zorn
Bluelighter
Another study, with some intriguing results, substantiating the link between MDMA and long-term memory damage. The abstract is below. Also, Arch Gen Pysch also included a critique by McCann, Ricaurte, and crew, which does a nice job in my view of covering the problems and major unresolved issues with MDMA neurotoxicity.
A couple highlights:
Article Abstract
Reneman L, Lavalaye J, Schmand B, de Wolff FA, van den Brink W, den Heeten GJ, Booij J.
Cortical Serotonin Transporter Density and Verbal Memory in Individuals Who Stopped Using 3,4-Methylenedioxymethamphetamine (MDMA or "Ecstasy"); Preliminary Findings
Arch Gen Psych 58(10):901-906 (Oct 2001).
Background Although the popular drug 3,4-methylenedioxymethamphetamine (MDMA or "ecstasy") has been shown to damage brain serotonin (5-HT) neurons in animals, the fate and functional consequences of 5-HT neurons after MDMA injury are not known in humans. We investigated the long-term effects of MDMA use on cortical 5-HT neurons in humans and memory function, because brain 5-HT has been implicated in memory function.
Methods Twenty-two recent MDMA users, 16 ex-MDMA users who had stopped using MDMA for more than 1 year, and 13 control subjects. The effects of MDMA use on cortical 5-HT neurons was studied by means of single-photon emission computed tomography with iodine 123–labeled 2-carbomethoxy-3-(4-iodophenyl) tropane ([123I]-CIT) by quantification of brain 5-HT transporter densities. Verbal memory performance was assessed with the Rey Auditory Verbal Learning Test.
Results Mean cortical [123I]-CIT-labeled 5-HT transporter density was significantly lower in recent MDMA users than in controls (1.17 vs 1.28 [–9%]) but not in ex-MDMA users (1.24 vs 1.28 [-3%]). Recent and ex-MDMA users recalled significantly fewer words than did controls on the immediate recall (47.0 and 48.0 vs 60.0, respectively; P = .001) as well as the delayed recall (9.8 and 10.1 vs 13.1, respectively; P = .003). Greater use of MDMA was associated with greater impairment in immediate verbal memory. However, memory performance was not associated with [123I]-CIT binding to cortical 5-HT transporters or duration of abstinence from MDMA.
Conclusion The present study suggests that, while the neurotoxic effects of MDMA on 5-HT neurons in the human cortex may be reversible, the effects of MDMA on memory function may be long-lasting.
Commentary text
McCann UD, Ricaurte GA, Molliver ME
"Ecstasy" and Serotonin Neurotoxicity: New Findings Raise More Questions.
Arch Gen Psych 58(10):907-908 (Oct 2001)
THE ARTICLE by Reneman et al1 in this issue of the ARCHIVES is timely and provocative and highlights several areas of controversy in the fields of substance abuse, drug-induced neurotoxic effects, and neuroimaging. The authors present evidence that the illicit recreational drug 3,4-methylenedioxymethamphetamine (MDMA, or "ecstasy") may cause persistent cognitive deficits2-9 and that these deficits are related to the extent of previous MDMA use. Based on single-photon emission computed tomography (SPECT) imaging with 123I-labeled 2-carbomethoxy-3-(4-iodophenyl)tropane (-CIT), they conclude that MDMA causes neurotoxic injury to cortical serotonin (5-HT) axon terminals that may be reversible. This is the first study to evaluate a separate cohort of previous MDMA users who have abstained from use for longer than 1 year, and thus has the potential to provide information regarding long-term effects of exposure to MDMA.
With respect to cognitive effects of MDMA, there is some question regarding the role of concomitant marijuana use in the cognitive deficits observed in MDMA users. Reports by Rodgers10 and Croft et al11 indicate that marijuana is an important confounding factor in studies of cognitive function in MDMA users, with marijuana use predicting much of the observed cognitive decline. This is a nettlesome problem, since most MDMA users also use marijuana. In the present study, although the "ex-MDMA" group of subjects abstained from MDMA for at least 1 year, they continued substantial marijuana use, potentially accounting for diminished cognitive performance. Nevertheless, the present findings of impaired verbal memory are cause for concern and underscore the need for longitudinal studies in MDMA users to evaluate the persistence of functional deficits and to determine whether tardive adverse effects emerge. Clearly, future studies aimed at elucidating cognitive effects of MDMA use will need to control for concomitant marijuana use. Moreover, the relationship between MDMA-induced serotonin neurotoxicity and cognitive deficits in MDMA users needs further investigation and will require assessment of several brain regions (eg, hippocampus) in addition to cerebral cortex.
Data obtained using SPECT with the radioligand [123I]-CIT insert themselves into the ongoing debate regarding the suitability of this method for measuring serotonin transporter (SERT) sites in cerebral cortex. Several laboratories12-14 have demonstrated the capability of [123I]-CIT for measurement of brainstem and mid brain SERT. However, as noted by Heinz and Jones,15 there is little evidence that SPECT with [123I]-CIT can accurately measure specific binding to cortical SERT sites, with studies in a nonhuman primate demonstrating no change in the level of cortical [123I]-CIT binding following administration of the serotonin reuptake inhibitor, citalopram.12 Nevertheless, one other research group16 has also reported reductions in the binding of [123I]-CIT in occipital cortex of MDMA users. To address the question of whether MDMA-induced brain serotonin injury in cerebral cortex can be detected by SPECT with [123I]-CIT, studies using large nonhuman primates, such as baboons, with similar cortical SERT distributions and densities as humans are required, ideally before and after MDMA treatment.
An important issue regarding SPECT sensitivity deserves clarification. The authors note in the "Comment" section that reductions in cortical [123I]-CIT in MDMA users were on the order of 9%, while previous binding studies in nonhuman primates17 given doses of MDMA similar to those used by humans exhibit far greater deficits in cortical 5-HT axonal markers, ranging from 83% to 95%. This disparity leads the authors to conclude that MDMA is less toxic toward humans than primates. However, it has not been established that reduced binding of [123I]-CIT corresponds directly with decreased 5-HT axonal markers measured using in vitro tissue samples. Notably, SPECT studies in MDMA-treated monkeys using [123I]INQUIP,18 a SERT (5-HT transporter) radioligand with similar cortical/cerebellar binding ratios to [123I]-CIT, found that MDMA-treated monkeys exhibited cortical reductions of less than 5% by SPECT, while in vitro measures indicated reductions greater than 75%. These values reveal a large disparity between SERT levels determined by SPECT and by direct in vitro tissue samples. This difference between 2 dissimilar methods raises questions regarding the sensitivity of SPECT for detecting SERT in cerebral cortex, as recognized by the authors. Thus, until the sensitivity and accuracy of SPECT with [123I]-CIT for measuring SERT density in neocortex is established, conclusions regarding the degree of MDMA-induced cortical damage may be premature.
While the results of Reneman and coauthors and others suggest that MDMA can produce cognitive impairment (memory loss), several important questions concerning causality and mechanisms remain unresolved. Does decreased binding of -CIT measured with SPECT reliably indicate a loss of SERT in neocortex? Does the decrease in SERT result from frank axonal degeneration or from reduced SERT expression in surviving axons? Histologic studies in animals demonstrate that MDMA causes extensive loss of 5-HT axons in numerous brain regions,17, 19, 20 and a similar pattern of neurotoxic effects likely occurs in humans. An unresolved issue is whether the 5-HT axonal damage in neocortex is directly responsible for cognitive changes. Moreover, the regional localization of 5-HT axon loss that produces cognitive decline should be determined since denervation of hippocampus may cause memory loss, while the neocortical changes might be unrelated.
The observation that [123I]-CIT binding in cortex returns to normal in subjects who were abstinent for 1 year leads the authors to conclude that MDMA-induced damage to cortical 5-HT axon terminals may be reversible. This interpretation must be viewed with caution since, as mentioned earlier, the sensitivity of [123I]-CIT for measuring cortical SERT reliably is not established. Moreover, axonal regeneration in the adult brain may lead to abnormal, dysfunctional circuitry. The notion of spontaneous recovery has important public health implications since drug users may be led to believe that MDMA-induced damage can be reversed merely by abstaining from MDMA. However, experimental studies report that MDMA's neurotoxic effects on serotonin neurons in primates are extremely long-lasting and may be permanent.17, 21
The findings by Reneman and colleagues suggest several future directions for research in MDMA neurotoxicity. As noted previously, preclinical studies in nonhuman primates are essential for the interpretation of findings in humans. For example, it is important to establish that SPECT with [123I]-CIT is capable of reliably detecting MDMA-induced serotonin neurotoxicity in primate neocortex, and if so, the sensitivity of the method should be determined in multiple regions of cerebral cortex. Similarly, abnormal magnetic resonance spectroscopy, positron emission tomography, or functional magnetic resonance imaging data from human MDMA users can best be interpreted with reference to data from nonhuman primates that exhibit documented neurotoxic injury. A similar approach could be applied to functional consequences of MDMA use, including cognitive and neuroendocrine changes seen in MDMA users. Such studies will help clarify the relationship between neurotoxic injury and functional deficits. Another direction for clinical research in MDMA is to determine the long-term effects of MDMA use. These studies should address questions of potential recovery, as well as the possibility that tardive effects of MDMA on serotonin neurons may become manifest with age. Additionally, as knowledge grows regarding the mechanisms of MDMA-induced neurotoxicity, it may be possible to define genetic risk factors for the development of toxicity or methods for preventing injury and promoting recovery in those who have sustained damage.
In conclusion, the article by Reneman and colleagues raises several important questions. Fortunately, the tools for addressing many of these questions are available, and will undoubtedly be used to shed light on many issues regarding the neurotoxic effects of MDMA and its functional consequences in humans. Meanwhile, it is urgent to focus public attention on the current results indicating that MDMA may cause long-term damage and dysfunction in the human brain.
[ 15 December 2001: Message edited by: zorn ]
A couple highlights:
- Marijuana as always remains an important confounding factor in these studies. Despite what you may have heard, heavy marijuana use does impair cognitive ability, though much if not all of the impairment seems to be reversible upon cessation of marijuana use.
- The observed impairment in memory was large (47 vs 60 on their test, the RAVLT) and statistically very significant. (P<0.001) Users (n=22) had taken on average about 500 pills over 5.5 years, or about two pills/week for 5.5 years. The level of memory impairment was well correlated with the total amount of MDMA taken (p<0.05, r=-0.3), but not with abstinence from MDMA nor beta-CIT binding in the brain. This suggests that the regeneration of damaged serotonergic nerves after heavy MDMA use does not alleviate MDMA-induced memory problems.
- Studying the cortex may be the wrong way to go. It is important to study other brain regions, eg the hippocampus, to see if MDMA neurotoxicity here is better correlated with functional damage.
- The serotonin transporter loss seen in humans in newer studies using radioligands/SPECT appears to be on the order of 10%, whereas animals given similar regimins of MDMA have 80%-95% loss. McCann et al suggest this could be due to inaccuracies of the radiolabel in the region being scanned. I can't judge this claim but it seems reasonable, and they cite some independent research in support of it.
Article Abstract
Reneman L, Lavalaye J, Schmand B, de Wolff FA, van den Brink W, den Heeten GJ, Booij J.
Cortical Serotonin Transporter Density and Verbal Memory in Individuals Who Stopped Using 3,4-Methylenedioxymethamphetamine (MDMA or "Ecstasy"); Preliminary Findings
Arch Gen Psych 58(10):901-906 (Oct 2001).
Background Although the popular drug 3,4-methylenedioxymethamphetamine (MDMA or "ecstasy") has been shown to damage brain serotonin (5-HT) neurons in animals, the fate and functional consequences of 5-HT neurons after MDMA injury are not known in humans. We investigated the long-term effects of MDMA use on cortical 5-HT neurons in humans and memory function, because brain 5-HT has been implicated in memory function.
Methods Twenty-two recent MDMA users, 16 ex-MDMA users who had stopped using MDMA for more than 1 year, and 13 control subjects. The effects of MDMA use on cortical 5-HT neurons was studied by means of single-photon emission computed tomography with iodine 123–labeled 2-carbomethoxy-3-(4-iodophenyl) tropane ([123I]-CIT) by quantification of brain 5-HT transporter densities. Verbal memory performance was assessed with the Rey Auditory Verbal Learning Test.
Results Mean cortical [123I]-CIT-labeled 5-HT transporter density was significantly lower in recent MDMA users than in controls (1.17 vs 1.28 [–9%]) but not in ex-MDMA users (1.24 vs 1.28 [-3%]). Recent and ex-MDMA users recalled significantly fewer words than did controls on the immediate recall (47.0 and 48.0 vs 60.0, respectively; P = .001) as well as the delayed recall (9.8 and 10.1 vs 13.1, respectively; P = .003). Greater use of MDMA was associated with greater impairment in immediate verbal memory. However, memory performance was not associated with [123I]-CIT binding to cortical 5-HT transporters or duration of abstinence from MDMA.
Conclusion The present study suggests that, while the neurotoxic effects of MDMA on 5-HT neurons in the human cortex may be reversible, the effects of MDMA on memory function may be long-lasting.
Commentary text
McCann UD, Ricaurte GA, Molliver ME
"Ecstasy" and Serotonin Neurotoxicity: New Findings Raise More Questions.
Arch Gen Psych 58(10):907-908 (Oct 2001)
THE ARTICLE by Reneman et al1 in this issue of the ARCHIVES is timely and provocative and highlights several areas of controversy in the fields of substance abuse, drug-induced neurotoxic effects, and neuroimaging. The authors present evidence that the illicit recreational drug 3,4-methylenedioxymethamphetamine (MDMA, or "ecstasy") may cause persistent cognitive deficits2-9 and that these deficits are related to the extent of previous MDMA use. Based on single-photon emission computed tomography (SPECT) imaging with 123I-labeled 2-carbomethoxy-3-(4-iodophenyl)tropane (-CIT), they conclude that MDMA causes neurotoxic injury to cortical serotonin (5-HT) axon terminals that may be reversible. This is the first study to evaluate a separate cohort of previous MDMA users who have abstained from use for longer than 1 year, and thus has the potential to provide information regarding long-term effects of exposure to MDMA.
With respect to cognitive effects of MDMA, there is some question regarding the role of concomitant marijuana use in the cognitive deficits observed in MDMA users. Reports by Rodgers10 and Croft et al11 indicate that marijuana is an important confounding factor in studies of cognitive function in MDMA users, with marijuana use predicting much of the observed cognitive decline. This is a nettlesome problem, since most MDMA users also use marijuana. In the present study, although the "ex-MDMA" group of subjects abstained from MDMA for at least 1 year, they continued substantial marijuana use, potentially accounting for diminished cognitive performance. Nevertheless, the present findings of impaired verbal memory are cause for concern and underscore the need for longitudinal studies in MDMA users to evaluate the persistence of functional deficits and to determine whether tardive adverse effects emerge. Clearly, future studies aimed at elucidating cognitive effects of MDMA use will need to control for concomitant marijuana use. Moreover, the relationship between MDMA-induced serotonin neurotoxicity and cognitive deficits in MDMA users needs further investigation and will require assessment of several brain regions (eg, hippocampus) in addition to cerebral cortex.
Data obtained using SPECT with the radioligand [123I]-CIT insert themselves into the ongoing debate regarding the suitability of this method for measuring serotonin transporter (SERT) sites in cerebral cortex. Several laboratories12-14 have demonstrated the capability of [123I]-CIT for measurement of brainstem and mid brain SERT. However, as noted by Heinz and Jones,15 there is little evidence that SPECT with [123I]-CIT can accurately measure specific binding to cortical SERT sites, with studies in a nonhuman primate demonstrating no change in the level of cortical [123I]-CIT binding following administration of the serotonin reuptake inhibitor, citalopram.12 Nevertheless, one other research group16 has also reported reductions in the binding of [123I]-CIT in occipital cortex of MDMA users. To address the question of whether MDMA-induced brain serotonin injury in cerebral cortex can be detected by SPECT with [123I]-CIT, studies using large nonhuman primates, such as baboons, with similar cortical SERT distributions and densities as humans are required, ideally before and after MDMA treatment.
An important issue regarding SPECT sensitivity deserves clarification. The authors note in the "Comment" section that reductions in cortical [123I]-CIT in MDMA users were on the order of 9%, while previous binding studies in nonhuman primates17 given doses of MDMA similar to those used by humans exhibit far greater deficits in cortical 5-HT axonal markers, ranging from 83% to 95%. This disparity leads the authors to conclude that MDMA is less toxic toward humans than primates. However, it has not been established that reduced binding of [123I]-CIT corresponds directly with decreased 5-HT axonal markers measured using in vitro tissue samples. Notably, SPECT studies in MDMA-treated monkeys using [123I]INQUIP,18 a SERT (5-HT transporter) radioligand with similar cortical/cerebellar binding ratios to [123I]-CIT, found that MDMA-treated monkeys exhibited cortical reductions of less than 5% by SPECT, while in vitro measures indicated reductions greater than 75%. These values reveal a large disparity between SERT levels determined by SPECT and by direct in vitro tissue samples. This difference between 2 dissimilar methods raises questions regarding the sensitivity of SPECT for detecting SERT in cerebral cortex, as recognized by the authors. Thus, until the sensitivity and accuracy of SPECT with [123I]-CIT for measuring SERT density in neocortex is established, conclusions regarding the degree of MDMA-induced cortical damage may be premature.
While the results of Reneman and coauthors and others suggest that MDMA can produce cognitive impairment (memory loss), several important questions concerning causality and mechanisms remain unresolved. Does decreased binding of -CIT measured with SPECT reliably indicate a loss of SERT in neocortex? Does the decrease in SERT result from frank axonal degeneration or from reduced SERT expression in surviving axons? Histologic studies in animals demonstrate that MDMA causes extensive loss of 5-HT axons in numerous brain regions,17, 19, 20 and a similar pattern of neurotoxic effects likely occurs in humans. An unresolved issue is whether the 5-HT axonal damage in neocortex is directly responsible for cognitive changes. Moreover, the regional localization of 5-HT axon loss that produces cognitive decline should be determined since denervation of hippocampus may cause memory loss, while the neocortical changes might be unrelated.
The observation that [123I]-CIT binding in cortex returns to normal in subjects who were abstinent for 1 year leads the authors to conclude that MDMA-induced damage to cortical 5-HT axon terminals may be reversible. This interpretation must be viewed with caution since, as mentioned earlier, the sensitivity of [123I]-CIT for measuring cortical SERT reliably is not established. Moreover, axonal regeneration in the adult brain may lead to abnormal, dysfunctional circuitry. The notion of spontaneous recovery has important public health implications since drug users may be led to believe that MDMA-induced damage can be reversed merely by abstaining from MDMA. However, experimental studies report that MDMA's neurotoxic effects on serotonin neurons in primates are extremely long-lasting and may be permanent.17, 21
The findings by Reneman and colleagues suggest several future directions for research in MDMA neurotoxicity. As noted previously, preclinical studies in nonhuman primates are essential for the interpretation of findings in humans. For example, it is important to establish that SPECT with [123I]-CIT is capable of reliably detecting MDMA-induced serotonin neurotoxicity in primate neocortex, and if so, the sensitivity of the method should be determined in multiple regions of cerebral cortex. Similarly, abnormal magnetic resonance spectroscopy, positron emission tomography, or functional magnetic resonance imaging data from human MDMA users can best be interpreted with reference to data from nonhuman primates that exhibit documented neurotoxic injury. A similar approach could be applied to functional consequences of MDMA use, including cognitive and neuroendocrine changes seen in MDMA users. Such studies will help clarify the relationship between neurotoxic injury and functional deficits. Another direction for clinical research in MDMA is to determine the long-term effects of MDMA use. These studies should address questions of potential recovery, as well as the possibility that tardive effects of MDMA on serotonin neurons may become manifest with age. Additionally, as knowledge grows regarding the mechanisms of MDMA-induced neurotoxicity, it may be possible to define genetic risk factors for the development of toxicity or methods for preventing injury and promoting recovery in those who have sustained damage.
In conclusion, the article by Reneman and colleagues raises several important questions. Fortunately, the tools for addressing many of these questions are available, and will undoubtedly be used to shed light on many issues regarding the neurotoxic effects of MDMA and its functional consequences in humans. Meanwhile, it is urgent to focus public attention on the current results indicating that MDMA may cause long-term damage and dysfunction in the human brain.
[ 15 December 2001: Message edited by: zorn ]
