Bud and stress... what do you think?

[WaterLillyFairy]

So I have been reading a lot lately that marijuana inhibits dopamine production along with other stress reducing chemicals, and can long term, continued use can cause you to no longer naturally produce those chemicals, meaning without bud you will be unable to handle everyday stress... I'm curious to see what people here think about it... Does it bother you thinking you may not be able to handle stress well without bud, or does it not really matter much to you? And Why/Why not? Just out of curiosity.

[shagra]

well, it does matter quite a bit to me. i don't want to become dependent on the greens, even though i love 'em. Do you know the ratio of smoking to reduction of production?

[gOngaToKeR420]

That's already happening to me.. it's crazy, because I've always been an independent person and this means that I'm dependent on something. I'm dependent on the bud to get through everyday life. If I dont have it everyday, that I get real stressed out and real agitated. I HATE this..

[WaterLillyFairy]

Here are a few paragraphs I found while searching for specific information on marijuana and stress from this website
http://www.druglibrary.org/schaffer/hemp/BRAIN.HTM
it's a pretty long read but it's interesting...

RECEPTORS IN THE BRAIN

The locations of the cannabinoid receptors are most revealing of the way THC acts on the brain, but the importance of this determination is best understood in comparison with the effects of other drugs on the brain. Neurons are brain cells which process information. Neurotransmitter chemicals enable them to communicate with each other by their release into the gap between the neurons. This gap is called the synapse. Receptors are actually proteins in neurons which are specific to neurotransmitters, and which turn various cellular mechanisms on or off. Neurons can have thousands of receptors for different neurotransmitters, causing any neurotransmitter to have diverse effects in the brain. Drugs affect the production, release or re-uptake (a regulating mechanism) of various neurotransmitters. They also mimic or block actions of neurotransmitters, and can interfere with or enhance the mechanisms associated with the receptor. Dopamine is a neurotransmitter which is associated with extremely pleasurable sensations, so that the neural systems which trigger dopamine release are known as the "brain reward system." The key part of this system is identified as the mesocorticolimbic pathway, which links the dopamine-production area with the nucleus of accumbens in the limbic system, an area of the brain which is associated with the control of emotion and behavior. Cocaine, for example, blocks the re-uptake of dopamine so that the brain, lacking biofeedback, keeps on producing it. Amphetamines also block the re-uptake of dopamine, and stimulate additional production and release of it. Opiates activate neural pathways that increase dopamine production by mimicking opioid-peptide neurotransmitters which increase dopamine activity in the ventral tegmental area of the brain where the neurotransmitter originates. Opiates work on three receptor sites, and in effect restrain an inhibitory amino acid, gamma-aminobutyric acid, that otherwise would slow down or halt dopamine production. All of these substances can produce strong reinforcing properties that can seriously influence behavior. The rewarding properties of dopamine are what accounts for animal studies in which animals will forgo food and drink or willingly experience electric shocks in order to stimulate the brain reward system. It is now widely held that drugs of abuse directly or indirectly affect the brain reward system. The key clinical test of whether a substance is a drug of abuse potential or not is whether administration of the drug reduces the amount of electrical stimulation needed to produce self-stimulation response, or dopamine production. This is an indication that a drug has reinforcing properties, and that an individual's use of the drug can lead to addictive and other harmful behavior. To be precise, according to the Office of Technological Assessment (OTA): "The capacity to produce reinforcing effects is essential to any drug with significant abuse potential." Marijuana should no longer be considered a serious drug abuse because, as summarized by the OTA: "Animals will not self-administer THC in controlled studies . . . . Cannabinoids generally do not lower the threshold needed to get animals to self-stimulate the brain regard system, as do other drugs of abuse." Marijuana does not produce reinforcing effects. The definitive experiment which measures drug-induced dopamine production utilizes microdialysis is live, freely-moving rats. Brain microdialysis has proven that opiates, cocaine, amphetamines, nicotine and alcohol all affect dopamine production, whereas marijuana does not. This latest research confirms and explains Hollister's 1986 conclusion about cannabis and addiction: "Physical dependence is rarely encountered in the usual patterns, despite some degree of tolerance that may develop." Most important, the discoveries of Howlett and Devane, Herkenham and their associates demonstrate that the cannabinoid receptors do not influence the dopamine reward system.

CANNABINOID RECEPTORS Research has enabled scientists to know which portions of the brain control various body functions, and this knowledge has been used to explain the pharmacological properties of drugs that activate receptor sites in the brain. There is a dense concentration of cannabinoid binding sites in the basal ganglia and the cerebellum of the base-brain, both of which affect movement and coordination. This discovery will aid in determining the actual physical mechanism by which THC affects spasticity and provides therapeutic benefits to patients with multiple sclerosis and other spastic disorders. While there are cannabinoid receptors in the ventromedial striatum and basal ganglia which are areas associated with dopamine production, no cannabinoid receptors have been found in dopamine-producing neurons, and as mentioned above, no reinforcing properties have been demonstrated in animal studies. There is one study by Gardner and Lowinson, involving inbred Lewis rats, in which doses of THC lowered the amount of electrical stimulation required to trigger the brain reward system. However, no one has been able to replicate the results with any other species of rat, or any other animal. The finding is believed to be the result of some inbred genetic variation in the inbred species, and is both widely mentioned in the literature and disregarded. According to Herkenham and his associates, "There are virtually no reports of fatal cannabis overdose in humans. The safety reflects the paucity of receptors in medullary nuclei that mediate respiratory and cardiovascular functions." This is also why cannabinoids have great promise as analgesics or painkillers, in that they do not depress the function of the heart or the lungs. In this respect, they are far superior to opiates, which decrease the entire physiological system because the receptors are all over the medulla as well as the brain. Marijuana is distinguished from most other illicit drugs by the locations of its brain-receptor sites for two predominant reasons: (1) The lack of receptors in the medulla significantly reduces the possibility of accidental, or even deliberate, death from THC, and (2) the lack of receptors in the mesocorticolimbic pathway significantly reduces the risks of addiction and serious physical dependence. As a therapeutic drug, these features are God's greatest gifts.

THE CHEMISTRY OF EMOTIONS

Mechoulam regrets that more has not been done in the therapeutic application of THC. In a 1986 interview with the International Journal of the Addictions, he said that, "Knowing what I know today, I would have worked more on the therapeutic aspects of cannabis. This area apparently needs a major push that is has not had up till now, particularly given that it has a therapeutic potential. One of the reasons that it has not been pushed was than most pharmaceutical companies years ago were afraid to get into that field. Companies were 'burnt' working on amphetamines and LSD. . . . They are afraid of notoriety." Clearly, cannabis acts on coordination of movement by way of the receptors in the cerebellum and basal ganglia, and on memory by way of the receptors in the limbic system's hippocampus, which "gates" information during memory consolidation. Mechoulam believes that in humans these actions "are rather marginal." "Cannabis," he states, "is used . . . for its actions on mood and emotion." The key to understanding the reason for the presence of cannabinoid receptors in the human brain lies in understanding the role of the receptors in the limbic system, which has a central role in the mechanisms which govern behavior and emotions. The limbic system coordinates activities between the visceral base-brain and the rest of the nervous system. "We know next to nothing on the chemistry of emotions," Mechoulam instructs. It is his hope that future research on the role of cannabinoid receptors in the brain will shed light on this new area of investigation and reflection.