There seems to be a lot of negativity directed towards nootropics including piracetam even on this board. A few negative individualys have claimed there are no benefits from taking this drug. In this thread I will attempt to present some of the research and information on the subject. Feel free to add your own.
http://sulcus.berkel...ripts/_774.html
Piracetam is a psychoactive drug widely used in European and Asian countries for its ability to augment cognitive, learning, and memory abilities, to decrease oxidative and hypoxic stress and to stabilize cells in the blood and CNS (central nervous system). With no known toxicity or addictive properties documented in the past two decades, the drug has been used overseas to address numerous neurological and physical disorders including: myoclonus, Down's syndrome, sickle cell anemia, dyslexia, senile dementia, and others. However, as piracetam is not currently approved by the FDA (Federal Drug Administration) or manufactured by any U.S. pharmaceutical companies, there is very little clinical information and research in the United States. The goal of this paper is to introduce the study of nootropic drugs, summarize current theories on their mechanism of action, and describe relevant applications of piracetam as documented in recent international and domestic research.
Piracetam is among the most popular of the smart drugs due to its reported efficacy in enhancing cognitive ability and alleviating various ailments among normal and disease-afflicted individuals. The exact mechanism of action for piracetam is still undetermined but believed to affect many physiological systems simultaneously.
Recent human research has finally started to shed light on the mechanism(s) and effects of piracetam. Elderly psychiatric patients have been administered piracetam for years to improve memory (8) and treat Alzheimer's disease and multi-farct dementia. The synergistic effect of choline with piracetam was not observed in the elderly (9) but PET (positron emission tomography) experiments have verified improved glucose metabolism in piracetam-using AD patients. (10) These studies and others have collectively led scientists toward a cholinergic mechanism of action and/or influence on ion transport..
Although the exact details of piracetam metabolism haven't been deduced, a recent review of piracetam and other structurally related nootropics indicate piracetam potentiates an increase of sodium/calcium influx or decrease in potassium efflux during neurotransmission. Many common psychoactive pathways such as muscarinic, dopaminergic, GABAergic receptors show no affinity when piracetam is used.
"The piracetam-like nootropics are capable of achieving reversal of amnesia induced by, e.g., scopolamine, electroconvulsive shock and hypoxia. Protection against barbiturate intoxication is observed and some benefit in clinical studies with patients suffering from mild to moderate degrees of dementia has been demonstrated. No affinity for the alpha 1-, alpha 2-, beta-, muscarinic, 5-hydroxytryptamine-, dopamine, adenosine-A1-, mu-opiate, gamma-aminobutyric acid (GABA) (except for nefiracetam (GABAA)), benzodiazepine and glutamate receptors has been found. The racetams possess a very low toxicity and lack serious side effects. Increased turnover of different neurotransmitters has been observed as well as other biochemical findings, e.g., inhibition of enzymes such as prolylendopeptidase. So far, no generally accepted mechanism of action has, however, emerged. We believe that the effect of the racetams is due to a potentiation of already present neurotransmission and that much evidence points in the direction of a modulated ion flux by, e.g., potentiated calcium influx through non-L-type voltage-dependent calcium channels, potentiated sodium influx through alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor gated channels or voltage-dependent channels or decreases in potassium efflux. Effects on carrier mediated ion transport are also possible." (11)
For nearly three decades, piracetam has exhibited extremely low toxicity in research with humans. Although extremely large doses of piracetam have been administered to humans in clinical studies, average daily doses for normal people range between 800-4000 milligrams, which is a rather large amount for a psychoactive substance.
"The classical measure of drug toxicity, the LD-50 (the dose causing death for 500f test animals), is not applicable; standard dosing methods (oral, intravenous injection, intraperitoneal injection) cannot deliver enough piracetam to kill laboratory animals. Doses of greater than 20g/day have been given to people suffering from myoclonic seizure disorders, without serious side effects [Karacostas et al., 1993]. The recommended dose of piracetam for infants with myoclonic seizures is 10-20g/day (approximately 1-2 rounded tablespoons), a phenomenally high dose by normal drug standards." (13)
The documented efficacy and extremely low toxicity of piracetam also make it a lucrative nootropic for private industry, especially the various analogues under development such as vinpocetine, aniracetam, pramiracetam, oxiracetam, and others. These drugs have been under intensive research and development during this past decade. The piracetam analogues also demonstrate the low toxicity associated with nootropics and in some cases, even greater efficacy.
Alarmist opinion regarding the safety of nootropics has quieted over the past few years as piracetam has been acknowledged as the drug of choice for treating myoclonus, a seizure-like condition characterized by uncontrollable muscle twitching or jerking. (14) A nationwide multi-institution study in Japan found:
"Piracetam was effective in myoclonus, especially that of cortical origin, in both monotherapy and polytherapy. Piracetam also had positive benefits on gait ataxia and convulsions but not on dysarthria, and feeding and handwriting improved much more significantly. Psychologically significant improvement was seen in decreased motivation, sleep disturbance, attention deficit, and depression, all of which might be possibly secondary benefits associated with improvement of myoclonus. There was no positive correlation between clinical and electrophysiological improvement. Tolerance was good, and side effects were transient. However, hemtological abnormalities observed in at least two patients in the present study should be kept in mind when relatively large doses of piracetam are administered, especially in combination with other antimyoclonic drugs." (15)
These desirable effects have been associated with alterations in lipid membrane fluidity within the brain. Membrane fluidity is an indicator of permeability, influenced by many factors such as cholesterol content, fatty acid profile, and degree of lipid peroxidation. Higher levels of cholesterol content, fatty acid saturation (hydrogenation) and peroxidation (form of oxidative stress) cause lipid membranes to become rigid and impermeable. Piracetam has already been shown to alleviate oxidative stress caused by excess hydrogen peroxide and increase membrane fluidity in the brain.
"In vitro preincubation of brain membranes of aged mice with piracetam (0.1-1.0 mmol/L) enhanced membrane fluidity, as indicated by decreased anisotropy of the membrane-bound fluorescence probe 1,6-diphenyl-1,3,5-hexatriene (DPH). Piracetam had similar in vitro effects on brain membranes of aged rats and humans, but it did not alter brain membrane fluidity in young mice. Chronic treatment of young and aged rats with piracetam (300 mg/kg once daily) significantly increased membrane fluidity in some brain regions of the aged animals, but had no measurable effect on membrane fluidity in the young rats. The same treatment significantly improved active avoidance learning in the aged rats only. It is suggested that some of the pharmacological properties of piracetam can be explained by its effects on membrane fluidity." (16)
Hypoxia (a condition of low oxygen levels in the tissues caused by hypobaric conditions, decreased oxygen-carrying capacity of the blood, and impaired circulation) has been treated with piracetam because of its protective effects from lipid peroxidation.
Medical applications are being researched in Russia including improvement of metabolic and hormonal indices disturbed by collateral damage from heart disease (17) and treatment of hypoxia-related damage from prostaglandin synthesis (powerful hormones created by oxygen free radicals and polyunsaturated fatty acids). (18) Vast amounts of anecdotal evidence among athletes, academics, elderly people, and parents with children afflicted by DS (developmental delays in closing of heart muscle wall cause de-oxygenated blood to circulate resulting in chronic hypoxia) support piracetam's usefulness in treating hypoxia-related symptoms.
However, the treatment of Down's Syndrome remains the center of controversy regarding the applications of piracetam. A recent presentation at by the Pediatric Academic Societies in San Francisco included a study reporting that piracetam does not enhance cognitive abilities in moderate to high-functioning 7-13 year-old children with DS.
"Piracetam, a drug reported to enhance cognitive performance in many neurobehavioural conditions, has become popular in the treatment of children with Down Syndrome (DS). However, reports of its efficacy in DS have been anecdotal, not from evidence-based studies. Some caregivers have noted no effect of piracetam, while others claim substantial improvement in cognitive functioning. To address the need for objective analysis, we conducted a double-blind placebo-controlled crossover study assessing the cognitive and behavioral effects of piracetam in children with DS... Piracetam did not show significant effects over placebo on any outcome measure (ANCOVA, covariate was age at baseline). All significant interactions (p's < 0.05) with drug order or the covariate were examined further to ensure drug effects were not being masked. That analysis did not alter the results. Piracetam administration was associated with CNS stimulatory effects: aggressiveness (n=4), agitation (n =3), sexual arousal, (including masturbation in public, n=2), irritability (n=1), and poor sleep (n=1). Conclusion. Piracetam has received a great deal of attention in the popular press purporting its efficacy in improving cognitive function in children with Down Syndrome. In this study, we were unable to substantiate these claims, even at doses associated with adverse effects. Neither cognitive nor behavioural measures demonstrated improvement under piracetam. Due to the serious adverse effects, it is unlikely that larger doses can be tolerated."(19)
Fortunately, because nootropics exhibit favorable activity in cognitive enhancement and are relatively safe, piracetam has fared reasonably well within this tumultuous context of science and politics. With orphan drug status as a treatment for myoclonus, and a study of piracetam and Ts65dn mice (an animal model for trisomy 21) currently underway at John Hopkins, U.S. research is finally starting to pick up speed. A new study assessing the feasibility of piracetam and school-aged children has gained attention at Kennedy-Kriger Institute in an effort to raise awareness for the possible application of piracetam and possibly acquire funding for a large-scale study by the FDA. In addition, with adequate media coverage and an American manufacturer, the expected profitability of piracetam may eventually speed the FDA approval process, illuminating the future of piracetam and its users in the United States.
