sábado, 15 de junho de 2019

Gut microbes eat our medication

Date: June 13, 2019 Source: Harvard University Summary: Researchers have discovered one of the first concrete examples of how the microbiome can interfere with a drug's intended path through the body. Focusing on levodopa (L-dopa), the primary treatment for Parkinson's disease, they identified which bacteria out of the trillions of species is responsible for degrading the drug and how to stop this microbial interference.

son's disease, they identified which bacteria out of the trillions of species is responsible for degrading the drug and how to stop this microbial interference.
Pills illustration (stock image).
Credit: © georgejmclittle / Adobe Stock

The first time Vayu Maini Rekdal manipulated microbes, he made a decent sourdough bread. At the time, young Maini Rekdal, and most people who head to the kitchen to whip up a salad dressing, pop popcorn, ferment vegetables, or caramelize onions, did not consider the crucial chemical reactions behind these concoctions.


Even more crucial are the reactions that happen after the plates are clean. When a slice of sourdough travels through the digestive system, the trillions of microbes that live in our gut help the body break down that bread to absorb the nutrients. Since the human body cannot digest certain substances -- all-important fiber, for example -- microbes step up to perform chemistry no human can.

"But this kind of microbial metabolism can also be detrimental," said Maini Rekdal, a graduate student in the lab of Professor Emily Balskus and first-author on their new study published in Science. According to Maini Rekdal, gut microbes can chew up medications, too, often with hazardous side effects. "Maybe the drug is not going to reach its target in the body, maybe it's going to be toxic all of a sudden, maybe it's going to be less helpful," Maini Rekdal said.

In their study, Balskus, Maini Rekdal, and their collaborators at the University of California San Francisco, describe one of the first concrete examples of how the microbiome can interfere with a drug's intended path through the body. Focusing on levodopa (L-dopa), the primary treatment for Parkinson's disease, they identified which bacteria are responsible for degrading the drug and how to stop this microbial interference.

Parkinson's disease attacks nerve cells in the brain that produce dopamine, without which the body can suffer tremors, muscle rigidity, and problems with balance and coordination. L-dopa delivers dopamine to the brain to relieve symptoms. But only about 1 to 5% of the drug actually reaches the brain.

This number -- and the drug's efficacy -- varies widely from patient to patient. Since the introduction of L-dopa in the late 1960s, researchers have known that the body's enzymes (tools that perform necessary chemistry) can break down L-dopa in the gut, preventing the drug from reaching the brain. So, the pharmaceutical industry introduced a new drug, carbidopa, to block unwanted L-dopa metabolism. Taken together, the treatment seemed to work.

"Even so," Maini Rekdal said, "there's a lot of metabolism that's unexplained, and it's very variable between people." That variance is a problem: Not only is the drug less effective for some patients, but when L-dopa is transformed into dopamine outside the brain, the compound can cause side effects, including severe gastrointestinal distress and cardiac arrhythmias. If less of the drug reaches the brain, patients are often given more to manage their symptoms, potentially exacerbating these side effects.

Maini Rekdal suspected microbes might be behind the L-dopa disappearance. Since previous research showed that antibiotics improve a patient's response to L-dopa, scientists speculated that bacteria might be to blame. Still, no one identified which bacterial species might be culpable or how and why they eat the drug.

So, the Balskus team launched an investigation. The unusual chemistry -- L-dopa to dopamine -- was their first clue.

Few bacterial enzymes can perform this conversion. But, a good number bind to tyrosine -- an amino acid similar to L-dopa. And one, from a food microbe often found in milk and pickles (Lactobacillus brevis), can accept both tyrosine and L-dopa.

Using the Human Microbiome Project as a reference, Maini Rekdal and his team hunted through bacterial DNA to identify which gut microbes had genes to encode a similar enzyme. Several fit their criteria; but only one strain, Enterococcus faecalis (E. faecalis), ate all the L-dopa, every time.

With this discovery, the team provided the first strong evidence connecting E. faecalis and the bacteria's enzyme (PLP-dependent tyrosine decarboxylase or TyrDC) to L-dopa metabolism.

And yet, a human enzyme can and does convert L-dopa to dopamine in the gut, the same reaction carbidopa is designed to stop. Then why, the team wondered, does the E. faecalis enzyme escape carbidopa's reach?

Even though the human and bacterial enzymes perform the exact same chemical reaction, the bacterial one looks just a little different. Maini Rekdal speculated that carbidopa may not be able to penetrate the microbial cells or the slight structural variance could prevent the drug from interacting with the bacterial enzyme. If true, other host-targeted treatments may be just as ineffective as carbidopa against similar microbial machinations.

But the cause may not matter. Balskus and her team already discovered a molecule capable of inhibiting the bacterial enzyme.

"The molecule turns off this unwanted bacterial metabolism without killing the bacteria; it's just targeting a non-essential enzyme," Maini Rekdal said. This and similar compounds could provide a starting place for the development of new drugs to improve L-dopa therapy for Parkinson's patients.

The team might have stopped there. But instead, they pushed further to unravel a second step in the microbial metabolism of L-dopa. After E. faecalis converts the drug into dopamine, a second organism converts dopamine into another compound, meta-tyramine.

To find this second organism, Maini Rekdal left behind his mother dough's microbial masses to experiment with a fecal sample. He subjected its diverse microbial community to a Darwinian game, feeding dopamine to hordes of microbes to see which prospered.

Eggerthella lenta won. These bacteria consume dopamine, producing meta-tyramine as a by-product. This kind of reaction is challenging, even for chemists. "There's no way to do it on the bench top," Maini Rekdal said, "and previously no enzymes were known that did this exact reaction."

The meta-tyramine by-product may contribute to some of the noxious L-dopa side effects; more research needs to be done. But, apart from the implications for Parkinson's patients, E. lenta's novel chemistry raises more questions: Why would bacteria adapt to use dopamine, which is typically associated with the brain? What else can gut microbes do? And does this chemistry impact our health?

"All of this suggests that gut microbes may contribute to the dramatic variability that is observed in side effects and efficacy between different patients taking L-dopa," Balskus said.

But this microbial interference may not be limited to L-dopa and Parkinson's disease. Their study could shepherd additional work to discover exactly who is in our gut, what they can do, and how they can impact our health, for better or worse.

Story Source:

Materials provided by Harvard University. Original written by Caitlin McDermott-Murphy. Note: Content may be edited for style and length.

Journal Reference:
Vayu Maini Rekdal, Elizabeth N. Bess, Jordan E. Bisanz, Peter J. Turnbaugh, Emily P. Balskus. Discovery and inhibition of an interspecies gut bacterial pathway for Levodopa metabolism. Science, 2019; 364 (6445): eaau6323 DOI: 10.1126/science.aau6323

Cite This Page:
Harvard University. "Gut microbes eat our medication." ScienceDaily. ScienceDaily, 13 June 2019. <www.sciencedaily.com/releases/2019/06/190613143629.htm>.

HORTO DE PLANTAS MEDICINAIS DO ESF NAZARÉ

Projeto: Canteiro de Plantas Medicinais IFB- CAMPUS PLANALTINA TURMA AP...

ESF Rodrigues dispõe de horta com plantas medicinais

sexta-feira, 14 de junho de 2019

Lowering cholesterol is not enough to reduce hyperactivity of the immune system

Date: June 13, 2019 Source: Radboud University Medical Center Summary: Despite treatment with statins, many patients with elevated cholesterol levels will still develop cardiovascular disease. It is apparent that not only cholesterol but also the immune system plays an important role in the development of atherosclerosis. Researchers now provide a novel potential explanation for this residual cardiovascular risk, related to persistent activation of the immune system in patients with hypercholesterolemia who are treated with statins.


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quinta-feira, 13 de junho de 2019

Boldo (Peumus boldus)

Self-pollination in a flower of Vanilla (Autopolinização em Vanilla)

Verifying 'organic' foods

Date: June 5, 2019 Source: American Chemical Society Summary: Organic foods are increasingly popular -- and pricey. Organic fruits and vegetables are grown without synthetic pesticides, and because of that, they are often perceived to be more healthful than those grown with these substances. But not all foods with this label are fully pesticide free, and it can be challenging to detect low amounts of the substances. Now scientists report a new strategy to determine organic authenticity.Share:

Organic foods are increasingly popular -- and pricey. Organic fruits and vegetables are grown without synthetic pesticides, and because of that, they are often perceived to be more healthful than those grown with these substances. But not all foods with this label are fully pesticide free, and it can be challenging to detect low amounts of the substances. Now, scientists report in ACS' Journal of Agricultural and Food Chemistry a new strategy to determine organic authenticity.

The high cost and popularity of organic foods can be an incentive to try to pass off pesticide-treated foods as organic. Pesticide detection can be challenging, or even impossible, especially because some of these substances break down rapidly after being applied, leading to a false impression that a food has not been treated. However, a bit of pesticide on the surface of a fruit doesn't necessarily signal intentional fraud. The compound might have just blown over from a neighboring field. To help improve the practice of verifying organic foods, Jana Hajslova and colleagues developed a method to analyze the metabolites generated within plants when pesticides break down, using an experimental vineyard as their testing ground.

The researchers used a combination of ultra-high-performance liquid chromatography and high-resolution mass spectrometry to identify and screen the metabolites of seven common pesticides. The team then used the method on the leaves and fruits of treated grapevines at different intervals between planting and harvest, as well as the wine made from the treated fruits. With the technique, the team observed decreasing levels of the initial pesticides as degradation occurred. The group also detected the metabolites of these substances as their levels varied over time. Many metabolites were still detectable at higher levels than the applied pesticide compound in wine made from the treated fruits, meaning that organic wines, not just fruits and leaves, could potentially be verified using the strategy. The researchers say that their methodology, with some refinement, should aid in food regulators' efforts to crack down on illegal practices in organic farming.

Story Source:

Materials provided by American Chemical Society. Note: Content may be edited for style and length.

Journal Reference:
Dana Schusterova, Marie Suchanova, Jana Pulkrabova, Vladimir Kocourek, Jiri Urban, Jana Hajslova. Can Occurrence of Pesticide Metabolites Detected in Crops Provide the Evidence on Illegal Practices in Organic Farming? Journal of Agricultural and Food Chemistry, 2019; DOI: 10.1021/acs.jafc.8b06999

Cite This Page:
American Chemical Society. "Verifying 'organic' foods." ScienceDaily. ScienceDaily, 5 June 2019. <www.sciencedaily.com/releases/2019/06/190605105949.htm>.

Guia Alimentar Plantas Ruderais: O mato que alimenta, protege e embeleza o meio ambiente


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Mathematics of plant leaves

Unusual Japanese plant inspires recalculation of equation used to model leaf arrangement patterns

Date: June 6, 2019 Source: University of Tokyo Summary: A Japanese plant species with a peculiar leaf pattern recently revealed unexpected insight into how almost all plants control their leaf arrangement.Share:

Leaves can be enjoyed for their shade, autumn colors, or taste, and the arrangement of leaves on a plant is a practical way to identify a species. However, the details of how plants control their leaf arrangement have remained a persistent mystery in botany. A Japanese plant species with a peculiar leaf pattern recently revealed unexpected insight into how almost all plants control their leaf arrangement.

"We developed the new model to explain one peculiar leaf arrangement pattern. But in fact, it more accurately reflects not only the nature of one specific plant, but the range of diversity of almost all leaf arrangement patterns observed in nature," said Associate Professor Munetaka Sugiyama from the University of Tokyo's Koishikawa Botanical Garden.

All in the angles

To identify the leaf arrangement of a plant species, botanists measure the angle between leaves, moving up the stem from oldest to youngest leaf.

Common patterns are symmetrical and have leaves arranged at regular intervals of 90 degrees (basil or mint), 180 degrees (stem grasses, like bamboo), or in Fibonacci golden angle spirals (like the needles on some spherical cacti, or the succulent spiral aloe).

The peculiar pattern that Sugiyama's research team studied is called "orixate" after the species Orixa japonica, a shrub native to Japan, China, and the Korean peninsula. O. Japonica is sometimes used as a hedge.

The angles between O. Japonica leaves are 180 degrees, 90 degrees, 180 degrees, 270 degrees, and then the next leaf resets the pattern to 180 degrees.

"Our research has the potential to truly understand beautiful patterns in nature," said Sugiyama.

The math of a plant

Sugiyama's research team began their investigation by doing exhaustive testing of the existing mathematical equation used to model leaf arrangement.

Leaf arrangement has been modeled mathematically since 1996 using an equation known as the DC2 (Douady and Couder 2). The equation can generate many, but not all, leaf arrangement patterns observed in nature by changing the value of different variables of plant physiology, such as the relationships between different plant organs or strength of chemical signals within the plant.

The DC2 has two shortcomings that researchers wanted to address:
No matter what values are put into the DC2 equation, certain uncommon leaf arrangement patterns are never calculated.
The Fibonacci spiral leaf arrangement pattern is by far the most common spiral pattern observed in nature, but is only modestly more common than other spiral patterns calculated by the DC2 equation.

A peculiar pattern

At least four unrelated plant species possess the unusual orixate leaf arrangement pattern. Researchers suspected that it must be possible to create the orixate pattern using the fundamental genetic and cellular machinery shared by all plants because the alternative possibility -- that the same, very unusual leaf arrangement pattern evolved four or more separate times -- seemed too unlikely.

One fundamental assumption used in the DC2 equation is that leaves emit a constant signal to inhibit the growth of other leaves nearby and that the signal gets weaker at longer distances. Researchers suspect that the signal is likely related to the plant hormone auxin, but the exact physiology remains unknown.

Rare patterns and common rules

"We changed this one fundamental assumption -- inhibitory power is not constant, but in fact changes with age. We tested both increasing and decreasing inhibitory power with greater age and saw that the peculiar orixate pattern was calculated when older leaves had a stronger inhibitory effect," said Sugiyama.

This insight into the inhibitory signal power changing with age may be used to direct future studies of the genetics or physiology of plant development.

Researchers call this new version of the equation the EDC2 (Expanded Douady and Couder 2).

First author of the research paper, doctoral student Takaaki Yonekura, designed computer simulations to generate thousands of leaf arrangement patterns calculated by EDC2 and to count how often the same patterns were generated. Patterns that are more commonly observed in nature were more frequently calculated by the EDC2, further supporting the accuracy of the ideas used to create the formula.

"There are other very unusual leaf arrangement patterns that are still not explained by our new formula. We are now trying to design a new concept that can explain all known patterns of leaf arrangement, not just almost all patterns," said Sugiyama.

Do it yourself -- ID the pattern

Experts recommend looking at a group of relatively new leaves when identifying a plant's leaf arrangement, or phyllotaxis, pattern. (In Greek, phyllon means leaf.) Older leaves may have turned (due to wind or sun exposure), which can make it difficult to identify their true angle of attachment to the stem.

Think of the stem as a circle and begin by carefully observing where on the circle the oldest and second-oldest leaves are attached. The angle between those two leaves is the first "angle of divergence." Continue identifying the angles of divergence between increasingly younger leaves on the stem. The pattern of angles of divergence is the leaf arrangement pattern.

Common leaf arrangement patterns are distichous (regular 180 degrees, bamboo), Fibonacci spiral (regular 137.5 degrees, the succulent Graptopetalum paraguayense), decussate (regular 90 degrees, the herb basil), and tricussate (regular 60 degrees, Nerium oleander sometimes known as dogbane).

Story Source:

Materials provided by University of Tokyo. Note: Content may be edited for style and length.

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Journal Reference:
Takaaki Yonekura, Akitoshi Iwamoto, Hironori Fujita, Munetaka Sugiyama. Mathematical model studies of the comprehensive generation of major and minor phyllotactic patterns in plants with a predominant focus on orixate phyllotaxis. PLOS Computational Biology, 2019; 15 (6): e1007044 DOI: 10.1371/journal.pcbi.1007044

Cite This Page:
University of Tokyo. "Mathematics of plant leaves: Unusual Japanese plant inspires recalculation of equation used to model leaf arrangement patterns." ScienceDaily. ScienceDaily, 6 June 2019. <www.sciencedaily.com/releases/2019/06/190606150226.htm>.

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Medical marijuana does not reduce opioid deaths

Date: June 10, 2019 Source: Stanford Medicine Summary: Legalizing medical marijuana does not reduce the rate of fatal opioid overdoses, according to researchers.

Legalizing medical marijuana does not reduce the rate of fatal opioid overdoses, according to researchers at the Stanford University School of Medicine.

The finding contradicts a 2014 study that legal-pot advocates, public officials and even physicians have touted as a reason to legalize marijuana. That study found lower rates of fatal opioid overdoses in the states that had legalized marijuana for medical purposes than in states where marijuana remained illegal.

The Stanford study, which revisited the issue after many more states had legalized medical marijuana, found no evidence of a connection between opioid deaths and the availability of medical cannabis, said Keith Humphreys, PhD, professor of psychiatry and behavioral sciences.

"If you think opening a bunch of dispensaries is going to reduce opioid deaths, you'll be disappointed," Humphreys said. "We don't think cannabis is killing people, but we don't think it's saving people."

A paper describing the new study will be published online June 10 in Proceedings of the National Academy of Sciences. Humphreys is the senior author. The lead author is postdoctoral scholar Chelsea Shover, PhD.

Medical pot now legal in 47 states

In 1996, California became the first state to legalize medical marijuana. By 2010, 13 states, most of them in the West, had legalized medical marijuana. Today, 47 states permit some version of medical pot.

For the new study, the Stanford researchers used the same method employed in the 2014 study to evaluate the connection between legalized medical marijuana and fatal opioid overdoses. They confirmed the findings from the 2014 study, but when they looked at opioid deaths up to 2017 -- by which point most states had legalized some form of medical marijuana, if not recreational marijuana -- they found that the opposite was true: States with legal medical marijuana had a higher rate of deaths due to opioid overdose.

After the 2014 study was released, medical marijuana proponents and some public officials interpreted the results to mean that, given access to legalized pot, people would turn to it rather than opioids for pain relief or recreation. Yet when the Stanford researchers compared states that have more restrictive medical marijuana laws with those that allow recreational marijuana, they found no correlation between opioid overdose mortality and the level of restriction.

"Accounting for different types of laws didn't change the bottom line," Shover said.

Also, given that only 2.5% of the U.S. population uses medical marijuana, it's unlikely that use could affect mortality statistics, the researchers said.

'Something else about those states'

Humphreys said the results of the 2014 study may have reflected policies and conditions in states that legalized medical marijuana early. Those states tended to be wealthier and more politically liberal, with greater access to addiction treatment and to naloxone, which reverses the effects of opioids and can prevent overdose fatalities. The states that legalized pot early also incarcerate fewer people for drug use, Humphreys added. When people are released from prison, where they lack access to drugs and lose tolerance to them, they may try to use the same levels as they did before they were incarcerated, leading to overdose.

The finding of lower death rates "wasn't about the cannabis," Humphreys said. "It was something else about those states."

Humphreys and Shover said they believe that medical marijuana provides benefits and that research into its effectiveness should continue.

"There are valid reasons to pursue medical cannabis policies, but this doesn't seem to be one of them," Shover said. "I urge researchers and policymakers to focus on other ways to reduce mortality due to opioid overdoses."

Story Source:

Materials provided by Stanford Medicine. Note: Content may be edited for style and length.

Journal Reference:
Chelsea L. Shover, Corey S. Davis, Sanford C. Gordon, Keith Humphreys. Association between medical cannabis laws and opioid overdose mortality has reversed over time. Proceedings of the National Academy of Sciences, 2019; 201903434 DOI: 10.1073/pnas.1903434116

Cite This Page:
Stanford Medicine. "Medical marijuana does not reduce opioid deaths." ScienceDaily. ScienceDaily, 10 June 2019. <www.sciencedaily.com/releases/2019/06/190610151933.htm>.

How to Prevent Toxoplasmosis

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Vitamin D and estradiol help guard against heart disease, stroke, and diabetes

New study demonstrates synergistic effects of vitamin D and estradiol deficiency on metabolic syndrome

Date: June 12, 2019

Source: The North American Menopause Society (NAMS)

Summary:
Vitamin D and estrogen have already shown well-documented results in improving bone health in women. A new study suggests that this same combination could help prevent metabolic syndrome, a constellation of conditions that increases the risk of heart disease, stroke, and diabetes in postmenopausal women.

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Origins of cannabis smoking

Evidence from ancient burials at high elevations

Date: June 12, 2019

Source: Max Planck Institute for the Science of Human History Summary: A chemical residue study of incense burners from ancient burials at high elevations in western China has revealed psychoactive cannabinoids. The finding provides some of the earliest evidence for the use of cannabis for its psychoactive compounds.
Cannabis plant (stock image).
Credit: © EpicStockMedia / Adobe Stock

Cannabis has been cultivated as an oil-seed and fibre crop for millennia in East Asia. Little is known, however, about the early use and eventual cultivation of the plant for its psychoactive and medicinal properties. Despite being one of the most widely used psychoactive drugs in the world today, there is little archaeological or historical evidence for the use of marijuana in the ancient world. The current study, published in the journal Science Advances, identified psychoactive compounds preserved in 2,500-year-old funerary incense burners from the Jirzankal Cemetery in the eastern Pamirs. Researchers from the Max Planck Institute for the Science of Human History, the Chinese Academy of Sciences, and the Chinese Academy of Social Sciences have shown that people were selecting plants with higher levels of THC, and burning them as part of mortuary rituals. This is the earliest clear evidence to date of cannabis being used for its psychoactive properties.

Cannabis is one of the most infamous plants on the planet today, especially in light of rapidly changing legislation surrounding its legalisation in Europe and America. Despite the popularity of the plant for its psychoactive properties, very little is known about the earliest use or cultivation of cannabis for its mind-altering effects. Cannabis plants were cultivated in East Asia for their oily seeds and fibre from at least 4000 BC. However, the early cultivated varieties of cannabis, as well as most wild populations, have low levels of THC and other cannabinoid compounds with psychoactive properties. Therefore, it has been a long-standing mystery as to when and where specific varieties of the plant with higher levels of these compounds were first recognized and used by humans. Many historians place the origins of cannabis smoking on the ancient Central Asian steppes, but these arguments rely solely on a passage from a single ancient text from the late first millennium BC, written by the Greek historian Herodotus. Archaeologists have thus long sought to identify concrete evidence for cannabis smoking in Eurasia, but to date, there are few reliable, well-identified and properly dated examples of early cannabis use.

The researchers in the current study uncovered the early cannabis use when they sought to identify the function of ancient wooden burners discovered by archaeologists from the Chinese Academy of Social Sciences, who were excavating in the high mountainous regions of eastern China. The burners were recovered from 2500-year-old tombs in the Pamir mountain range. The international research team used a method called gas chromatography-mass spectrometry to isolate and identify compounds preserved in the burners. To their surprise, the chemical signature of the isolated compounds was an exact match to the chemical signature of cannabis. Moreover, the signature indicated a higher level of THC than is normally found in wild cannabis plants.

The data produced by the research effort, which brought together archaeologists and laboratory scientists from Jena, Germany and Beijing, China, provides clear evidence that ancient people in the Pamir Mountains were burning specific varieties of cannabis that had higher THC levels. The findings corroborate other early evidence for cannabis from burials further north, in the Xinjiang region of China and in the Altai Mountains of Russia. As Nicole Boivin, Director at the Max Planck Institute for the Science of Human History notes, "The findings support the idea that cannabis plants were first used for their psychoactive compounds in the mountainous regions of eastern Central Asia, thereafter spreading to other regions of the world."

Cannabis likely spread across exchange routes along the early Silk Road

The THC-containing residues were extracted from burners from a cemetery known as Jirzankal in the remote Pamir Mountains. Some of the skeletons recovered from the site, situated in modern-day western China, have features that resemble those of contemporaneous peoples further west in Central Asia. Objects found in the burials also appear to link this population to peoples further west in the mountain foothills of Inner Asia. Additionally, stable isotope studies on the human bones from the cemetery show that not all of the people buried there grew up locally.

These data fit with the notion that the high-elevation mountain passes of Central and Eastern Asia played a key role in early trans-Eurasian exchange. Indeed, the Pamir region, today so remote, may once have sat astride a key ancient trade route of the early Silk Road. The Silk Road was at certain times in the past the single most important vector for cultural spread in the ancient world. Robert Spengler, the lead archaeobotanist for the study, also at the Max Planck Institute for the Science of Human History, explains, "The exchange routes of the early Silk Road functioned more like the spokes of a wagon wheel than a long-distance road, placing Central Asia at the heart of the ancient world. Our study implies that knowledge of cannabis smoking and specific high-chemical-producing varieties of the cannabis plant were among the cultural traditions that spread along these exchange routes."

People sought and later cultivated more psychoactive varieties of cannabis for use in burial rituals

Compared to cultivated varieties, wild cannabis plants contain lower levels of THC, one of the psychoactive compounds in cannabis. It is still unclear whether the people buried at Jirzankal actively cultivated cannabis or simply sought out higher THC-producing plants. One theory is that cannabis plants will produce greater quantities of active compounds in response to increased UV radiation and other stressors related to growing at higher elevations. So people roaming the high mountainous regions may have discovered more potent wild plants there, and initiated a new kind of use of the plant.

While modern cannabis is used primarily as a recreational drug or for medical applications, cannabis may have been used rather differently in the past. The evidence from Jirzankal suggests that people were burning cannabis at rituals commemorating the dead. They buried their kin in tombs over which they created circular mounds, stone rings and striped patterns using black and white stones.

Whether cannabis also had other uses in society is unclear, though it seems likely that the plant's ability to treat a variety of illnesses and symptoms was recognized early on. Yimin Yang, researcher at the University of the Chinese Academy of Sciences in Beijing observes, "This study of ancient cannabis use helps us understand early human cultural practices, and speaks to the intuitive human awareness of natural phytochemicals in plants." Dr. Yang has studied ancient organic residues in East Asia for over ten years. He notes that "biomarker analyses open a unique window onto details of ancient plant exploitation and cultural communication that other archaeological methods cannot offer."

Professor Boivin points out that "given the modern political climate surrounding the use of cannabis, archaeological studies like this can help us to understand the origins of contemporary cultural practice and belief structures -- which, in turn, can inform policy." As Dr. Spengler observes, "Modern perspectives on cannabis vary tremendously cross-culturally, but it is clear that the plant has a long history of human use, medicinally, ritually, and recreationally, over countless millennia."

Story Source:

Materials provided by Max Planck Institute for the Science of Human History. Note: Content may be edited for style and length.

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Journal Reference:
Meng Ren, Zihua Tang, Xinhua Wu, Robert Spengler, Hongen Jiang, Yimin Yang, Nicole Boivin. The origins of cannabis smoking: Chemical residue evidence from the first millennium BCE in the Pamirs. Science Advances, 2019; 5 (6): eaaw1391 DOI: 10.1126/sciadv.aaw1391

Cite This Page:
Max Planck Institute for the Science of Human History. "Origins of cannabis smoking: Evidence from ancient burials at high elevations." ScienceDaily. ScienceDaily, 12 June 2019. <www.sciencedaily.com/releases/2019/06/190612165603.htm>.