Different strains and products available

Different strains and products available

Indica, Sativa, and Hybrid Strains

When it comes to exploring the world of cannabis, one of the most important distinctions to understand is between Indica, Sativa, and Hybrid strains. Each type offers a unique set of effects and benefits, making it crucial for consumers to know what they are looking for when selecting a product.


Indica strains are known for their relaxing and sedating properties. They are often used by individuals seeking relief from pain, insomnia, or anxiety. Indica strains typically have higher levels of cannabinoids like THC, which contribute to their calming effects. These strains are best enjoyed in the evening or before bed when you can fully unwind and relax.


On the other hand, Sativa strains are known for their energizing and uplifting effects. They are ideal for daytime use when you need a boost of creativity, focus, or motivation. Sativa strains tend to have higher levels of cannabinoids like CBD, which help promote feelings of alertness and euphoria. These strains are perfect for social gatherings or creative activities that require mental stimulation.


Hybrid strains combine the best of both worlds by blending characteristics from both Indica and Sativa plants. This results in a balanced experience that can offer relaxation without sedation or energy without jitteriness. Hybrid strains can be tailored to suit a variety of needs and preferences, making them a popular choice among consumers looking for a versatile option.


With so many different strains and products available on the market today, it's important to do your research and experiment with different varieties to find what works best for you. Whether you're looking for pain relief, relaxation, creativity, or focus, there is sure to be a strain out there that suits your needs perfectly. So next time you're shopping for cannabis products, keep in mind the differences between Indica, Sativa, and Hybrid strains to make an informed decision that aligns with your desired effects.

Legal regulations for online dispensaries

When it comes to exploring the world of cannabis, there are a variety of options available beyond just smoking flower. Edibles, concentrates, and topicals offer alternative ways to enjoy the benefits of different strains and products.


Edibles are a popular choice for those who prefer not to smoke. These tasty treats come in many forms, from gummies and chocolates to cookies and brownies. Edibles can be a discreet way to consume cannabis, as they often don't have the same strong odor as smoking. They also provide a longer-lasting high compared to smoking, making them a favorite among those looking for a more sustained experience.


Concentrates are another option for those seeking potent effects. These highly concentrated forms of cannabis come in various forms such as wax, shatter, and oils. Concentrates are known for their high THC content, which can lead to intense effects that may not be suitable for beginners. However, experienced users often appreciate the potency and quick onset of concentrates for a powerful high.


Topicals offer a unique way to enjoy the benefits of cannabis without experiencing psychoactive effects. These products include lotions, balms, and oils that can be applied directly to the skin for localized relief from pain or inflammation. Topicals are popular among medical marijuana patients seeking targeted relief without feeling "high."


Overall, exploring edibles, concentrates, and topicals can provide cannabis enthusiasts with new ways to experience different strains and products. Whether you're looking for a discreet option like edibles, a potent high from concentrates, or targeted relief with topicals – there's something for everyone in the world of alternative cannabis consumption.

THC and CBD Ratios

THC and CBD ratios play a crucial role in determining the effects of different strains and products available in the market. THC (Tetrahydrocannabinol) is the psychoactive compound that produces a "high" feeling, while CBD (Cannabidiol) is known for its therapeutic benefits without any psychoactive effects.


Various strains and products have different ratios of THC to CBD, which can significantly impact their effects on the body. For example, strains with high THC content are more likely to produce strong psychoactive effects, while those with high CBD content are known for their calming and anti-anxiety properties.


Finding the right balance of THC and CBD ratios is essential for individuals looking to achieve specific benefits from cannabis products. Some may prefer a higher THC ratio for recreational purposes, while others may opt for a higher CBD ratio for medicinal use.


It's important for consumers to understand the THC and CBD ratios in different strains and products to make informed decisions about their cannabis consumption. By considering these ratios, individuals can tailor their experience based on their desired effects, whether it be relaxation, pain relief, or simply enjoying the euphoric sensations that cannabis has to offer.

This article is about the plant genus. For therapeutic use, see Medical cannabis. For the psychoactive drug, see Cannabis (drug). For other uses, see Cannabis (disambiguation).

 

Cannabis
Temporal range: Early Miocene – Present 19.6–0 Ma
Common hemp
Scientific classification Edit this classification
Kingdom: Plantae
Clade: Tracheophytes
Clade: Angiosperms
Clade: Eudicots
Clade: Rosids
Order: Rosales
Family: Cannabaceae
Genus: Cannabis
L.
Species[1]
Part of a series on
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Cannabis (/ˈkænÉ™bɪs/ ⓘ)[2] is a genus of flowering plants in the family Cannabaceae that is widely accepted as being indigenous to and originating from the continent of Asia.[3][4][5] However, the number of species is disputed, with as many as three species being recognized: Cannabis sativa, C. indica, and C. ruderalis. Alternatively, C. ruderalis may be included within C. sativa, or all three may be treated as subspecies of C. sativa,[1][6][7][8] or C. sativa may be accepted as a single undivided species.[9]

The plant is also known as hemp, although this term is usually used to refer only to varieties cultivated for non-drug use. Hemp has long been used for fibre, seeds and their oils, leaves for use as vegetables, and juice. Industrial hemp textile products are made from cannabis plants selected to produce an abundance of fibre.

Cannabis also has a long history of being used for medicinal purposes, and as a recreational drug known by several slang terms, such as marijuana, pot or weed. Various cannabis strains have been bred, often selectively to produce high or low levels of tetrahydrocannabinol (THC), a cannabinoid and the plant's principal psychoactive constituent. Compounds such as hashish and hash oil are extracted from the plant.[10] More recently, there has been interest in other cannabinoids like cannabidiol (CBD), cannabigerol (CBG), and cannabinol (CBN).

Etymology

[edit]
Main article: Etymology of cannabis

Cannabis is a Scythian word.[11][12][13] The ancient Greeks learned of the use of cannabis by observing Scythian funerals, during which cannabis was consumed.[12] In Akkadian, cannabis was known as qunubu (𐎯𐎫𐎠𐎭𐏂).[12] The word was adopted in to the Hebrew language as qaneh bosem (קָנֶה בֹּשׂם).[12]

Description

[edit]
Cannabis growing as weeds at the foot of Dhaulagiri, Nepal
A thicket of wild cannabis in Islamabad, Pakistan

Cannabis is an annual, dioecious, flowering herb. The leaves are palmately compound or digitate, with serrate leaflets.[14] The first pair of leaves usually have a single leaflet, the number gradually increasing up to a maximum of about thirteen leaflets per leaf (usually seven or nine), depending on variety and growing conditions. At the top of a flowering plant, this number again diminishes to a single leaflet per leaf. The lower leaf pairs usually occur in an opposite leaf arrangement and the upper leaf pairs in an alternate arrangement on the main stem of a mature plant.

The leaves have a peculiar and diagnostic venation pattern (which varies slightly among varieties) that allows for easy identification of Cannabis leaves from unrelated species with similar leaves. As is common in serrated leaves, each serration has a central vein extending to its tip, but in Cannabis this originates from lower down the central vein of the leaflet, typically opposite to the position of the second notch down. This means that on its way from the midrib of the leaflet to the point of the serration, the vein serving the tip of the serration passes close by the intervening notch. Sometimes the vein will pass tangentially to the notch, but often will pass by at a small distance; when the latter happens a spur vein (or occasionally two) branches off and joins the leaf margin at the deepest point of the notch. Tiny samples of Cannabis also can be identified with precision by microscopic examination of leaf cells and similar features, requiring special equipment and expertise.[15]

Reproduction

[edit]

All known strains of Cannabis are wind-pollinated[16] and the fruit is an achene.[17] Most strains of Cannabis are short day plants,[16] with the possible exception of C. sativa subsp. sativa var. spontanea (= C. ruderalis), which is commonly described as "auto-flowering" and may be day-neutral.

Cannabis is predominantly dioecious,[16][18] having imperfect flowers, with staminate "male" and pistillate "female" flowers occurring on separate plants.[19] "At a very early period the Chinese recognized the Cannabis plant as dioecious",[20] and the (c. 3rd century BCE) Erya dictionary defined xi 枲 "male Cannabis" and fu 莩 (or ju 苴) "female Cannabis".[21] Male flowers are normally borne on loose panicles, and female flowers are borne on racemes.[22]

Many monoecious varieties have also been described,[23] in which individual plants bear both male and female flowers.[24] (Although monoecious plants are often referred to as "hermaphrodites", true hermaphrodites – which are less common in Cannabis – bear staminate and pistillate structures together on individual flowers, whereas monoecious plants bear male and female flowers at different locations on the same plant.) Subdioecy (the occurrence of monoecious individuals and dioecious individuals within the same population) is widespread.[25][26][27] Many populations have been described as sexually labile.[28][29][30]

As a result of intensive selection in cultivation, Cannabis exhibits many sexual phenotypes that can be described in terms of the ratio of female to male flowers occurring in the individual, or typical in the cultivar.[31] Dioecious varieties are preferred for drug production, where the fruits (produced by female flowers) are used. Dioecious varieties are also preferred for textile fiber production, whereas monoecious varieties are preferred for pulp and paper production. It has been suggested that the presence of monoecy can be used to differentiate licit crops of monoecious hemp from illicit drug crops,[25] but sativa strains often produce monoecious individuals, which is possibly as a result of inbreeding.

Cannabis female flower with visible trichomes
Male Cannabis flower buds

Sex determination

[edit]
See also: Cytogenetics § History

Cannabis has been described as having one of the most complicated mechanisms of sex determination among the dioecious plants.[31] Many models have been proposed to explain sex determination in Cannabis.

Based on studies of sex reversal in hemp, it was first reported by K. Hirata in 1924 that an XY sex-determination system is present.[29] At the time, the XY system was the only known system of sex determination. The X:A system was first described in Drosophila spp in 1925.[32] Soon thereafter, Schaffner disputed Hirata's interpretation,[33] and published results from his own studies of sex reversal in hemp, concluding that an X:A system was in use and that furthermore sex was strongly influenced by environmental conditions.[30]

Since then, many different types of sex determination systems have been discovered, particularly in plants.[18] Dioecy is relatively uncommon in the plant kingdom, and a very low percentage of dioecious plant species have been determined to use the XY system. In most cases where the XY system is found it is believed to have evolved recently and independently.[34]

Since the 1920s, a number of sex determination models have been proposed for Cannabis. Ainsworth describes sex determination in the genus as using "an X/autosome dosage type".[18]

The question of whether heteromorphic sex chromosomes are indeed present is most conveniently answered if such chromosomes were clearly visible in a karyotype. Cannabis was one of the first plant species to be karyotyped; however, this was in a period when karyotype preparation was primitive by modern standards. Heteromorphic sex chromosomes were reported to occur in staminate individuals of dioecious "Kentucky" hemp, but were not found in pistillate individuals of the same variety. Dioecious "Kentucky" hemp was assumed to use an XY mechanism. Heterosomes were not observed in analyzed individuals of monoecious "Kentucky" hemp, nor in an unidentified German cultivar. These varieties were assumed to have sex chromosome composition XX.[35] According to other researchers, no modern karyotype of Cannabis had been published as of 1996.[36] Proponents of the XY system state that Y chromosome is slightly larger than the X, but difficult to differentiate cytologically.[37]

More recently, Sakamoto and various co-authors[38][39] have used random amplification of polymorphic DNA (RAPD) to isolate several genetic marker sequences that they name Male-Associated DNA in Cannabis (MADC), and which they interpret as indirect evidence of a male chromosome. Several other research groups have reported identification of male-associated markers using RAPD and amplified fragment length polymorphism.[40][28][41] Ainsworth commented on these findings, stating,

It is not surprising that male-associated markers are relatively abundant. In dioecious plants where sex chromosomes have not been identified, markers for maleness indicate either the presence of sex chromosomes which have not been distinguished by cytological methods or that the marker is tightly linked to a gene involved in sex determination.[18]

Environmental sex determination is known to occur in a variety of species.[42] Many researchers have suggested that sex in Cannabis is determined or strongly influenced by environmental factors.[30] Ainsworth reviews that treatment with auxin and ethylene have feminizing effects, and that treatment with cytokinins and gibberellins have masculinizing effects.[18] It has been reported that sex can be reversed in Cannabis using chemical treatment.[43] A polymerase chain reaction-based method for the detection of female-associated DNA polymorphisms by genotyping has been developed.[44]

  • A male hemp plant
    A male hemp plant
  • Dense raceme of female flowers typical of drug-type varieties of Cannabis
    Dense raceme of female flowers typical of drug-type varieties of Cannabis
  • Male Lemon Kush cannabis plant (12 foot plant)
    Male Lemon Kush cannabis plant (12 foot plant)
  • Male Lemon Kush cannabis Flowers
    Male Lemon Kush cannabis Flowers
  • A young female Acapulco Gold plant (Mexican x Nepalese). Seed grown plant from seeds obtained from a cannabis seed bank.[45]
    A young female Acapulco Gold plant (Mexican x Nepalese). Seed grown plant from seeds obtained from a cannabis seed bank.[45]
  • Acapulco Gold female plant in bloom
    Acapulco Gold female plant in bloom
  • Indoor grown Acapulco Gold female plant in final stages of flowering (flushing in amber and gold tones)
    Indoor grown Acapulco Gold female plant in final stages of flowering (flushing in amber and gold tones)

Chemistry

[edit]
See also: Chemical defenses in Cannabis

Cannabis plants produce a large number of chemicals as part of their defense against herbivory. One group of these is called cannabinoids, which induce mental and physical effects when consumed.

Cannabinoids, terpenes, terpenoids, and other compounds are secreted by glandular trichomes that occur most abundantly on the floral calyxes and bracts of female plants.[46]

  • Root system side view
    Root system side view
  • Root system top view
    Root system top view
  • Micrograph C. sativa (left), C. indica (right)
    Micrograph C. sativa (left), C. indica (right)

Genetics

[edit]

Cannabis, like many organisms, is diploid, having a chromosome complement of 2n=20, although polyploid individuals have been artificially produced.[47] The first genome sequence of Cannabis, which is estimated to be 820 Mb in size, was published in 2011 by a team of Canadian scientists.[48]

Taxonomy

[edit]
Underside of Cannabis sativa leaf, showing diagnostic venation

The genus Cannabis was formerly placed in the nettle family (Urticaceae) or mulberry family (Moraceae), and later, along with the genus Humulus (hops), in a separate family, the hemp family (Cannabaceae sensu stricto).[49] Recent phylogenetic studies based on cpDNA restriction site analysis and gene sequencing strongly suggest that the Cannabaceae sensu stricto arose from within the former family Celtidaceae, and that the two families should be merged to form a single monophyletic family, the Cannabaceae sensu lato.[50][51]

Various types of Cannabis have been described, and variously classified as species, subspecies, or varieties:[52]

  • plants cultivated for fiber and seed production, described as low-intoxicant, non-drug, or fiber types.
  • plants cultivated for drug production, described as high-intoxicant or drug types.
  • escaped, hybridised, or wild forms of either of the above types.

Cannabis plants produce a unique family of terpeno-phenolic compounds called cannabinoids, some of which produce the "high" which may be experienced from consuming marijuana. There are 483 identifiable chemical constituents known to exist in the cannabis plant,[53] and at least 85 different cannabinoids have been isolated from the plant.[54] The two cannabinoids usually produced in greatest abundance are cannabidiol (CBD) and/or Δ9-tetrahydrocannabinol (THC), but only THC is psychoactive.[55] Since the early 1970s, Cannabis plants have been categorized by their chemical phenotype or "chemotype", based on the overall amount of THC produced, and on the ratio of THC to CBD.[56] Although overall cannabinoid production is influenced by environmental factors, the THC/CBD ratio is genetically determined and remains fixed throughout the life of a plant.[40] Non-drug plants produce relatively low levels of THC and high levels of CBD, while drug plants produce high levels of THC and low levels of CBD. When plants of these two chemotypes cross-pollinate, the plants in the first filial (F1) generation have an intermediate chemotype and produce intermediate amounts of CBD and THC. Female plants of this chemotype may produce enough THC to be utilized for drug production.[56][57]

Top of Cannabis plant in vegetative growth stage

Whether the drug and non-drug, cultivated and wild types of Cannabis constitute a single, highly variable species, or the genus is polytypic with more than one species, has been a subject of debate for well over two centuries. This is a contentious issue because there is no universally accepted definition of a species.[58] One widely applied criterion for species recognition is that species are "groups of actually or potentially interbreeding natural populations which are reproductively isolated from other such groups."[59] Populations that are physiologically capable of interbreeding, but morphologically or genetically divergent and isolated by geography or ecology, are sometimes considered to be separate species.[59] Physiological barriers to reproduction are not known to occur within Cannabis, and plants from widely divergent sources are interfertile.[47] However, physical barriers to gene exchange (such as the Himalayan mountain range) might have enabled Cannabis gene pools to diverge before the onset of human intervention, resulting in speciation.[60] It remains controversial whether sufficient morphological and genetic divergence occurs within the genus as a result of geographical or ecological isolation to justify recognition of more than one species.[61][62][63]

Early classifications

[edit]
Relative size of varieties of Cannabis

The genus Cannabis was first classified using the "modern" system of taxonomic nomenclature by Carl Linnaeus in 1753, who devised the system still in use for the naming of species.[64] He considered the genus to be monotypic, having just a single species that he named Cannabis sativa L.[a 1] Linnaeus was familiar with European hemp, which was widely cultivated at the time. This classification was supported by Christiaan Hendrik Persoon (in 1807), Lindley (in 1838) and De Candollee (in 1867). These first classification attempts resulted in a four group division:[65]

  • Kif (southern hemp - psychoactive)
  • Vulgaris (intermediate - psychoactive and fiber)
  • Pedemontana (northern hemp - fiber)
  • Chinensis (northern hemp - fiber)

In 1785, evolutionary biologist Jean-Baptiste de Lamarck published a description of a second species of Cannabis, which he named Cannabis indica Lam.[66] Lamarck based his description of the newly named species on morphological aspects (trichomes, leaf shape) and geographic localization of plant specimens collected in India. He described C. indica as having poorer fiber quality than C. sativa, but greater utility as an inebriant. Also, C. indica was considered smaller, by Lamarck. Also, woodier stems, alternate ramifications of the branches, narrow leaflets, and a villous calyx in the female flowers were characteristics noted by the botanist.[65]

In 1843, William O’Shaughnessy, used "Indian hemp (C. indica)" in a work title. The author claimed that this choice wasn't based on a clear distinction between C. sativa and C. indica, but may have been influenced by the choice to use the term "Indian hemp" (linked to the plant's history in India), hence naming the species as indica.[65]

Additional Cannabis species were proposed in the 19th century, including strains from China and Vietnam (Indo-China) assigned the names Cannabis chinensis Delile, and Cannabis gigantea Delile ex Vilmorin.[67] However, many taxonomists found these putative species difficult to distinguish. In the early 20th century, the single-species concept (monotypic classification) was still widely accepted, except in the Soviet Union, where Cannabis continued to be the subject of active taxonomic study. The name Cannabis indica was listed in various Pharmacopoeias, and was widely used to designate Cannabis suitable for the manufacture of medicinal preparations.[68]

20th century

[edit]
Further information: Feral cannabis
Cannabis ruderalis

In 1924, Russian botanist D.E. Janichevsky concluded that ruderal Cannabis in central Russia is either a variety of C. sativa or a separate species, and proposed C. sativa L. var. ruderalis Janisch, and Cannabis ruderalis Janisch, as alternative names.[52] In 1929, renowned plant explorer Nikolai Vavilov assigned wild or feral populations of Cannabis in Afghanistan to C. indica Lam. var. kafiristanica Vav., and ruderal populations in Europe to C. sativa L. var. spontanea Vav.[57][67] Vavilov, in 1931, proposed a three species system, independently reinforced by Schultes et al (1975)[69] and Emboden (1974):[70] C. sativa, C. indica and C. ruderalis.[65]

In 1940, Russian botanists Serebriakova and Sizov proposed a complex poly-species classification in which they also recognized C. sativa and C. indica as separate species. Within C. sativa they recognized two subspecies: C. sativa L. subsp. culta Serebr. (consisting of cultivated plants), and C. sativa L. subsp. spontanea (Vav.) Serebr. (consisting of wild or feral plants). Serebriakova and Sizov split the two C. sativa subspecies into 13 varieties, including four distinct groups within subspecies culta. However, they did not divide C. indica into subspecies or varieties.[52][71][72] Zhukovski, in 1950, also proposed a two-species system, but with C. sativa L. and C. ruderalis.[73]

In the 1970s, the taxonomic classification of Cannabis took on added significance in North America. Laws prohibiting Cannabis in the United States and Canada specifically named products of C. sativa as prohibited materials. Enterprising attorneys for the defense in a few drug busts argued that the seized Cannabis material may not have been C. sativa, and was therefore not prohibited by law. Attorneys on both sides recruited botanists to provide expert testimony. Among those testifying for the prosecution was Dr. Ernest Small, while Dr. Richard E. Schultes and others testified for the defense. The botanists engaged in heated debate (outside of court), and both camps impugned the other's integrity.[61][62] The defense attorneys were not often successful in winning their case, because the intent of the law was clear.[74]

Three theories of classification for Cannabis. From left to right, monotypic with three subspecies (A), polytypic consisting of up to three species (B), and single phenotypically diverse species (C).

In 1976, Canadian botanist Ernest Small[75] and American taxonomist Arthur Cronquist published a taxonomic revision that recognizes a single species of Cannabis with two subspecies (hemp or drug; based on THC and CBD levels) and two varieties in each (domesticated or wild). The framework is thus:

  • C. sativa L. subsp. sativa, presumably selected for traits that enhance fiber or seed production.
    • C. sativa L. subsp. sativa var. sativa, domesticated variety.
    • C. sativa L. subsp. sativa var. spontanea Vav., wild or escaped variety.
  • C. sativa L. subsp. indica (Lam.) Small & Cronq.,[67] primarily selected for drug production.
    • C. sativa L. subsp. indica var. indica, domesticated variety.
    • C. sativa subsp. indica var. kafiristanica (Vav.) Small & Cronq, wild or escaped variety.

This classification was based on several factors including interfertility, chromosome uniformity, chemotype, and numerical analysis of phenotypic characters.[56][67][76]

Professors William Emboden, Loran Anderson, and Harvard botanist Richard E. Schultes and coworkers also conducted taxonomic studies of Cannabis in the 1970s, and concluded that stable morphological differences exist that support recognition of at least three species, C. sativa, C. indica, and C. ruderalis.[77][78][79][80] For Schultes, this was a reversal of his previous interpretation that Cannabis is monotypic, with only a single species.[81] According to Schultes' and Anderson's descriptions, C. sativa is tall and laxly branched with relatively narrow leaflets, C. indica is shorter, conical in shape, and has relatively wide leaflets, and C. ruderalis is short, branchless, and grows wild in Central Asia. This taxonomic interpretation was embraced by Cannabis aficionados who commonly distinguish narrow-leafed "sativa" strains from wide-leafed "indica" strains.[82] McPartland's review finds the Schultes taxonomy inconsistent with prior work (protologs) and partly responsible for the popular usage.[83]

Continuing research

[edit]

Molecular analytical techniques developed in the late 20th century are being applied to questions of taxonomic classification. This has resulted in many reclassifications based on evolutionary systematics. Several studies of random amplified polymorphic DNA (RAPD) and other types of genetic markers have been conducted on drug and fiber strains of Cannabis, primarily for plant breeding and forensic purposes.[84][85][28][86][87] Dutch Cannabis researcher E.P.M. de Meijer and coworkers described some of their RAPD studies as showing an "extremely high" degree of genetic polymorphism between and within populations, suggesting a high degree of potential variation for selection, even in heavily selected hemp cultivars.[40] They also commented that these analyses confirm the continuity of the Cannabis gene pool throughout the studied accessions, and provide further confirmation that the genus consists of a single species, although theirs was not a systematic study per se.

An investigation of genetic, morphological, and chemotaxonomic variation among 157 Cannabis accessions of known geographic origin, including fiber, drug, and feral populations showed cannabinoid variation in Cannabis germplasm. The patterns of cannabinoid variation support recognition of C. sativa and C. indica as separate species, but not C. ruderalis. C. sativa contains fiber and seed landraces, and feral populations, derived from Europe, Central Asia, and Turkey. Narrow-leaflet and wide-leaflet drug accessions, southern and eastern Asian hemp accessions, and feral Himalayan populations were assigned to C. indica.[57] In 2005, a genetic analysis of the same set of accessions led to a three-species classification, recognizing C. sativa, C. indica, and (tentatively) C. ruderalis.[60] Another paper in the series on chemotaxonomic variation in the terpenoid content of the essential oil of Cannabis revealed that several wide-leaflet drug strains in the collection had relatively high levels of certain sesquiterpene alcohols, including guaiol and isomers of eudesmol, that set them apart from the other putative taxa.[88]

A 2020 analysis of single-nucleotide polymorphisms reports five clusters of cannabis, roughly corresponding to hemps (including folk "Ruderalis") folk "Indica" and folk "Sativa".[89]

Despite advanced analytical techniques, much of the cannabis used recreationally is inaccurately classified. One laboratory at the University of British Columbia found that Jamaican Lamb's Bread, claimed to be 100% sativa, was in fact almost 100% indica (the opposite strain).[90] Legalization of cannabis in Canada (as of 17 October 2018) may help spur private-sector research, especially in terms of diversification of strains. It should also improve classification accuracy for cannabis used recreationally. Legalization coupled with Canadian government (Health Canada) oversight of production and labelling will likely result in more—and more accurate—testing to determine exact strains and content. Furthermore, the rise of craft cannabis growers in Canada should ensure quality, experimentation/research, and diversification of strains among private-sector producers.[91]

[edit]
Popular terms are discerned from scientific taxonomy by the lack of italics, use of quotes and uppercasing.

The scientific debate regarding taxonomy has had little effect on the terminology in widespread use among cultivators and users of drug-type Cannabis. Cannabis aficionados recognize three distinct types based on such factors as morphology, native range, aroma, and subjective psychoactive characteristics. "Sativa" is the most widespread variety, which is usually tall, laxly branched, and found in warm lowland regions. "Indica" designates shorter, bushier plants adapted to cooler climates and highland environments. "Ruderalis" is the informal name for the short plants that grow wild in Europe and Central Asia.[83]

Mapping the morphological concepts to scientific names in the Small 1976 framework, "Sativa" generally refers to C. sativa subsp. indica var. indica, "Indica" generally refers to C. sativa subsp. i. kafiristanica (also known as afghanica), and "Ruderalis", being lower in THC, is the one that can fall into C. sativa subsp. sativa. The three names fit in Schultes's framework better, if one overlooks its inconsistencies with prior work.[83] Definitions of the three terms using factors other than morphology produces different, often conflicting results.

Breeders, seed companies, and cultivators of drug type Cannabis often describe the ancestry or gross phenotypic characteristics of cultivars by categorizing them as "pure indica", "mostly indica", "indica/sativa", "mostly sativa", or "pure sativa". These categories are highly arbitrary, however: one "AK-47" hybrid strain has received both "Best Sativa" and "Best Indica" awards.[83]

Phylogeny

[edit]

Cannabis likely split from its closest relative, Humulus (hops), during the mid Oligocene, around 27.8 million years ago according to molecular clock estimates. The centre of origin of Cannabis is likely in the northeastern Tibetan Plateau. The pollen of Humulus and Cannabis are very similar and difficult to distinguish. The oldest pollen thought to be from Cannabis is from Ningxia, China, on the boundary between the Tibetan Plateau and the Loess Plateau, dating to the early Miocene, around 19.6 million years ago. Cannabis was widely distributed over Asia by the Late Pleistocene. The oldest known Cannabis in South Asia dates to around 32,000 years ago.[92]

Uses

[edit]

Cannabis is used for a wide variety of purposes.

History

[edit]
Main article: History of cannabis

According to genetic and archaeological evidence, cannabis was first domesticated about 12,000 years ago in East Asia during the early Neolithic period.[5] The use of cannabis as a mind-altering drug has been documented by archaeological finds in prehistoric societies in Eurasia and Africa.[93] The oldest written record of cannabis usage is the Greek historian Herodotus's reference to the central Eurasian Scythians taking cannabis steam baths.[94] His (c. 440 BCE) Histories records, "The Scythians, as I said, take some of this hemp-seed [presumably, flowers], and, creeping under the felt coverings, throw it upon the red-hot stones; immediately it smokes, and gives out such a vapour as no Greek vapour-bath can exceed; the Scyths, delighted, shout for joy."[95] Classical Greeks and Romans also used cannabis.

In China, the psychoactive properties of cannabis are described in the Shennong Bencaojing (3rd century AD).[96] Cannabis smoke was inhaled by Daoists, who burned it in incense burners.[96]

In the Middle East, use spread throughout the Islamic empire to North Africa. In 1545, cannabis spread to the western hemisphere where Spaniards imported it to Chile for its use as fiber. In North America, cannabis, in the form of hemp, was grown for use in rope, cloth and paper.[97][98][99][100]

Cannabinol (CBN) was the first compound to be isolated from cannabis extract in the late 1800s. Its structure and chemical synthesis were achieved by 1940, followed by some of the first preclinical research studies to determine the effects of individual cannabis-derived compounds in vivo.[101]

Globally, in 2013, 60,400 kilograms of cannabis were produced legally.[102]

Recreational use

[edit]
Main article: Cannabis (drug)
Comparison of physical harm and dependence regarding various drugs[103]
A dried bud, typical of what is sold for recreational use

Cannabis is a popular recreational drug around the world, only behind alcohol, caffeine, and tobacco. In the U.S. alone, it is believed that over 100 million Americans have tried cannabis, with 25 million Americans having used it within the past year.[when?][104] As a drug it usually comes in the form of dried marijuana, hashish, or various extracts collectively known as hashish oil.[10]

Normal cognition is restored after approximately three hours for larger doses via a smoking pipe, bong or vaporizer.[105] However, if a large amount is taken orally the effects may last much longer. After 24 hours to a few days, minuscule psychoactive effects may be felt, depending on dosage, frequency and tolerance to the drug.

Cannabidiol (CBD), which has no intoxicating effects by itself[55] (although sometimes showing a small stimulant effect, similar to caffeine),[106] is thought to attenuate (i.e., reduce)[107] the anxiety-inducing effects of high doses of THC, particularly if administered orally prior to THC exposure.[108]

According to Delphic analysis by British researchers in 2007, cannabis has a lower risk factor for dependence compared to both nicotine and alcohol.[109] However, everyday use of cannabis may be correlated with psychological withdrawal symptoms, such as irritability or insomnia,[105] and susceptibility to a panic attack may increase as levels of THC metabolites rise.[110][111] Cannabis withdrawal symptoms are typically mild and are not life-threatening.[112] Risk of adverse outcomes from cannabis use may be reduced by implementation of evidence-based education and intervention tools communicated to the public with practical regulation measures.[113]

In 2014 there were an estimated 182.5 million cannabis users worldwide (3.8% of the global population aged 15–64).[114] This percentage did not change significantly between 1998 and 2014.[114]

Medical use

[edit]
Main article: Medical cannabis

Medical cannabis (or medical marijuana) refers to the use of cannabis and its constituent cannabinoids, in an effort to treat disease or improve symptoms. Cannabis is used to reduce nausea and vomiting during chemotherapy, to improve appetite in people with HIV/AIDS, and to treat chronic pain and muscle spasms.[115][116] Cannabinoids are under preliminary research for their potential to affect stroke.[117] Evidence is lacking for depression, anxiety, attention deficit hyperactivity disorder, Tourette syndrome, post-traumatic stress disorder, and psychosis.[118] Two extracts of cannabis – dronabinol and nabilone – are approved by the FDA as medications in pill form for treating the side effects of chemotherapy and AIDS.[119]

Short-term use increases both minor and major adverse effects.[116] Common side effects include dizziness, feeling tired, vomiting, and hallucinations.[116] Long-term effects of cannabis are not clear.[120] Concerns including memory and cognition problems, risk of addiction, schizophrenia in young people, and the risk of children taking it by accident.[115]

Industrial use (hemp)

[edit]
Main article: Cannabis (industrial uses)
Cannabis sativa stem longitudinal section

The term hemp is used to name the durable soft fiber from the Cannabis plant stem (stalk). Cannabis sativa cultivars are used for fibers due to their long stems; Sativa varieties may grow more than six metres tall. However, hemp can refer to any industrial or foodstuff product that is not intended for use as a drug. Many countries regulate limits for psychoactive compound (THC) concentrations in products labeled as hemp.

Cannabis for industrial uses is valuable in tens of thousands of commercial products, especially as fibre[121] ranging from paper, cordage, construction material and textiles in general, to clothing. Hemp is stronger and longer-lasting than cotton. It also is a useful source of foodstuffs (hemp milk, hemp seed, hemp oil) and biofuels. Hemp has been used by many civilizations, from China to Europe (and later North America) during the last 12,000 years.[121][122] In modern times novel applications and improvements have been explored with modest commercial success.[123][124]

In the US, "industrial hemp" is classified by the federal government as cannabis containing no more than 0.3% THC by dry weight. This classification was established in the 2018 Farm Bill and was refined to include hemp-sourced extracts, cannabinoids, and derivatives in the definition of hemp.[125]

Ancient and religious uses

[edit]
Main articles: Cannabis and religion and History of medical cannabis
Cannabis Museum in Amsterdam
Cannabis leaf pictured in the coat of arms of Kanepi Parish

The Cannabis plant has a history of medicinal use dating back thousands of years across many cultures.[126] The Yanghai Tombs, a vast ancient cemetery (54 000 m2) situated in the Turfan district of the Xinjiang Uyghur Autonomous Region in northwest China, have revealed the 2700-year-old grave of a shaman. He is thought to have belonged to the Jushi culture recorded in the area centuries later in the Hanshu, Chap 96B.[127] Near the head and foot of the shaman was a large leather basket and wooden bowl filled with 789g of cannabis, superbly preserved by climatic and burial conditions. An international team demonstrated that this material contained THC. The cannabis was presumably employed by this culture as a medicinal or psychoactive agent, or an aid to divination. This is the oldest documentation of cannabis as a pharmacologically active agent.[128] The earliest evidence of cannabis smoking has been found in the 2,500-year-old tombs of Jirzankal Cemetery in the Pamir Mountains in Western China, where cannabis residue were found in burners with charred pebbles possibly used during funeral rituals.[129][130]

Settlements which date from c. 2200–1700 BCE in the Bactria and Margiana contained elaborate ritual structures with rooms containing everything needed for making drinks containing extracts from poppy (opium), hemp (cannabis), and ephedra (which contains ephedrine).[131]: 262  Although there is no evidence of ephedra being used by steppe tribes, they engaged in cultic use of hemp. Cultic use ranged from Romania to the Yenisei River and had begun by 3rd millennium BC Smoking hemp has been found at Pazyryk.[131]: 306 

Cannabis is first referred to in Hindu Vedas between 2000 and 1400 BCE, in the Atharvaveda. By the 10th century CE, it has been suggested that it was referred to by some in India as "food of the gods".[132] Cannabis use eventually became a ritual part of the Hindu festival of Holi. One of the earliest to use this plant in medical purposes was Korakkar, one of the 18 Siddhas.[133][134][self-published source?] The plant is called Korakkar Mooli in the Tamil language, meaning Korakkar's herb.[135][136]

In Buddhism, cannabis is generally regarded as an intoxicant and may be a hindrance to development of meditation and clear awareness. In ancient Germanic culture, Cannabis was associated with the Norse love goddess, Freya.[137][138] An anointing oil mentioned in Exodus is, by some translators, said to contain Cannabis.[139]

In modern times, the Rastafari movement has embraced Cannabis as a sacrament.[140] Elders of the Ethiopian Zion Coptic Church, a religious movement founded in the U.S. in 1975 with no ties to either Ethiopia or the Coptic Church, consider Cannabis to be the Eucharist, claiming it as an oral tradition from Ethiopia dating back to the time of Christ.[141] Like the Rastafari, some modern Gnostic Christian sects have asserted that Cannabis is the Tree of Life.[142][143] Other organized religions founded in the 20th century that treat Cannabis as a sacrament are the THC Ministry,[144] Cantheism,[145] the Cannabis Assembly[146] and the Church of Cognizance.

Since the 13th century CE, cannabis has been used among Sufis[147][148] – the mystical interpretation of Islam that exerts strong influence over local Muslim practices in Bangladesh, India, Indonesia, Turkey, and Pakistan. Cannabis preparations are frequently used at Sufi festivals in those countries.[147] Pakistan's Shrine of Lal Shahbaz Qalandar in Sindh province is particularly renowned for the widespread use of cannabis at the shrine's celebrations, especially its annual Urs festival and Thursday evening dhamaal sessions – or meditative dancing sessions.[149][150]

See also

[edit]

Notes

[edit]
  1. ^ "L." stands for Linnaeus, and indicates the authority who first named the species

References

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Further reading

[edit]
[edit]
Cannabis at Wikipedia's sister projects
 
 
 
 
 
 
 
 
 
 
 

 

Hashish
1.5 grams (116 oz) pressed marijuana
Source plant(s) Cannabis indica, Cannabis sativa, Cannabis ruderalis[a]
Part(s) of plant Trichome
Geographic origin South Asia[2]
Active ingredients Tetrahydrocannabinol, cannabidiol, cannabinol, tetrahydrocannabivarin
Legal status
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Hashish (/həˈʃiːʃ/ ⓘ; from Arabic ḥašiš 'hay'), usually abbreviated as hash, is a compressed form of resin (trichomes) derived from the marijuana flowers.[3][4] As a psychoactive substance, it is consumed plain or mixed with tobacco. It has a long history of use in countries such as Afghanistan, India, Pakistan, Iran, Iraq, Lebanon, Morocco, and Egypt.[5]

Hashish consumption is also popular in Europe. In the United States, dried flowers or concentrates are more popular, and hash has seen a relative decrease in popularity following changes in laws that have indirectly allowed for the development and increased availability of cannabis extracts that are more potent than traditional hashish, although regional differences in product preferences exist.[6] Like many recreational drugs, multiple synonyms and alternative names for hashish exist, and vary greatly depending on the country and native language.[7]

Hashish is a cannabis concentrate product composed of compressed or purified preparations of stalked resin glands, called trichomes, from the plant. It is defined by the 1961 UN Single Convention on Narcotic Drugs (Schedule I and IV) as "the separated resin, whether crude or purified, obtained from the cannabis plant". The resin contains ingredients such as tetrahydrocannabinol (THC) and other cannabinoids—but often in higher concentrations than the unsifted or unprocessed cannabis flower.[8] Purities of confiscated hashish in Europe (2011) range between 3% and 15%. Between 2000 and 2005, the percentage of hashish in cannabis end product seizures was at 18%.[3] With the strength of unprocessed cannabis flowers having increased greatly in recent years—with flowers containing upwards of 25% THC by weight—the strength of hashish produced today and in the future is likely to be far more potent than in these older records.[9][10]

The consistency and appearance of hashish is highly dependent on the process used and the amount of leftover plant material (e.g. chlorophyll). It is typically solid, though its consistency ranges from brittle to malleable. It is most commonly light or dark brown in color, though may appear transparent, yellow, black, or red.[11]

History

[edit]

Hashish has been consumed for many centuries, though there is no clear evidence as to its first appearance.[12] North India and Nepal have a long social tradition in the production of hashish, known locally as charas.[13]

The first attestation of the term "hashish" is in a pamphlet published in Cairo in 1123 CE, accusing Nizari Muslims of being "hashish-eaters".[14] The cult of Nizari militants which emerged after the fall of the Fatimid Caliphate is commonly called the sect of the Assassins—a corruption of hashishin, Arabic for "hashish-smokers." The 13th-century jurist Ibn Taymiyyah prohibited the use of hashish; he mentioned that it was introduced to Levant with the Mongol invasion (throughout the 13th century).[15] Smoking did not become common in the Old World until after the introduction of tobacco; until the 1500s, hashish was consumed as an edible in the Muslim world.[16]

In 1596, Dutchman Jan Huyghen van Linschoten spent three pages on "Bangue" (bhang) in his historic work documenting his journeys in the East. He particularly mentioned the Egyptian hashish.[17] He said, "Bangue is likewise much used in Turkie and Egypt, and is made in three sorts, having also three names. The first by the Egyptians is called Assis (Hashish (Arab.)), which is the poulder of Hemp, or of Hemp leaves, which is water made in paste or dough, they would eat five pieces, (each) as big as a Chestnut (or larger); This is used by the common people, because it is of a small price, and it is no wonder, that such vertue proceedeth from the Hempe, for that according to Galens opinion, Hempe excessively filleth the head."[18]

Hashish arrived in Europe from the East during the 18th century,[3] and is first mentioned scientifically by Gmelin in 1777.[3] The Napoleonic campaigns introduced French troops to hashish in Egypt and the first description of its useful stems was in 1830 by pharmacist and botanist Theodor Friedrich Ludwig Nees von Esenbeck.[3]

In 1839, O'Shaughnessy wrote a comprehensive study of Himalayan hemp, which was recognised by the European school of medicine and describes hashish as relief for cramps and causing the disappearance of certain symptoms from afflictions such as rabies, cholera, and tetanus.[3] This led to high hopes in the medical community. In 1840, Louis Aubert-Roche reported his successful use of hashish against pestilence.[3] Also, psychiatric experiments with hashish were done at the same time with Jacques-Joseph Moreau being convinced that it is the supreme medicament for use in psychiatry.[3]

In the 19th century, hashish was embraced in some European literary circles. Most famously, the Club des Hashischins was a Parisian club dedicated to the consumption of hashish and other drugs; its members included writers Théophile Gautier, Dr. Moreau de Tours, Victor Hugo, Alexandre Dumas, Charles Baudelaire and Honoré de Balzac.[19] Baudelaire later wrote the 1860 book Les paradis artificiels about the state of being under the influence of opium and hashish. Around the same time, American author Fitz Hugh Ludlow wrote the 1857 book The Hasheesh Eater about his youthful experiences, both positive and negative, with the drug.

Hashish was also mentioned[by whom?] and used as an anesthetic in Germany in 1869. It was imported in great quantities especially from India where it was called charas. However, there were also people[who?] who did not deem cannabis as harmless.[3] Between 1880 and 1900 was the peak of the medicinal use, where hashish compounds were most commonplace in almost all European countries and the USA. Evidence of misuse at that time was practically non-existent (as opposed to widespread reports in Asia and Africa).[3] Hashish played a significant role in the treatment of pain, migraine, dysmenorrhea, pertussis, asthma and insomnia in Europe and USA towards the end of the 19th century. Rare applications included stomach ache, depression, diarrhea, diminished appetite, pruritus, hemorrhage, Basedow syndrome and malaria.[3] The use was later prohibited worldwide as the use as a medicine was made impossible by the 1961 UN Single Convention on Narcotic Drugs.

At the beginning of the 20th century, the majority of hashish in Europe came from Kashmir and other parts of India, Afghanistan, as well as Greece, Syria, Nepal, Lebanon, and Turkey. Larger markets developed in the late 1960s and early 1970s when most of the hashish was imported from Pakistan and Afghanistan. In Greece, Hashish was prevalent in the early decades of the 20th century, and although locally produced for hundreds of years prior, it reached its peak with the coming of two and a half million Greek refugees, expelled from Turkey following the disastrous 1919-21 war. Many of these refugees had habitually smoked hashish in Turkey, using waterpipes, (hookas) called "arghilethes", and due to extreme poverty upon arriving in Greece, and living in overcrowded and poor refugee communities, many hashish dens, called "tekethes", sprung up in Greece's larger cities, the port city of Piraeus, and the northern city of Thessaloniki (where many refugees lived). This gave rise to a substantial urban underclass and sub culture of hashish smokers called "hasiklithes", and a musical genre "rembetika" (oriental sounding), "urban blues" played on the bouzouki, tzoura, and oriental instruments such as the baglama, outi (oud) and kanonaki (kanun) that spoke of life as a hashish user in the "tekethes", as well as about life as refugees, society's unfairness, lack of financial opportunities, prejudice against the refugees, and the deceit of lovers and others in the community. The "tekethes" were closed down in the 1930s by the Greek police and the "rembetes" were jailed and ostracized. In succeeding decades, there was a strong resurgence in Greece of "rembetika" music with the songs of the rembetes and hasiklithes being continually performed publicly by many including the younger generation, as a form of cultural heritage, and have gained respectability and popularity for their frank expressions of that period, and Greek society in general. Due to disruptive conflicts in the regions, Morocco took over and was the sufficient exporter until lately.[when?][20] It is believed that massive hashish production for international trade originated in Morocco during the 1960s, where the cannabis plant was widely available. Before the coming of the first hippies from the Hippie Trail, only small pieces of Lebanese hashish were found in Morocco.[12]

However, since the 2000s, there has been a dramatic shift in the market due to an increase of homegrown cannabis production. While Morocco held a quasi-monopoly on hashish in the 1990s with the 250-gram (8.8 oz) so-called "soap bar" blocks, which were of low quality, Afghanistan is now regarded as the biggest producer of higher quality hashish. Since then, hashish quality in Europe has increased while its prices have remained stable,[3] with the exception of during the COVID-19 pandemic, where the cannabis street prices surged due to various national lockdowns.[21][22]

Hashish remains in high demand in most of the world while quality continues to increase, due to many Moroccan and western farmers in Morocco and other hash producing countries using more advanced cultivation methods as well as cultivating further developed cannabis strains which increases yields greatly, as well as improving resin quality with higher ratios of psychoactive ingredients (THC).[citation needed] A tastier, smoother and more aromatic terpenes and flavonoids profile is seen as an indicator of a significant rise in hashish quality in more recent years. Hashish production in Spain has also become more popular and is on the rise, however the demand for relatively cheap and high-quality Moroccan hash is still extremely high.[citation needed]

Changes to regulations around the world have contributed greatly to more and more countries becoming legitimate hashish producing regions, with countries like Spain effecting more lenient laws on cannabis products such as hashish. Washington State followed by Colorado started regulating cultivation, manufacturing and distribution of cannabis and cannabis derived products such as hashish in the United States, followed by many other places in the US (such as Humboldt, California) and around the world.[citation needed]

European market

[edit]
Hashish shown next to a

19-millimetre (34 in) diameter U.S. penny for scale

According to the European Monitoring Centre for Drugs and Drug Addiction (EMCDDA), Western Europe is the biggest market for cannabis resin with 70% of global seizures. The European hashish market is changing though: Cannabis cultivation increased throughout the 1990s until 2004, with a noticeable decrease reported in 2005 according to the European Monitoring Centre for Drugs and Drug Addiction.[3] Morocco has been the major source, however lately there has been a shift in the market and Afghanistan has been named the major producer of Hashish. Even though a drop in usage and production has been reported, Morocco produced around 6600 tonnes of resin in 2005.[3]

As 641 tonnes of hashish were consumed in the EU in 2013, the European market is currently the world's largest and most profitable. Therefore, many players are involved in the business, including organised crime groups. The largest cannabis resin seizures in Europe happen in Portugal, due to its proximity to Northern Africa.[3]

The 1990s "soap bars" disappeared and the physical shapes of hashish changed to melon shaped, tablets or olive shaped pellets. Overall the general trend of domestically grown cannabis displacing the imported resin leads to a market reaction of potency changes while the prices remain stable while soap-bar potency increased from 8% to up to 20.7% in 2014.[3]

Generally, more resin than herb is consumed in Europe.[3]

Substance properties

[edit]

Hashish is made from cannabinoid-rich glandular hairs known as trichomes, as well as varying amounts of cannabis flower and leaf fragments.[23] The flowers of a mature female plant contain the most trichomes, though trichomes are also found on other parts of the plant. Certain strains of cannabis are cultivated specifically for their ability to produce large amounts of trichomes. The resin reservoirs of the trichomes, sometimes erroneously called pollen (vendors often use the euphemism "pollen catchers" to describe screened kief-grinders in order to skirt paraphernalia-selling laws), are separated from the plant through various methods.

Hashish samples from India, Lebanon and Morocco confiscated in Europe and Israel in 2005 contained all appreciable amounts of cannabidiol (CBD), and cannabinol (CBN), in addition to tetrahydrocannabinol (THC). In some samples the CBD-content was significantly higher than the THC-content. The simultaneous occurrence of these three cannabinoids constitute the typical, chemical profile of hashish consumed in Europe and Northern Africa. In comparison, most high-potency marijuana products contain only THC. It is believed that the psychotropic effects of hashish are therefore more subtle, and sedative.[24]

In a study conducted in 2014 by Jean-Jaques Filippi, Marie Marchini, Céline Charvoz, Laurence Dujourdy and Nicolas Baldovini (Multidimensional analysis of cannabis volatile constituents: Identification of 5,5-dimethyl-1-vinylbicyclo[2.1.1]hexane as a volatile marker of hashish, the resin of Cannabis sativa L.) the researchers linked the characteristic flavour of hashish with a rearrangement of myrcene caused during the process of manufacture.[25]

Depending on the production process, the product can be contaminated with different amounts of dirt and plant fragments, varying greatly in terms of appearance, texture, odour and potency. Also, adulterants may be added in order to increase weight or modify appearance.[20]

Short-term effects

[edit]
See also: Effects of cannabis
Sebsi, a Moroccan long-drawtube one-hitter

Hashish can be consumed by oral ingestion or smoking. When smoked, it may be smoked in a pipe, bong, vaporizer or joints, where it is often mixed with tobacco, as pure hashish will burn poorly alone. THC has a low water solubility therefore it is most effective when ingested alongside a fatty meal or snack.[26] Not all hashish can be consumed orally as some is not decarboxylated during manufacture. Generally the methods are similar to overall cannabis consumption.

As hashish’s active ingredient is THC, it has the same effects as cannabis. The onset is felt within 15 minutes when smoking, and about 30 to 60 minutes when eaten.[27] Common effects include:

Side effects with overdose may include anxiety, paranoia and panic.[28]

Manufacturing processes

[edit]

 

Making charas from fresh cannabis resin, Uttarakhand, India

The sticky resins of the fresh flowering female cannabis plant are collected. Traditionally this was, and still is, done in remote locations by pressing or rubbing the flowering plant between two hands and then forming the sticky resins into a small ball of hashish called charas. This method produces the highest amount of cannabinoids (THC content up to 60%) without chemical solvents or distillation. The best quality charas is produced in Central Asia, and sold in sausage-like shapes.[29]

Mechanical separation methods use physical action to remove the trichomes from the dried plant material, such as sieving through a screen by hand or in motorized tumblers. This technique is known as "drysifting". The resulting powder, referred to as "kief" or "drysift", is compressed with the aid of heat into blocks of hashish; if pure, the kief will become gooey and pliable. When a high level of pure THC is present, the end product will be almost transparent and will start to melt at the point of human contact.

Ice-water separation is another mechanical method of isolating trichomes. Newer techniques have been developed such as heat and pressure separations, static-electricity sieving or acoustical dry sieving.[citation needed]

Trichomes isolated with ice-water extraction method

Trichomes may break away from supporting stalks and leaves when plant material becomes brittle at low temperatures. After plant material has been agitated in an icy slush, separated trichomes are often dense enough to sink to the bottom of the ice-water mixture following agitation, while lighter pieces of leaves and stems tend to float.[30]

The ice-water method requires ice, water, agitation, filtration bags with various-sized screens and plant material. With the ice-water extraction method the resin becomes hard and brittle and can easily be separated. This allows large quantities of pure resins to be extracted in a very clean process without the use of solvents, making for a more purified hashish.[30][31]

Chemical separation methods generally use a solvent such as ethanol, butane or hexane to dissolve the lipophilic desirable resin. Remaining plant materials are filtered out of the solution and sent to the compost. The solvent is then evaporated, or boiled off (purged) leaving behind the desirable resins, called honey oil, "hash oil", or just "oil". Honey oil still contains waxes and essential oils and can be further purified by vacuum distillation to yield "red oil". The product of chemical separations is more commonly referred to as "honey oil". This oil is not really hashish, as the latter name covers trichomes that are extracted by sieving. This leaves most of the glands intact.

Morocco has been the major hashish producer globally with €10.8 billion earned from Moroccan resin in 2004, but some so-called "Moroccan" may actually be European-made.[3][20] The income for the farmers was around €325 million in 2005. While the overall number of plants and areas shrank in size, the introduction of more potent hybrid plants produced a high resin rate. The amount of resin produced is estimated to range between 3,800 and 9,500 tonnes in 2005.[3]

The largest producer today is Afghanistan,[32] however studies suggest there is a "hashish revival" in Morocco.[33]

Solventless Rosin Method was discovered by Phil Salazar in 2015. Rosin is created by pressing Cannabis Flower, Dry sift, or Ice water hash in between parchment paper using a pneumatic or hydraulic press with heated plates to create force and pressure to expel the oil from the product. The moisture present in the flower, Dry Sift, or ice water hash will create steam pressure and force the oil from the source creating a solventless hash product.[34]

Quality

[edit]

Tiny pieces of leaf matter may be accidentally or even purposely added; adulterants introduced when the hashish is being produced will reduce the purity of the material and often resulting in green finished product. If hash is particularly sticky, this can mean that additional oils have been added to increase the overall weight of the product. The most common quality indicator is the smell. High-quality hash will smell fragrant and aromatic, whereas hash of low quality may have a distinct mouldy or musty aroma.[35] The tetrahydrocannabinol (THC) content of hashish comes in wide ranges from almost none to 65% and that of hash oil from 30% to 90%.[36] Hashish can also contain appreciable amounts of CBD, CBN and also contain trace amounts of other cannabinoids[37]

As mentioned above, there has been a general increase in potency as the competition has grown bigger and new hybrid plants have been developed.[20]

See also

[edit]

References

[edit]

Footnotes

  1. ^ Pure varieties of C. ruderalis are rarely used for recreational purposes (including as hashish) due to their negligible amounts of THC.[1]

Citations

  1. ^ Cervantes, Jorge (2006). Marijuana Horticulture: The Indoor/Outdoor Medical Grower's Bible (5th ed.). Van Patten Publishing. pp. 12. ISBN 9781878823236.
  2. ^ Mahmoud A. ElSohly (2007). Marijuana and the Cannabinoids. Springer. p. 8. ISBN 978-1-59259-947-9. Archived from the original on 2023-01-15. Retrieved 2016-08-02.
  3. ^ a b c d e f g h i j k l m n o p q r s EMCDDA (2008). "A cannabis reader: global issues and local experiences". Monograph Series. 8 (1). Archived from the original on 2019-04-04. Retrieved 2017-06-29. European Monitoring Centre for Drugs and Drug Addiction, Lisbon, doi:10.2810/13807
  4. ^ "What is Hash?". Leafly. 2020-06-25. Archived from the original on 2020-10-09. Retrieved 2020-10-05.
  5. ^ "The History Of Hashish". druglibrary.org. Archived from the original on 2020-08-11. Retrieved 2020-10-05.
  6. ^ "Is Old-School Hashish Going Extinct in America?". MERRY JANE. 9 May 2019. Archived from the original on 2020-10-09. Retrieved 2020-10-05.
  7. ^ "Hashish". drugs.com. Archived from the original on 26 April 2019. Retrieved 19 May 2017.
  8. ^ Russo, Ethan. Cannabis and Cannabinoids: Pharmacology, Toxicology, and Therapeutic Potential, p. 34 (Routledge 2013).
  9. ^ ElSohly, Mahmoud A.; Mehmedic, Zlatko; Foster, Susan; Gon, Chandrani; Chandra, Suman; Church, James C. (2016-04-01). "Changes in Cannabis Potency over the Last Two Decades (1995-2014) - Analysis of Current Data in the United States". Biological Psychiatry. 79 (7): 613–619. doi:10.1016/j.biopsych.2016.01.004. ISSN 0006-3223. PMC 4987131. PMID 26903403.
  10. ^ "Highly Potent Weed Has Swept The Market, Raising Concerns About Health Risks". NPR.org. Archived from the original on 2020-10-08. Retrieved 2020-10-05.
  11. ^ "Guide To The Different Types Of Hashish". www.druglibrary.org. Archived from the original on 2014-01-09. Retrieved 2014-01-09.
  12. ^ a b Hashish! by Robert Connell Clarke, ISBN 0-929349-05-9
  13. ^ Usaybia, Abu; Notes on Uyunu al-Anba fi Tabaquat al-Atibba, Berkeley: University of California Press, 1965.
  14. ^ Martin Booth (30 September 2011). Cannabis: A History. Transworld. pp. 84–. ISBN 978-1-4090-8489-1. Archived from the original on 20 April 2023. Retrieved 25 December 2017.
  15. ^ Ibn Taymiyyah, Majmu al-Fatwa al-Kubra (Arabic), Vol. 3, p 425. http://shamela.ws/browse.php/book-9690#page-1323 Archived 2018-11-10 at the Wayback Machine
  16. ^ John Charles Chasteen (9 February 2016). Getting High: Marijuana through the Ages. Rowman & Littlefield. pp. 72–. ISBN 978-1-4422-5470-1. Archived from the original on 20 April 2023. Retrieved 25 December 2017.
  17. ^ Burnell, Arthur Coke; Tiele, P.A (1885). The voyage of John Huyghen van Linschoten to the East Indies. from the old English translation of 1598: the first book, containing his description of the East. London: The Hakluyt Society. pp. 115–117. Full text at Internet Archive. Chapter on Bangue.
  18. ^ Jan Huygen van Linschoten (1885). The Voyage of John Huyghen Van Linschoten to the East Indies: From the Old English Translation of 1598. The First Book, Containing His Description of the East... Hakluyt society. pp. 116–.
  19. ^ Levinthal, C. F. (2012). Drugs, behavior, and modern society. (6th ed.). Boston: Pearson College Div.
  20. ^ a b c d Chouvy, Pierre-Arnaud. "The supply of hashish to Europe" (PDF). Background Paper Commissioned by the EMCDDA for the 2016 EU Drug Markets Report. Archived (PDF) from the original on 2019-08-19. Retrieved 2017-07-01.
  21. ^ Pailliez, Caroline; Guichard, Mourad (2020-03-27). "Cannabis street prices surge under coronavirus lockdown in France". Reuters. Archived from the original on 2020-03-29. Retrieved 2022-07-18. The street price of cannabis in French cities has surged after tight border controls imposed as part of a nationwide lockdown to slow the coronavirus outbreak disrupted the flow of illegal narcotics and drug gangs hiked their rates.
  22. ^ Larsen, Martin Hall; Espedal, Jan T.; Kagge, Gunnar (2020-04-12). "Rusmiljøet frykter koronavirus vil gi økte priser og doptørke i Oslo". Aftenposten (in Norwegian). Archived from the original on 2022-07-18. Retrieved 2022-07-18. – Hasjprisen har skutt i været i det siste. Prisen lå på rundt hundre kroner per gram. Nå har jeg hørt priser rundt femhundrelappen, sier Torbjørn Johnsbø.
  23. ^ Gloss, D (October 2015). "An Overview of Products and Bias in Research". Neurotherapeutics (Review). 12 (4): 731–4. doi:10.1007/s13311-015-0370-x. PMC 4604179. PMID 26202343.
  24. ^ Lumír O. Hanuš, Rina Levy, Dafna De La Vega, Limor Katz, Michael Roman & Pavel Tomíček (08 Jun 2016). "The main cannabinoids content in hashish samples seized in Israel and Czech Republic." Archived 2021-09-11 at the Wayback Machine tandfonline.org. p. 182-190. doi:10.1080/07929978.2016.1177983. Archived 2023-04-20 at the Wayback Machine Retrieved 10 September 2021.
  25. ^ Alchimia Blog, Hashishene, the new terpene of cannabis Archived 2016-03-03 at the Wayback Machine
  26. ^ "Cannabis drug profile". emcdda.europa.eu. Archived from the original on 24 June 2018. Retrieved 19 May 2017.
  27. ^ a b c d "DrugFacts: Marijuana | National Institute on Drug Abuse (NIDA)". 2019-08-01. Archived from the original on 2019-08-01. Retrieved 2021-10-18.
  28. ^ a b c d e f "Marijuana Symptoms and Warning Signs - Addiction Center". 2021-01-22. Archived from the original on 2021-01-22. Retrieved 2021-10-18.
  29. ^ Inciardi, James A. The War on Drugs II (неопр.). — Mountain View, California: McGraw-Hill Education, 1992. — С. 19. — ISBN 1-55934-016-9.
  30. ^ a b Scammel and, Liza; Bianca Sind. "How to Make Wicked hash/Bubble hash". Cannabis Culture Magazine. Archived from the original on 28 June 2011. Retrieved 22 June 2011.
  31. ^ Brady, P. (February 4, 2003). "Bubble Hash". Cannabis Culture Magazine. Archived from the original on 12 June 2011. Retrieved 22 June 2011.
  32. ^ "UN: Afghanistan is leading hashish producer". Fox News. 2010-03-31. Archived from the original on 2011-07-16. Retrieved 2016-05-28.
  33. ^ Chouvy, Pierre Arnaud; Afsahi, Kenza (2014). "Hashish Revival in Morocco". International Journal of Drug Policy. 25 (3): 416–423. doi:10.1016/j.drugpo.2014.01.001. ISSN 0955-3959. PMID 24507440. Archived from the original on 2017-02-03. Retrieved 2017-07-01.
  34. ^ Andrew Parker (May 8, 2017). "The Birth of Rosin". High Times. Archived from the original on 11 November 2020.
  35. ^ Zamnesia Archived 2021-04-18 at the Wayback Machine How to determine high-quality hash
  36. ^ Inciardi, James A. (1992). The War on Drugs II. Mountain View, CA: Mayfield Publishing Company. p. 19. ISBN 1-55934-016-9.
  37. ^ "The main cannabinoids content in hashish samples seized in Israel and Czech Republic". Lumir Lab. Archived from the original on 2020-06-09. Retrieved 2020-06-09.

Further reading

[edit]
  • Hashish! by Robert Connell Clarke, ISBN 0-929349-05-9
  • The Hasheesh Eater by Fitz Hugh Ludlow; first edition 1857
  • Marihuana The first twelve thousand years by Ernest L. Abel, 1980, ISBN 0-306-40496-6
  • Starks, Michael. Marijuana Potency. Berkeley, California: And/Or Press, 1977. Chapter 6 "Extraction of THC and Preparation of Hash Oil" pp. 111–122. ISBN 0-915904-27-6.
[edit]
 
Look up hashish in Wiktionary, the free dictionary.
 
Wikisource has the text of the 1905 New International Encyclopedia article "Hashish".
 
Wikimedia Commons has media related to Hashish.
 
 

 

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