sciences 28: 1091–1093, 1981
Yamada K, Inoue T, Tanaka M, Furukawa T. Prolongation of latencies for passive avoidance responses in rats treated with aniracetam or piracetam. Pharmacology, Biochemistry and Behavior 22: 645–648, 1985
Author information
Authors and Affiliations
Additional information
Various sections of the manuscript reviewed by: A. Ennaceur, Laboratoire de Psychophysiologie, Université Paris 7, France; S.H. Ferris, Aging and Dementia Research Center, New York University Medical Center, New York, New York, USA; J. Kabeš, Department of Neurology and Psychiatry, Faculty Hospital, Prague, Czechoslovakia; C. McDonald, Warlingham Park Hospital, Warlingham, Surrey, England; J.S. Meyer, Cerebrovascular Research Laboratories, Baylor College of Medicine, Houston, Texas, USA; M. Nikolova, The Chemical Pharmaceutical Research Institute, Sofia, Bulgaria.
Rights and permissions
About this article
Cite this article
Vernon, M.W., Sorkin, E.M. Piracetam. Drugs & Aging 1, 17–35 (1991). https://doi.org/10.2165/00002512-199101010-00004
Published:
Issue Date:
DOI: https://doi.org/10.2165/00002512-199101010-00004
Keywords
- Passive Avoidance
- Piracetam
- Aniracetam
- Oxiracetam
- Nootropic Drug