Showing posts with label meth. Show all posts
Showing posts with label meth. Show all posts
Thursday, October 2, 2014
Strokes in Young People
Drug use as a risk factor.
(First published 12-09-12)
When a stroke happens to anyone under the age of 55, a major suspect is drugs, specifically the stimulants—methamphetamine and cocaine. In the journal Stroke, researcher Brett Kissela and his associates provided additional evidence to support that unpleasant truth.
“We know that even with vascular risk factors that are prevalent—smoking, high blood pressure—most people still don’t have a stroke until they’re older,” Kissela said in a Reuters article. “When a young person has a stroke, it is probably much more likely that the cause of their stroke is something other than traditional risk factors.”
The modest study involved residents of Cincinnati and Northern Kentucky who had suffered a stroke before turning 55. The researchers found that the rate of substance abuse among the stroke group was higher than in control populations. This doesn’t prove that drug or alcohol addiction lead directly to strokes, since drug users often have additional risk factors for stroke and heart disease, particularly if they are also cigarette smokers.
But the suspected link between strokes and young drug abusers is by no means a new one. In 2007, scientists at the University of Texas Southwestern Medical Center in Dallas published a massive survey of more than 3 million records of Texas hospital patients from 2000 through 2003 in the Archives of General Psychiatry. This gigantic database gave the researchers access to the records of virtually every stroke patient in the state of Texas. The researchers found that strokes associated with amphetamine use among young people 18 to 44 years of age represented a rapidly growing category. In fact, the Texas group found that “the rate of strokes among amphetamine abusers was increasing faster than the rate of strokes among abusers of any other drug.”
Curiously, amphetamine and cocaine are responsible for different kinds of strokes. An ischemic stroke, the classic blood clot, is caused by a blockage of blood vessels to the brain. Hemorrhagic strokes result from bleeding caused by the rupture of a weakened blood vessel. In general, hemorrhagic strokes are more severe and more likely to cause death. And what the researchers found was more bad news for speed freaks: “Amphetamine abuse was strongly associated with hemorrhagic stroke, but not with ischemic stroke.” Cocaine abuse was more robustly linked to ischemic strokes. So, it’s not surprising that when it comes to drug and fatal strokes, the clear winner was amphetamine. It’s not entirely clear what causes the difference, but the investigators pointed out that meth injections in lab animals can cause microhemorrhaging, heart attacks, fragmentation of capillary beds, and something called “poor vascular filling.” For cocaine, the culprits are vasoconstriction and disrupted regulation of blood pressure.
More than 14 percent of strokes in hospitals “were accounted for by abuse of drugs,” the researchers wrote. The data showed that for patients with hemorrhagic strokes, “only amphetamine abuse, coagulation defects, and hypertension were strong independent predictors of in-hospital death.”
So what can we conclude? Either the number of speed users in these communities is increasing, or the existing speed communities are using the drug more intensely. Since the rate of increase of speed use was relatively modest during the study years, the researchers concluded that “increased rate in our hospital population is because of the increased intensity of methamphetamine use.” Meaning higher dosages, stronger meth, and more needles.
Sadly, much of this has been known since it least 1990. In that year, research published in the Annals of Internal Medicine, based on a study of stroke victims at San Francisco General Hospital, concluded that “the possibility of serious and sometimes fatal cerebrovascular accidents in people taking potent stimulants and using the intravenous route of administration is not as widely known as it needs to be.”
About 800,000 people in the U.S. suffer a stroke each year, according to figures from the U.S. Centers for Disease Control and Prevention. Strokes are considered America’s leading cause of serious long-term disability.
de los Rios F., Kleindorfer D.O., Khoury J., Broderick J.P., Moomaw C.J., Adeoye O., Flaherty M.L., Khatri P., Woo D. & Alwell K.; (2012). Trends in Substance Abuse Preceding Stroke Among Young Adults: A Population-Based Study, Stroke, 43 (12) 3179-3183. DOI: 10.1161/STROKEAHA.112.667808
Labels:
amphetamine,
crank,
meth,
methamphetamine,
stroke,
strokes,
strokes and speed
Tuesday, August 6, 2013
Methamphetamine: An Excerpt
There’s more than one kind of monster.
Type and I pass the pipe. The overhead light flickers and the wind picks up even more. It’s coming from the north because with each exhale, the smoke slips past my face, back toward the Twin Cities and my dead parents.
But for a brief moment, I’m not thinking about all that. I’m feeling the closest thing I can think of to God and he’s playing the samba inside of my body, his fingers gentle, as they press on the backs of my retinas, my spine, the tendons along my hip flexors. I’m thinking that I love drugs more than anything. That they are the one and only constant in my life. Yeah, they demand a lot of attention and effort, but their love is legendary, their compassion endless. I hold each hit for hours, exhale for decades. The determination that comes with the onset of a high rushes back and I’m all about conquering the world and making money and finding happiness in the form of a loving woman who knows when it’s time to brush the backs of her nails across my cheek and then I’m thinking about this being the same thing as what God is doing to me now.
I love it when my heart rattles against my uvula.
I love it when my vision is a camera shutter.
I love it when I know that someday, I will do great things.
I love it when methamphetamines make things okay.
But I don’t love it when I start to hallucinate because the line between knowing it’s only the drugs and knowing your psyche is about to snap the fuck apart like a high wire is oh so delicate....
—From Fiend, a novel by Peter Stenson
Tuesday, June 26, 2012
The New Highs: Are Bath Salts Addictive?
Part II.
Call bath salts a new trend, if you insist. Do they cause psychosis? Are they “super-LSD?” The truth is, they are a continuation of a 70-year old trend: speed. Lately, we’ve been fretting about the Adderall Generation, but every population cohort has had its own confrontation with the pleasures and perils of speed: Ritalin, ice, Methedrine, crystal meth, IV meth, amphetamine, Dexedrine, Benzedrine… and so it goes. For addicts: Speed kills. Those two words were found all over posters in the Haight Ashbury district of San Francisco, a few years too late to do the residents much good.
While the matter of the addictiveness of Spice and other synthetic cannabis products remains open to question, there no longer seems to be much doubt about the stimulant drugs known collectively as bath salts. To a greater or lesser degree, these off-the-shelf synthetic stimulants appear to be potentially addictive. And that’s not good news for anyone.
Last week, the U.S. Congress added 26 additional synthetic chemicals to the Controlled Substances Act, including the designer stimulants mephedrone and MDPV, at the behest of the Drug Enforcement Administration. Mephedrone and MDPV are cathinones, sold as bath salts or plant food, and chemically similar to amphetamine and ephedrine. (Methcathinone, often called MCAT, is to cathinone as methamphetamine is to amphetamine)
The research news on bath salts at the annual meeting of the College on Problems of Drug Dependence (CPDD) in Palm Springs recently was complex and confusing. For example, the phemonenon of overheating, or hyperthermia, that plagues ravers on MDMA and sends some of them to the hospital is a function of certain temperature-sensitive effects of Ecstasy. But it is not as much of a problem with MDPV and mephedrone. The bath salts, like meth, don’t seem to cause overheating as readily.
On another front, William Fantegrossi, assistant professor in the Department of Pharmacology and Toxicology at the University of Arkansas for Medical Sciences, told the panel audience that at very high doses and very high temperatures, stimulants like Ecstasy and MDPV “can cause self-mutilation in animals.” Fantegrossi’s statement was the closest anybody has come to providing a possible scientific basis for popular press accounts linking bath salts to flesh-eating frenzies by psychotic users. But this remains speculative, as there are still no reliable toxicological findings available in such cases.
The symposium on bath salts at the CPDD played to a packed conference hall, a sure sign that professional scientists who study addiction for a living were interested in the subject. The panel was titled “A Stimulating Soak in ‘Bath Salts’: Investigating Cathinone Derivative Drugs,” and was co-chaired by Dr. Michael Taffe of the Scripps Research Institute in La Jolla, CA, and pharmacology professor Dr. Annette Fleckenstein of the University of Utah.
Fantegrossi characterized the overall problem of designer stimulants as “dirty pharmacology” on both sides, pointing to the desperate efforts underway by government-funded scientists to “throw antagonists [blocking drugs] at these things.”
Alexander Shulgin, the grandfather of the modern psychedelic movement, popularized MDMA and hundreds of variants in his backyard laboratory in the Bay Area over the years. Shulgin, better than anyone, knew that legitimate research and dirty recreational chemistry are only a molecule away. In their book Pihkal: A Chemical Love Story, Alexander Shulgin and his wife Ana recall that cartoonist Gary Trudeau captured the truth of the situation as far back as 1985, when the MDMA story became front-page news:
Way back in mid-1985, the cartoonist-author of Doonesbury, Gary Trudeau, did a two-week feature on it, playing it humorous, and almost (but not quite) straight, in a hilarious sequence of twelve strips. On August 19, 1985 he had Duke, president of Baby Doc College, introduce the drug design team from USC in the form of two brilliant twins, Drs. Albie and Bunny Gorp. They vividly demonstrated to the enthusiastic conference that their new drug "Intensity" was simply MDMA with one of the two oxygens removed. "Voila," said one of them, with a molecular model in his hands, "Legal as sea salt."
Jeffrey Moran of the Arkansas Department of Health noted that despite the cat-and-mouse game continuously played between illegal drug designers and the law, government bans on mephedrone and MDPV, the two most common forms of designer stimulant, cause only temporary downturns in supply. They are no longer as legal as sea salt, but it doesn’t seem to matter. There are always new ones in the pipeline. Moran told the audience that at least 48 different compounds had been identified in more than 200 distinct bath salt-style products in his state alone. Sorting out the specific chemistry involves specialized assays designed to detect a bewildering array of molecules: methylone, mephedrone, paphyrone, butylone, 4-MEC, alpha-PVP, and a host of others, some old, some new, some reimagined by underground chemists.
Terry Boos of the U.S. Drug Enforcement Agency explained that most designer stimulants currently in play are not manufactured stateside. Most originate in Asia and arrive through various ports of call, where they are repackaged for sale in the U.S. Purity of the cathinone ranges from 30 to 95 per cent, Boos said.
Annette Fleckenstein of the University of Utah emphasized that scientists shouldn’t be fooled by overall structural similarities among such drugs as meth, mephedrone, MDMA, and MDPV. In a 2011 study published with her colleagues at the University of Utah, Fleckenstein lamented that mephedrone’s recent emergence on the drug scene had exposed the fact that “there are no formal pharmacodynamic or pharmacokinetic studies of mephedrone.”
But she has managed to show that methamphetamine causes lasting decreases in serotonin functions, as well as the better-known dopamine alterations, and that MDMA and mephedrone are intimately involved in the accumulation of serotonin in the brain’s nucleus accumbens, where addictive drugs produce many of their rewarding effects. “Rats will self-administer mephedrone,” said Fleckenstein—always a troubling clue that the drug in question may have addictive properties. Since the high in humans only last for three to six hours, there is a tendency to reinforce the behavior through repeated dosings.
Other behavioral clues have been teased out of rat studies. The Taffe Laboratory at Scripps Research Institute has focused on the cognitive, thermoregulatory, and potentially addictive effects of the cathinones. Rats will self-administer mephedrone, MDPV, and of course methamphetamine. However, Dr. Taffe told the audience that MDMA does not produce these classic locomotor stimulant effects at low doses and that it is “more difficult to get them to self-administer” Ecstasy. Nonetheless, Taffe told me he believes that MDMA is, in fact, potentially addictive. “Our data suggest that MDPV is highly reinforcing,” Taffe said in an email exchange after the conference, “and at least as readily self-administered as methamphetamine, at approximately the same per-infusion doses. But it is a very complicated story.”
Scripps researchers have carried the investigation forward with a new study, currently in press at the journal Drug and Alcohol Dependence. Pai-Kai Huang and coworkers studied the differing effects of designer stimulants on voluntary wheel-running activity in rats, adding additional evidence to the basic behavioral split among club drugs of the moment. Taffe, one of the study’s co-authors, said the researchers had predicted that the two drugs with the strongest serotonin activity—MDMA and the mephedrone variants—would decrease wheel running activity in the rats. Methedrine and MDPV, they predicted, would increase activity.
And that’s how it turned out. What that means for human users is still not entirely clear. But MDPV in particular, it now seems evident, has some rather direct and disturbing affinities with crystal meth and cocaine. And the vagaries of the market have led to sharp increases in the percentage of MDPV found in bath salt products in the last two years. Are we seeing the wholesale replacement of MDMA by a more directly addictive, methedrine-like drug? Will we see a rise in psychotic symptoms, and increased visits to the ER, as MDPV becomes more common in bath salts? Ecstasy has been implicated in the death of users as well, but will the surge in cathinone drugs mean there will be additional deaths?
And remember: Researchers are able to distinguish between rats under the influence of either MDMA- or MDPV-based wheel activity—but the research suggests that under blinded conditions, human users aren’t very good at guessing which of those two drugs they’re on. Furthermore, we don’t have the data to say whether users can tell mephedrone from MDPV in a blind test. And even wheel-running rats don’t give away whether they’re running on MDMA or mephedrone. These categorical distinctions are all-important, but still in relative infancy as far as street use is concerned.
The Scripps scientists concluded that their study “underlines the error of assuming all novel cathinone derivative stimulants that become popular with recreational users will share neuropharmacological or biobehavioral properties.” Some of the combinations produce a “unique constellation of desired effects.”
But by 2011, the U.S. media had conflated mephedrone with MDPV and half a dozen other substances, all with differing effects on users. For public health officials, it was a nightmare.
“We know that MDMA users follow the science,” Taffe said, at the close of the bath salts panel. “So information we make available can have a direct effect on public health for those people.” But for bath salt users, the picture is not as clear. Consider, once again, Arkansas’ finding of 30 or 40 different cathinone derivatives, part of a set of 250 distinct chemicals identified in different combinations of bath salt products. “Slight modifications can change the toxicities,” Taffe said. “Abuse liabilities differ between MDMA and different cathinones. They all confer different health risks.”
One of the primary drivers of bath salt usage appears to be the desire to finesse drug-testing programs. And if drug-testing programs are pushing people in the direction of more dangerous, unfamiliar, and addictive substances, then perhaps drug testing is part of the problem rather than the solution.
In the short run, emergency treatment of patients with OD symptoms they attribute to bath salts will remain the same, whether the cathinone in question is mephedrone, MDPV, or some other variant. General emergency-department procedures for stimulant intoxication are standardized. People can suffer cardiac arrest from either MDMA or meth. And people can run very high temperatures with overdoses of any of these stimulants.
Are users listening? Do they believe any of the health warnings this time out, or have there been too many over the years, always strident and hysterical and overinflated?
Huang PK, Aarde SM, Angrish D, Houseknecht KL, Dickerson TJ, & Taffe MA (2012). Contrasting effects of d-methamphetamine, 3,4-methylenedioxymethamphetamine, 3,4-methylenedioxypyrovalerone, and 4-methylmethcathinone on wheel activity in rats. Drug and alcohol dependence PMID: 22664136
Hadlock GC, Webb KM, McFadden LM, Chu PW, Ellis JD, Allen SC, Andrenyak DM, Vieira-Brock PL, German CL, Conrad KM, Hoonakker AJ, Gibb JW, Wilkins DG, Hanson GR, & Fleckenstein AE (2011). 4-Methylmethcathinone (mephedrone): neuropharmacological effects of a designer stimulant of abuse. The Journal of pharmacology and experimental therapeutics, 339 (2), 530-6 PMID: 21810934
Labels:
4-MMC,
bath salts,
cathinones,
designer stimulant,
MDMA,
MDPV,
mephedrone,
meth,
methamphetamine
Wednesday, October 5, 2011
Bath Salts, Graphically
What you need to know about mephedrone.
The Pat Moore Foundation has put together this nifty chart as a primer on mephedrone, the amphetamine-type stimulant marketed as "bath salts." Thanks PMF!
Created by Pat Moore Foundation
The Pat Moore Foundation has put together this nifty chart as a primer on mephedrone, the amphetamine-type stimulant marketed as "bath salts." Thanks PMF!
Created by Pat Moore Foundation
Friday, April 22, 2011
Let’s Get Cellular: Meth Metabolism
Speedy fruit flies metabolize glucose differently.
We know from the work of Nora Volkow and others that meth abusers have chronically low levels of dopamine D2 receptors in their brains. But what is going on in the rest of the body when methamphetamine addiction is running full force? A study of meth-crazed fruit flies, just published at PLoS ONE by researchers at the University of Illinois, Purdue, and elsewhere, took a whole-body approach, tracing the meth-induced cascade of chemical reactions wherever they found it. Most drug research in animal models concentrates on changes in the brain. But this study was looking elsewhere, for changes caused by meth and evidenced along common metabolic pathways. They found that meth exposure had striking effects on insect molecular pathways associated with “energy generation, sugar metabolism, sperm cell formation, cell structure, hormones, skeletal muscle and cardiac muscles.” In other words—and no secret here—speed impacts aging, sexual behavior and cardiovascular health. But how, exactly?
The administration of methamphetamine to Drosophilia melanogaster—a fruit fly with one of the most studies genotypes in history—causes changes in the way certain genes and proteins are expressed. Some of the changes might hold for human users, as well:
-- Meth dysregulates calcium and iron homeostasis.
-- Meth inhibits something called ETC—the mitochondrial electron transport chain. This causes changes in proteins and reduced enzyme activity that, among other things, has been known to make bees more aggressive.
-- Meth alters peptides related to chronic heart failure in humans. The researchers observed that “concentrations of numerous muscle-associated proteins changed in response to METH exposure.”
-- Meth causes various sexual dysfunctions in man and animal, including inhibited sperm motility. Some of the changes in fruit flies caused by meth involved genes known to control sperm maturation. Altogether, the team identified seven meth-responsive genes and proteins associated with male reproductive functions.
-- Meth also caused changes “in whole organism sugar levels” in the fruit flies. Using gas chromatography/mass spectrometry technology, researchers observed decreased levels of trehalose, the primary form of blood sugar in insects. This could reflect “either higher metabolic rates resulting from a METH-induced increase in physical activity or increased carbohydrate consumption resulting from increased glycolysis…. Interestingly, human METH addicts often imbibe large amounts of sugary soft drinks; such dietary studies in Drosophilia lead us to question whether sugar intake in humans helps to alleviate the toxic effects of METH.”
-- “METH impacts pathways associated with hypoxia and/or the Warburg effect, pathways in which cellular energy is predominantly produced by glycolysis rather than by oxidative respiration.” Short version: The Warburg effect is associated with the aberrant energy metabolism characteristic of cancer cells. This certainly doesn’t mean we can conclude that speed causes cancer, but it is one more piece of evidence confirming the notion that methamphetamine’s range of potentially damaging side effects is simply too high to justify. We can argue the merits of legalizing marijuana, but no one who studies meth seriously has ever suggested legalization of this pernicious substance.
Professor Barry Pittendrigh of the University of Illinois, a member of the study team, said: “One could almost call meth a perfect storm toxin because it does so much damage to so many different tissues in the body.”
Sun, L., Li, H., Seufferheld, M., Walters, K., Margam, V., Jannasch, A., Diaz, N., Riley, C., Sun, W., Li, Y., Muir, W., Xie, J., Wu, J., Zhang, F., Chen, J., Barker, E., Adamec, J., & Pittendrigh, B. (2011). Systems-Scale Analysis Reveals Pathways Involved in Cellular Response to Methamphetamine PLoS ONE, 6 (4) DOI: 10.1371/journal.pone.0018215
Labels:
meth,
methamphetamine addiction,
methampthetamine
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