Cannabis

Cannabis and Sleep

Based on archeological evidence;  the first use of cannabis may have been as early as the third millennium B.C.  However, the first evidence of medicinal use for cannabis for sleep is from around 400 AD. Chronic insomnia is present in 6%–15% of the population and is associated with adverse health effects.

 

Cannabis, and cannabis-based products, have a potential therapeutic role in the management of some common sleep disorders, such as insomnia, sleep apnea, and restless legs syndrome. Although research is limited, some studies support the use of cannabis to benefit some sleep disorders.

 

 

Links to other Pertinent Educational Pages:

Links to ALL Marijuana Educational Pages

Terpenes

Terpenes – An Overview

 

For in-depth information on the individual terpenes thought to benefit insomnia:

The medical information on this site is provided as a resource for information only, and is not to be used or relied upon for any diagnostic or treatment purposes and is not intended to create any patient-physician relationship.  Readers are advised to seek professional guidance regarding the diagnosis and treatment of their medical concerns.

 

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 This page is incomplete and is being developed… 

 

Cannabis and Sleep

To discuss and understand the impact  of cannabis and cannabis-based products on sleep, it is valuable to have a working knowledge of sleep stages and sleep physiology.

 

Sleep Cycles and Stages of Sleep

Ideally, one engages four to six cycles of sleep every 24 hours to feel fresh and rested. Each sleep cycle contains four individual stages: three that encompass non-rapid eye movement (NREM) sleep and one rapid eye movement (REM) sleep. Stages 1 through 3 are NREM sleep (N1, N2, and N3) and the 4th stage is REM sleep. In a sleep cycle, each NREM stage leads to progressively deeper sleep and an average sleep cycle lasts about 90 minutes.

 

NREM Sleep
Approximately 75% of sleep is spent in the three NREM stages, with the majority spent in the Stage 2 NREM sleep stage. The third stage of NREM is known as Slow-Wave Sleep (SWS) because brain activity during N3 is characterized by slow delta waves on an EEG.

Stage 1 NREM sleep is the lightest stage of sleep. Ones enter stage 1 right after falling asleep. This stage usually lasts only a few minutes, making up about 5% of one’s sleep time. After that, as sleep gets deeper, one moves into stage 2 NREM sleep.

Stage 2 NREM sleep is still light sleep, but deeper than stage 1. During this stage, brain waves slow down and there are noticeable pauses between short, powerful bursts of electrical activity. During  these bursts the brain  is organizing memories and information from the previous wakeful state. This stage accounts for about 45% of sleep time (the most of any stage). One passes through multiple rounds of stage 2 NREM sleep, with each round usually longer than the last. After stage 2, one usually moves deeper into stage 3 NREM sleep.

Stage 3 NREM sleep is also known as Slow-Wave Sleep (SWS) because brain activity during this stage is characterized by slow delta waves on an EEG. Stage 3 NREM is associated with moderate muscle tone and slow or absent eye movement. This stage is when it is most difficult to awaken someone from sleep, so Stage 3 NREM is often referred to as deep sleep. Because stage 3 NREM sleep is so deep, if one is awakened during this stage, they may experience a state of confusion or “brain fog” that may lasts up to 30 minutes.

Stage 3 NREM sleep is important for memory consolidation of learning material experienced during previous wake period including the conscious recall of facts and the ability to store and retrieve personal information and events. Stage 3 NREM is considered to be critical for restorative functions and maintenance of sleep. Without enough stage 3 NREM sleep, one feels tired and drained even if they slept for a long time. That’s why during sleep, if there has been sleep deprivation, the cycle automatically engages as much stage 3 sleep into the sleeping period as early as possible. The SWS stage determines sleep quality and is vital for waking up feeling revitalized.

Stage 3 NREM sleep usually lasts between 70 and 90 minutes, and the majority of slow-wave sleep happens early in the night. Most adults spend around 10% to 20% of their sleep in slow-wave sleep.

Drugs Known to Increase Slow Wave Sleep:

    • Gabapentin (Neurontin)
    • Pregabalin (Lyrica)
    • THC

 

REM Sleep (Rapid Eye Movement Sleep)

SWS and REM sleep are controlled by different mechanisms and have different functions. Moreover, these two sleep states occur preferentially during different parts of the sleep period: SWS is mainly located at the beginning of sleep whereas REM sleep occurs cyclically and is more often expressed at the end of the sleep
period.  It is controlled by short- and long-term homeostatic mechanisms determined by the circadian clock.

Following a period of slow-wave sleep the sleep stages continue to a quite different sleep state called rapid eye movement, or REM sleep. REM sleep is the stage of sleep where most dreams happen and it has similarities to wakefulness. Although muscles are fully relaxed, the brain acts somewhat like it is awake, with brain activity at the same overall intensity as in wakefulness. The eyes move rapidly behind the lids and breathing becomes shallow and rapid. Blood pressure and heart rate also increase during REM sleep but the arms and legs are deeply relaxed so that sleepers do not act out their dreams.

The first REM cycle of a sleep period is typically the shortest, around 10 minutes. Each REM cycle that follows is longer than the previous, and may last up to an hour. REM sleep makes up about 25% of total time asleep.

Spontaneous arousal from sleep is more likely to occur in REM sleep than in other sleep stages. Also, people instructed to wake at a specified time during the night, with no aid of an external alarm clock, mainly awaken from REM sleep. It appears that there is a continuum of increasing arousal levels that exists throughout NREM sleep, REM sleep and waking.

One theory of REM sleep function is that it provides periodic activation of the brain during sleep, without inducing wakefulness or disturbing the continuity of sleep and that the brain uses REM to help wake itself up after it has had a sufficient amount of sleep. Similarly, REM seems more likely to prepare for ensuing wakefulness than providing recovery from prior wakefulness, as happens with “deeper” SWS NREM.

Significance of REM sleep

Due to the fact that REM sleep is controlled by the circadian clock, it helps define the termination of the sleep period when there is still the necessity to complete the sleep cycle. An adequate amount of REM sleep is necessary to guarantee sleep continuity, while periodically activating the brain and preparing it for the return to consciousness. Physiological consequences of inadequate REM sleep include increased inflammation that contributes to oxidative stress, impairment of the immune system and increased sensitivity to pain.

 

A “Good Night’s Sleep”

A “good night’s sleep” (GNS) is a night with enough sleep to allow sufficient time for the restorative processes that sleep provides. Since the main function of sleep is to allow adequate wakeful functioning, a measure of a GNS can refer to the ability to stay fully awake and perform adequately during the day. It should be noted that sleep adequacy influences not only daytime wakefulness, it contributes to the ability to make decisions, solve problems, control emotions and behavior, and cope with change. Sleep deficiency is linked to feeling sad, depression, anger, impulsiveness, mood swings and lack of motivation. While an individual may be able to identify a good night’s sleep (GNS) when experienced, establishing a measure of GNS based on sleep staging is more elusive.

Total sleep time appears to be the natural measure of a GNS but it is more complicated than that. For example, many people, including those with fibromyalgia or untreated sleep apnea will describe their sleep as “non-restful” despite a seemingly “full night sleep” (7-8 hours for most people). Thus sleep quality can be as important as sleep duration and can influence not only daytime functioning but can significantly affect cognitive abilities and mental health..

Also, it should be emphasized that habitual sleep duration in the neighborhood of 7-8 hours is achieved only by a limited number of individuals in the general population, with many people consistently sleeping less than 6 hours per night, thus living in a state of chronic sleep deprivation. Even a duration of 7-8 hours may sometimes not be sufficient for the completion of sleep’s restorative process. Reduction in a night’s sleep period by as little as 1 – 1-1/2 hours for one night can result in a reduction in daytime alertness by as much as 32%.

 

Sleep Quality, SWS and Daytime Functioning

Since the main function of sleep is to support wakeful functioning, a measure of sleep quality can also refer to the ability to stay fully awake and adequately maintain cognitive functions such as memory, thought processing, judgement and critical decision making.

Based on sleep’s role in providing recovery from the previous wake period and the role of the SWS stage in memory consolidation etc., SWS is generally considered the main sleep component necessary to satisfy homeostatic maintenance needed to provide good cognitive performance the following day.

 

Sleep Quality, REM and Daytime Functioning

While  slow-wave sleep may be the core sleep component, adequate REM sleep is also essential. It is believed that we are experiencing “a silent epidemic of REM sleep deprivation” in which we are at least as dream deprived as we are sleep deprived. REM sleep deprivation contributes to illness, depression, and an erosion of consciousness. Sleep deprivation studies (sleep limited to 6 hours ) show that after a primary reduction in REM sleep, there is a follow-up rebound phenomenon of increased REM sleep with restoration of sleep time.  An adequate amount of REM sleep is necessary to guarantee sleep continuity, while periodically activating the brain and preparing it for the return to consciousness.

 

Sleep Disorders

Conditions that disrupt sleep or wakefulness are called sleep disorders. There are six main categories of sleep disorders:

  • Insomnia.
  • Sleep-disordered breathing (such as sleep apnea)
  • Circadian rhythm sleep-wake disorders (such as jet lag or shift work sleep disorder)
  • Central disorders of hypersomnolence (like narcolepsy).
  • Sleep-related movement disorders (like restless leg syndrome).
  • Parasomnias.

Insomnia

Insomnia is very common problem resulting from many conditions including shift work, poorly controlled pain, anxiety and stress.  Sleep deprivation has a negative impact on endocrine, metabolic, cardiovascular, immune, thought processing and neurological function. Evidence indicates that sleep deprivation involves a temporary activation of the major neuroendocrine stress systems. Sleep deprivation impairs memory, especially REM-sleep deprivation.

 

Cannabis for Insomnia

Cannabis may impact insomnia but research is limited regarding which constituents in cannabis provide specific benefits for insomnia. Most research at this time has been focused on the cannabinoids, especially THC and CBD. It is likely that various terpenes also play a role but less is known about them. While some studies show that cannabis use decreases insomnia severity, most research has shown mixed results.

 

Cannabinoids

The effect of cannabinoids (THC and CBD) on sleep and insomnia is dose dependent but also influenced by which cannabinoid and what combinations as well as their dose and frequency of use.

 

THC

Acute exposure/short-term use of THC:
With short-term use, THC may reduce the time it takes to fall asleep (sleep onset latency – SOL), increase total sleep time (TST), and decrease waking up after sleep onset (WASO). Short-term use of THC decreases REM sleep and increases slow wave sleep (SWS). However, these effects on slow wave sleep and total sleep time do not tend to persist over time.

Long-term use of THC:
In contrast to short-term use, chronic use of of THC may increase sleep disruption by increasing time needed to fall asleep and increasing waking during sleep resulting in decreased overall sleep time.

In one study, the majority of participants with long-term use show decreased overall sleep time (78%), with increased time it takes to fall asleep (>30 min), poor sleep efficiency, the percentage of time spent asleep while in bed (<85%), and increased waking up after sleep (54.7%). Additionally the study suggested chronic THC use increases sleep time prior to starting REM stage – average 114.5 min) as well as decreased percentage of REM sleep (17.7%).


Effects of THC Withdrawal:

THC/cannabis withdrawal, is associated with sleep disturbances and vivid dreams.as well as lower total sleep time, decreased slow wave sleep needed to feel revitalized and decreased sleep time prior to starting REM stage. One study also showed longer sleep onset and worse sleep efficiency. Another study also showed an increase in periodic limb movements (PLMs) after abrupt discontinuation of heavy marijuana use. Withdrawal-related sleep disturbances is worse among heavy users with onset in about 24–72 hours after discontinuation use and can persist up to 6– 7 weeks. Given these duration-dependent variable effects on sleep architecture, the role of cannabinoids in sleep disorders remains under investigation.

 

CBD

A 2022 systematic review based on very limited research on the therapeutic benefits of CBD in the management of insomnia concluded that CBD alone or with equal quantities of THC may be beneficial in alleviating the symptoms of insomnia.

Research regarding effects of CBD on sleep stages are limited. Animal studies show an increase in total percentage of sleep, with a decrease in REM latency at lower doses and an increase in REM latency at higher doses. At this time, there are a lack of human studies collaborating these findings. One recent controlled trial did show increased sleepiness based on subjective assessment in subjects who used CBD- dominant cannabis, but it is unclear if this was due to the small amount of THC in it. Animal studies suggest that its effectiveness depends on the dose. CBD at a variety of doses helps sleep, but lower doses may allow for falling asleep faster.

Chronic effects of CBD are yet to be studied. Thus, studies on the isolated effects of CBD on sleep architecture are limited and mostly have mixed results. CBD use has been shown to increase total sleep with mid to high doses in animal studies. There is a dose- dependent effect on REM sleep latency—with higher doses causing an increase in latency while mid-range doses yield a decrease. Another study found that CBD had a positive effect on anxiety-related REM sleep suppression but no effect in the NREM phase.

A 2024 study  explored the effectiveness of 150 mg CBD compared with placebo as a sleep aid in primary insomnia. Insomnia severity, self-reported sleep-onset latency, sleep efficiency, and wake after sleep onset did not differ between treatments throughout the trial . Compared with placebo, the CBD group reported greater well-being scores throughout the trial and had superior objective sleep efficiency after 2 weeks of treatment but no other significant treatment effects were observed. It was concluded that nightly supplementation of 150 mg CBD was similar to placebo regarding most sleep outcomes except sustaining greater well-being. Unfortunately this study did not evaluate higher doses of CBD that are often required for successful treatment of anxiety with CBD.

There is growing evidence of improvement in insomnia symptoms secondary to chronic conditions such as fibromyalgia.

 

CBN

CBN is a minor cannabinoid promoted for its sedative effects which are thought to be enhanced when combined with THC. Research that suggests it may promote healthy sleep is limited.

 

Combined THC and CBD
Studies of CBD in combination with THC have shown that CBD has more alerting effects and tends to counteract the sedative effects of THC especially at higher doses. However, definitive findings are inconclusive because most of the studies evaluating effects of cannabis and cannabinoids are limited by differences in study designs, sample sizes, and procedures, as well as the ratios of THC to CBD used.

A 2023 crossover study  evaluating a medicinal cannabis oil on sleep in adults with insomnia.  A total of 29 participants received placebo or active oil containing 10 mg/ml THC) and 15 mg/ml cannabidiol (CBD) over 2-weeks titrated 0.2-1.5 ml/day (2 – 15 mg THC with 3 – 22.5 mg CBD), followed by a 1-week wash-out period before crossover. The cannabis oil was well tolerated, and effective in improving sleep, with 60% of participants no longer having clinical insomnia at the end of the 2-week intervention period. Midnight salivary melatonin levels significantly improved in the active group by 30% compared to a 20% decline in the placebo group. The cannabis oil improved both time and quality of sleep improved overall by up to 80% in the active group, including higher daily functioning. The study concluded that cannabis oil was well tolerated and effective in improving sleep in adults with insomnia.

 

Combined THC, CBD and CBN

Another crossover, placebo controlled study published in 2021 assessed the use of a multi-cannabinoid medication  containing THC, CBD and CBN. The test medication contained THC 20 mg/mL, CBN 2 mg/mL, CBD 1 mg/ mL and naturally occurring terpenes, extracted from a cannabis plant.  The placebo contained the same terpenes, but no cannabinoids, extracted from the same cannabis plant. Participants were given 0.5-1 ml sublingually for the study  (up to 20 mg THC, 2 mg CBN and 1 mg CBD).

The average total time spent asleep each night increased by 33.5 minutes and sleep efficiency increased by 2.9%–84.8%. The mean total time spent asleep across the 2-week period was over 7 hours while taking the medication (the recommended minimum sleep duration for adults, and above average for individuals of comparable age without insomnia).

Their data also suggested that for patients with sleep onset insomnia dosing 2–4 hours before desired bedtime might be optimal, while those with sleep maintenance insomnia should dose 1 hour before desired bedtime. It was concluded that nightly sublingual use of this cannabinoid formulation for 2 weeks improved insomnia symptoms without significant adverse events.

 

 

Terpenes

While the cannabinoids THC, CBD and CBN may play dominant roles in how cannabis impacts insomnia, some strains do appear to offer more benefits than others outside of their cannabinoid profiles, suggesting the likelihood that the terpene profile of a cannabis strain is important but research is lacking for definitive answers. A number of terpenes are promoted to help sleep, including linalool, myrcene and caryiphyllene as well as possibly pinene, limonene, terpineol, terpinolene, and phytol.

The following terpenes are likely the most important for insomnia:

Linalool

Linalool is the dominant terpene found in lavender oil and is present in many cannabis strains known for their benefit for sleep and anxiety. It is postulated that that linalool improves the impairments caused by memory loss following REM-sleep deprivation. It is likely that linalool has the ability to improve the behavioral impairments of REM-sleep deprivation via serotonin which is related to the inhibition of sleep and the promotion of wakefulness.

 

Myrcene

Myrcene is generally considered the most important terpene to facilitate sleep so selecting a myrcene-dominant strain appears to be a reasonable choice at this time.

 

Cannabis Strains

In a 2018 study referenced above regarding cannabis strain preferences, the following 15 cannabis strains were preferred by patients using cannabis for insomnia:

    1. Lemon Sour Diesel (20 patients; 13.8% of respondents)
    2. OG shark (15; 10.4%)
    3. Skywalker OG (13; 9%)
    4. Pink Kush (12; 8.3%)
    5. Jack Herer (10; 6.9%)
    6. White Widow (9; 6.2%)
    7. Afghani (8; 5.5%)
    8. Indica House Blend (7; 4.8%)
    9. Sweet Skunk CBD (7; 4.8%)
    10. Island Sweet Skunk (7; 4.8%)
    11. Black Tuna (7; 4.8%)
    12. Jean Guy (6; 4.1%)

Click here for a breakdown of the constituents of these 15 preferred cannabis strains for insomnia

 

Insomnia Associated with Fibromyalgia (FM)

Insomnia is frequently comorbid with various chronic pain disorders, especially fibromyalgia (FM). Between 60% to 80% of patients with FM complain of sleep impairment, most typically manifesting as a sleep maintenance problem and confirmed with polysomnography (PSG). Sleep is also frequently described as non-restful in FM, with persisting symptoms of daytime sleepiness and fatigue, which is likely related to the disturbed sleep cycles of fibromyalgia.

The PSG studies in fibromyalgia have consistently identified reduced total sleep time (TST), primarily due to increased wake after sleep onset (WASO). However, despite having reduced nocturnal sleep and reporting elevated levels of daytime sleepiness and fatigue, patients with fibromyalgia show elevated daytime arousal based on objective measures of daytime sleepiness/alertness. This elevated daytime arousal is consistent with the sensory hypersensitization associated with FM.

The relation of sleep and pain is bidirectional; acute and chronic pain are associated with disturbed sleep and disturbed sleep worsens pain. Research has shown that reduced and fragmented sleep in pain-free individuals increases their pain sensitivity and in patients with chronic pain, a poor night of sleep is followed by worsened next-day pain. Analyses of large clinical datasets found that the sleep-pain side of the bi- directional relation, as opposed to the pain-sleep side, accounts for the greater impact. In other words, disturbed sleep is more detrimental, suggesting that improving sleep in those with chronic pain should reduce daytime pain and emphasizes the importance of treating insomnia in FM.

 

Cannabis and Insomnia in FM

A 2020 study, assessed clinical iprovement attributable to the addition of medical cannabis treatment (MCT) to a stable (≥3 months) standard analgesic treatment of fibromyalgia.  Significant functional improvement (44%) and sleep improvement (33%) was observed.as well as 50% who showed moderate improvement in anxiety and depression scales.
One-third of the participants experienced mild adverse events, which did not cause any significant treatment modifications.

Of interest, the clinical improvement was inversely correlated with BMI (a measure of obesity). In other words, clinical improvements were less the more obese an individual was. This correlation may be related to cannabinoid liposolubility where patients with higher BMI need higher doses because of the drug’s pharmacokinetics. Also, BMI influences peripheral and neuroinflammation which play a significant role in the development and maintenance of FM, which has both centrally and peripherally mediated mechanisms of pain magnification.

 

THC and Insomnia in FM

Multiple studies have assessed theuse  of cannabis for the many symptoms of FM, including sleep disturances, and have demonstrated many benefits.  See Cannabis – Fibromyalgia.

Of interest, however, is research directed at the treatment of insomnia with a relatively new category of hypnotics that are orexin receptor antagonists. Orexin is involved in arousal and maintenance of the waking state and the antagonism of orexin receptors has beeen shown to benefit those with insomnia. Because fibromyalgia is associated with central hyperarousal and hypersensitization, orexin antagonism may be expected to be especially effective in not only FM-related insomnia but also comorbid FM symptoms of daytime pain hypersensitivity, sleepiness and fatigue.

A recent study assessed the orexin receptor antagonist, suvorexant, for objective and self-report measures of sleep, pain, and daytime sleepiness and fatigue in patients with fibromyalgia and comorbid insomnia. The researchers concluded that in patients with fibromyalgia with comorbid insomnia, suvorexant improved sleep which was associated with a modest reduction of pain sensitivity. Suvorexant increased sleep time by approximately 30 minutes relative to placebo and by 80 minutes relative to baseline.

A 2020 study evaluating suvorexant demonstrated increased total sleep time (7.2 versus 6.7 hours) and reduced wake after sleep onset (37 versus 67 minutes) with no night effects or other interaction.  Latency to persistent sleep and sleep stage measures were not altered. The researchers concluded that in patients with fibromyalgia, suvorexant 20 mg improved sleep time and reduced next-day pain sensitivity.

This may be significant in that early research indicates that there is crosstalk between the orexinergic and the endocannabinoid systems and an overlapping distribution of CB1 and orexin receptors in several brain areas. This suggests a possible mechanism of action for cannabinoids benefits for fibromyalgia, including insomnia. There is also research establishing CBD as an Orexin-1 antagonist.

 

How cannabinoids and terpenes may enhance sleep

To begin with, a substance than can induce calm and relaxation or reduce anxiety will indirectly promote sleep. However, research is investigating the mechanisms by which these compounds may directly interact with sleep mechanisms and impact various stages of sleep such as SWS and REM sleep.

One mechanism by which terpenes may facilitate sleep is by activating the body’s GABA system. GABA is an amino acid produced in the brain that functions as a neurotransmitter to facilitate communication between brain cells.
It is the body’s most important inhibitory neurotransmitter, in that it reduces activity of nerves in the brain and spinal cord.  By inhibiting nerve activity, GABA helps initiate sleep, decrease stress and reduce anxiety.  Some terpenes that have sedative and anti-anxiety effects, including phytol and alpha-pinene, have been shown to work at least in part by activating the brain’s GABA system.

 

 

Obstructive Sleep Apnea and Central Sleep Apnea

Obstructive sleep apnea (OSA)

The majority of people with obstructive sleep apnea (OSA) are either undiagnosed or untreated. OSA is a very common sleep-related breathing disorder mostly associated with obesity, increasing age and people with short, thick necks and narrowed airways. Symptoms usually include snoring and daytime sleepiness with a tendency to fall asleep inappropriately easily and a sense of chronic fatigue. OSA can be worsened with alcohol consumption and snoring can be improved with sleeping on one’s side. Treatment generally includes weight loss, use of positive pressure airway devices including CPAP and BiPAP.  Surgical procedure can sometimes reverse airways with anatomic obstruction and there is a new procedure involving implantation into the upper airway of a device that maintains patency of the airway during sleep.

 

Understanding OSA

In OSA the airway becomes markedly narrowed when muscles in the throat relax during deeper stages of sleep, causing reduced flow of air due to the narrowed airway. Snoring, the hallmark of OSA, is the sound of these relaxed throat muscles vibrating as air passes through the narrowed airway.

This reduced airflow causes a drop in oxygen during deeper stages of sleep which then triggers receptors in the brain that in turn kick people out of their deep sleep into the lighter stages of sleep with less muscle relaxation and improved airflow. Snoring stops, oxygen levels improve initially, but over the next few minutes the person cycles into the deeper sleep stages and snoring returns.

This repetitive cycle of interrupted sleep staging can occur literally hundreds of times in the night without ever awakening, so the individual is unaware of the problem. Unfortunately, without adequate deep, restorative sleep  necessary for healthy brain functioning, the individual experiences chronic fatigue and impaired cognitive functioning. This quality sleep deprivation contributes to anxiety, depression and impaired pain control in those with chronic pain.

Furthermore, the frequent episodes of reduced oxygen during sleep triggers physiologic responses that contribute to elevated blood sugars, weight gain and high blood pressure, all factors that enhance risk for cardiovascular diseases. As such, treatment of OSA is very important but unfortunately the use of CPAP is commonly not tolerated resulting in lack of treatment.

Although a new procedure implanting a device in the airway shows great promise, there are no medications currently available that can treat OSA. But there is some evidence that THC may improve OSA.

 

Central Sleep Apneas (CSA)

Central sleep apnea (CSA) is caused by suppression of respiratory drive during sleep which may be caused by stroke or neurologic injury but is most commonly associated with the use of sedative medications, especially opioids, benzodiazepines (Xanax, Valium etc.) and alcohol. Accidental overdose deaths are often attributed to the use of these medications together. But in fact, a significant number of accidental overdose deaths blamed on the use of these medications is found in people with untreated OSA. The reduced blood oxygern levels associated with untreated OSA makes people more vulnerable to the respiratory depression caused by these medications, contributing to the fatalities.

 

Treatment

Currently, these conditions are primarily treated with positive airway pressure (PAP) therapy which is often not tolerated. This has led to investigation of other potential therapeutic alternatives. Multiple medications have been investigated but none have much therapeutic potential. Recently, there has been increased interest in the use of cannabinoids and there have been some preliminarily promising results.

In animal studies, cannabinoids have been shown to reduce apneas however, they decrease REM sleep and sleep efficiency. Studies  suggest a role of CB1 and CB2 receptors in suppressing apneas.. In human stud- ies, dronabinol (a synthetic THC) has been shown to decrease apnea  and subjective sleepiness in a placebo- controlled trial. Though preliminary human data is promising, more studies are needed.

 

Post-Traumatic Stress Disorder–Related Nightmares

Post-traumatic stress disorder (PTSD) is commonly associated with a range of sleep disturbances including insomnia, nightmares, and periodic limb movements. These sleep disturbances can further worsem PTSD symptoms.

Nightmares can be difficult to treat and few medications are recommended, including prazosin as a first-line choice. PTSD pathophysiology is linked to dysregulation of serotonin and noradrenaline as well as endogenous cannabinoids and opioids. With their known benefit for anxiety and their effect on the ECS, cannabinoids have potential for treatment of PTSD-related sleep problems.

THC and Nabilone

Although most research is of limited quality, one open-labeled study of THC in chronic PTSD found improvement in sleep quality and decreased nightmares. More data is needed to recommend routine use of THC for PTSD nightmares.

Nabilone, a synthetic cannabinoid similar to THC, has been studied for nightmares in PTSD patients and have shown improvement in insomnia and nightmares. Another study on treatment-resistant PTSD patients showed reduction in intensity of nightmares while improving sleep quality and timeas well as decreasing flashbacks. A small placebo-controlled trial ofnabilone also showed reduction in nightmares.

CBD

Research evaluating CBD for treatment of insomnia in patients with post-traumatic stress disorder (PTSD) showed decreased sleep disturbances.  A crossover study with nabilone demonstrated increased sleep efficiency and total sleep time as well as decreased awakenings, however, there was increased time for sleep onset.

 

Restless Leg Syndrome (RLS)

Restless leg syndrome (RLS) is a sleep-related movement disorder characterized by an unpleasant urge to move the legs and sometimes arms, worsened by inactivity and relieved by movement. This condition is often associated with a sleep-related movement disorder—periodic limb movement of sleep (PLMS).

There is limited evidence for cannabinoids use to treat RLS. Two small case series, one including 6 patients and another with 12 patients who continued previously prescribed medications for RLS while adding marijuana showed near total remission in RLS with recreational marijuana smoking.

RLS is thought to be related to several central neurotransmitters, especially dopamine but also including glutamate, gamma-aminobutyric acid (GABA), and endogenous opioid. Dopamine agonists have been a mainstay of treatment in addition to anticonvulsants and opiates.

Parasomnias

Parasomnias can vary widely. Some affect NREM sleep only, while others affect REM sleep only. Organized by possible NREM or REM stage, they include:

Stages 1 and 2 NREM sleep:

    • Sleep Myoclonus (Sleep starts or twitches )
    • Teeth grinding (bruxism)
    • Periodic limb movement disorder (PLMD)
    • Exploding Head Syndrome (EHS) is a sleep disorder that sounds painful, but isn’t. With EHS one hears a loud noise or explosion in one’s head but the sound isn’t real or heard by others. It happens as one is falling asleep or when waking up during the night. EHS is harmless and is not a sign of another serious health condition and it does not usually require treatment.

Stage 3 NREM sleep

    • Night terrors (also known as sleep terrors).
    • Sleepwalking (somnambulism).
    • Periodic limb movement disorder (PLMD).
    • Sleep-related eating disorder.

REM sleep

    • Nightmares
    • REM sleep behavior disorder.
    • Hypnagogic and hypnopompic hallucinations.

 

 

Resources:

National Academy of Sciences

The Health Effects of Cannabis and Cannabinoids: The Current State of Evidence and Recommendations for Research

 

www.Healer.com

This website appears to be good resource for exploring medical marijuana.

 

References:

   

Sleep

  1. REM Sleep- An Unknown Indicator of Sleep Quality – 2021
  2. Neuropsychopharmacological Induction of (Lucid) Dreams- A Narrative Review – 2024

Sleep – Cannabis

  1. Effects of Cannabinoids on Sleep and their Therapeutic Potential for Sleep Disorders – 2021
  2. Medicinal cannabis improves sleep in adults with insomnia a randomised double-blind placebo-controlled crossover study – PubMed – 2022
  3. Treating insomnia symptoms with medicinal cannabis- a randomized, crossover trial of the efficacy of a cannabinoid medicine compared with placebo – 2021

Sleep – CBD

  1. Use of Cannabidiol in the Management of Insomnia A Systematic Review – PubMed. – 2022
  2. Cannabidiol for moderate-severe insomnia a randomized controlled pilot trial of 150 mg of nightly dosing – PubMed – 2024
  3. Cannabidiol as an OX1R Antagonist – 2021
  4. Involvement of the orexin hypocretin system in the pharmacological effects induced by Δ9 -tetrahydrocannabinol – 2016

 

Sleep – Fibromyalgia

  1. Involvement of the orexin hypocretin system in the pharmacological effects induced by Δ9 -tetrahydrocannabinol – 2016
  2. Sleep and pain in humans with fibromyalgia and comorbid insomnia- double-blind, crossover study of suvorexant 20 mg versus placebo – 2020
  3. Adding medical cannabis to standard analgesic treatment for fibromyalgia: a prospective observational study 2020
  4. Involvement of the orexin hypocretin system in the pharmacological effects induced by Δ9 -tetrahydrocannabinol – 2016

Sleep – Linalool

  1. GS12-linalool
  2. Linalool – 1997
  3. The “Entourage Effect”: Terpenes Coupled With Cannabinoids for the Treatment of Mood Disorders and Anxiety Disorders – PubMed – 2020
  4. An olfactory stimulus modifies nighttime sleep in young men and women. – PubMed – NCBI
  5. Lavender and sleep – A systematic review of the evidence – 2012
  6. Lavender and the Nervous System – 2013
  7. Effects of odorant administration on objective and subjective measures of sleep quality, post-sleep mood and alertness, and cognitive performance – 2003
  8. In-vitro inhibition of human erythrocyte acetylcholinesterase by salvia lavandulaefolia essential oil and constituent terpenes. – PubMed – NCBI – 2000
  9. Odors enhance slow-wave activity in non-rapid eye movement sleep – 2016
  10. A question of scent – lavender aroma promotes interpersonal trust – 2015
  11. Is Lavender an Anxiolytic Drug? A Systematic Review of Randomised Clinical Trials – 2012
  12. Efficacy of Silexan in subthreshold anxiety – meta-analysis of randomised, placebo-controlled trials – 2019
  13. Essential oil of lavender in anxiety disorders – Ready for prime time? – 2017
  14. Linalool is a PPAR ligand that reduces plasma TG levels and rewires the hepatic transcriptome and plasma metabolome – 2014
  15. A Review of the Potential Use of Pinene and Linalool as Terpene-Based Medicines for Brain Health – Discovering Novel Therapeutics in the Flavours and Fragrances of Cannabis – 2021
  16. The Efficacy of Lavender Aromatherapy in Reducing Preoperative Anxiety in Ambulatory Surgery Patients Undergoing Procedures in General Otolaryngology – 2017
  17. Efficacy, Safety and Tolerability of Aroma Massage with Lavender Essential Oil – an Overview – 2020
  18. Antinociceptive and anticonvulsant effects of the monoterpene linalool oxide – 2017
  19. Exploring Pharmacological Mechanisms of Lavender (Lavandula angustifolia) Essential Oil on Central Nervous System Targets – 2017
  20. Linalool Ameliorates Memory Loss and Behavioral Impairment Induced by REM-Sleep Deprivation through the Serotonergic Pathway – 2018
  21. Effects of lavender on anxiety, depression and physiologic parameters – Systematic Review and Meta-Analysis – 2021
  22. Lavender and sleep – A systematic review of the evidence – 2012
  23. Lavender and the Nervous System – 2013
  24. A question of scent – lavender aroma promotes interpersonal trust – 2015
  25. Enhancing Effect of Chiral Enhancer Linalool on Skin Permeation of Naproxen – PubMed – 2018

 

Sleep – Restless Legs Syndrome

  1. Treatment of Sleep, Motor and Sensory Symptoms with the Orexin Antagonist Suvorexant in Adults with Idiopathic Restless Legs Syndrome – PubMed 2024

 

 

Terpenes – Overviews

  1. Therapeutic and Medicinal Uses of Terpenes – 2019
  2. Terpenes:Terpenoids in Cannabis – Are They Important? – 2020
  3. Advances in Pharmacological Activities of Terpenoids – 2020
  4. Terpenoids, Cannabimimetic Ligands, beyond the Cannabis Plant – 2020
  5. The Cannabis Terpenes – 2020
  6. The “Entourage Effect” – Terpenes Coupled with Cannabinoids for the Treatment of Mood Disorders and Anxiety Disorders – 2020
  7. Cannabis Essential Oil – A Preliminary Study for the Evaluation of the Brain Effects – 2018
  8. A Systematic Review of Essential Oils and the Endocannabinoid System – A Connection Worthy of Further Exploration – 2020
  9. Efficacy of Essential Oils in Pain – A Systematic Review and Meta-Analysis of Preclinical Evidence – 2021

 

Terpenes – Aromatherapy

  1. Aromatherapy and Aromatic Plants for the Treatment of Behavioural and Psychological Symptoms of Dementia in Patients with Alzheimer’s Disease Clinical Evidence and Possible Mechanisms – 2017
  2. Corrigendum – A question of scent – lavender aroma promotes interpersonal trust -2015
  3. Odors enhance slow-wave activity in non-rapid eye movement sleepOdors enhance slow-wave activity in non-rapid eye movement sleep
  4. Essential Oils and Animals – Which Essential Oils Are Toxic to Pets?
  5. Essential Oils and Pets
  6. Herbs and Their Uses for Animals – Patchouli and Pets
  7. Reactivating memories during sleep by odors – odor specificity and associated changes in sleep oscillations – 2014
  8. Increasing Explicit Sequence Knowledge by Odor Cueing during Sleep in Men but not Women – 2016
  9. Effects of odorant administration on objective and subjective measures of sleep quality, post-sleep mood and alertness, and cognitive performance – 2003
  10. An Olfactory Stimulus Modifies Nighttime Sleep in Young Men and Women – 2005
  11. Massage with or without aromatherapy for symptom relief in people with cancer. – PubMed – NCBI
  12. Aromatherapy hand massage for older adults with chronic pain living in long-term care. – PubMed – NCBI
  13. A Systematic Review of Essential Oils and the Endocannabinoid System – A Connection Worthy of Further Exploration – 2020
  14. Human olfactory receptors – novel cellular functions outside of the nose,” – 2017
  15. The diversified function and potential therapy of ectopic olfactory receptors in non-olfactory tissues – PubMed – 2017
  16. How does your kidney smell? Emerging roles for olfactory receptors in renal function,” – 2017
  17. The Effects of Essential Oils and Terpenes in Relation to Their Routes of Intake and Application – 2020
  18. Pharmacology of Natural Volatiles and Essential Oils in Food, Therapy, and Disease Prophylaxis – 2021

 

Terpenes – CB2 Receptor

  1. Cannabinoid-based therapy as a future for joint degeneration. Focus on the role of CB2 receptor in the arthritis progression and pain – an updated review – 2021
  2. β-Caryophyllene, a CB2 receptor agonist produces multiple behavioral changes relevant to anxiety and depression in mice – 2014
  3. The CB2 receptor and its role as a regulator of inflammation – 2016

 

Terpenes – Synergy with Cannabinoids:

  1. Taming THC – potential cannabis synergy and phytocannabinoid-terpenoid entourage effects – 2011
  2. A tale of two cannabinoids: the therapeutic rationale for combining tetrahydrocannabinol and cannabidiol. – PubMed – NCBI
  3. Entourage Effect 2.0
  4. Cannabis and the Anxiety of Fragmentation—A Systems Approach for Finding an Anxiolytic Cannabis Chemotype – 2018
  5. Terpenoids and Phytocannabinoids Co-Produced in Cannabis Sativa Strains Show Specific Interaction for Cell Cytotoxic Activity – 2019
  6. Absence of Entourage – Terpenoids Commonly Found in Cannabis sativa Do Not Modulate the Functional Activity of Δ9-THC at Human CB1 and CB2 Receptors – 2019
  7. Terpenoids From Cannabis Do Not Mediate an Entourage Effect by Acting at Cannabinoid Receptors – 2020
  8. The “Entourage Effect” – Terpenes Coupled with Cannabinoids for the Treatment of Mood Disorders and Anxiety Disorders – 2020

 

Terpenes – Marijuana Strains

  1. Patterns of medicinal cannabis use, strain analysis, and substitution effect among patients with migraine, headache, arthritis, and chronic pain in a medicinal cannabis cohort – 2018
  2. Terpenoid Chemoprofiles Distinguish Drug-type Cannabis sativa L. Cultivars in Nevada – 2018
  3. Terpenoids and Phytocannabinoids Co-Produced in Cannabis Sativa Strains Show Specific Interaction for Cell Cytotoxic Activity – 2019
  4. Identification of Terpenoid Chemotypes Among High (−)-trans-Δ9- Tetrahydrocannabinol-Producing Cannabis sativa L. Cultivars 0 2017
  5. The Cannabinoid Content of Legal Cannabis in Washington State Varies Systematically Across Testing Facilities and Popular Consumer Products – 2018

 

Terpenes – Routes of Use:

  1. The Effects of Essential Oils and Terpenes in Relation to Their Routes of Intake and Application – 2020
  2. Antiviral effect of phytochemicals from medicinal plants – Applications and drug delivery strategies – 2020
  3. Cannabinoid Delivery Systems for Pain and Inflammation Treatment – 2018

 

Terpenes – Bioavailability

  1. Bioavailability and Pharmacokinetics of Natural Volatile Terpenes in Animals and Humans – 2000
  2. Bioavailability of Bioactive Compounds
  3. SPC Liposomes as Possible Delivery Systems for Improving Bioavailability of the Natural Sesquiterpene β-Caryophyllene – 2018

 

Terpenes – Arthritis

  1. Evaluation of the anti-inflammatory, anti-catabolic and pro-anabolic effects of E-caryophyllene, myrcene and limonene in a cell model of osteoarthritis. – 2015

 

Terpenes – Anxiety

  1. Cannabis and the Anxiety of Fragmentation—A Systems Approach for Finding an Anxiolytic Cannabis Chemotype – 2018
  2. The “Entourage Effect”: Terpenes Coupled With Cannabinoids for the Treatment of Mood Disorders and Anxiety Disorders – PubMed – 2019
  3. Medicinal cannabis for psychiatric disorders – a clinically-focused systematic review – 2020
  4. A Systematic Review of the Anxiolytic-Like Effects of Essential Oils in Animal Models – 2015
  5. A Systematic Review on the Anxiolytic Effect of Aromatherapy during the First Stage of Labor – 2019
  6. A Systematic Review on the Anxiolytic Effectsof Aromatherapy in People with Anxiety Symptoms – 2011
  7. Anxiolytic Terpenoids and Aromatherapy for Anxiety and Depression – PubMed – 2020
  8. Effect of Aromatherapy on Dental Anxiety Among Orthodontic Patients – A Randomized Controlled Trial – 2019
  9. Essential Oils and Their Constituents – An Alternative Source for Novel Antidepressants – 2017
  10. Essential Oils and Their Constituents Targeting the GABAergic System and Sodium Channels as Treatment of Neurological Diseases – 2018
  11. Possible Use of Phytochemicals for Recovery from COVID-19-Induced Anosmia and Ageusia – 2021
  12. The calming effect of roasted coffee aroma in patients undergoing dental procedures – 2021
  13. The Effect of Lavender Aroma on Anxiety of Patients Having Bone Marrow Biopsy- 2020
  14. The-Effects-of-Essential-Oils-and-Terpenes-in-Relation-to-Their-Routes-of-Intake-and-Application-2020
  15. Therapeutic Effect and Mechanisms of Essential Oils in Mood Disorders – Interaction between the Nervous and Respiratory Systems – 2021
  16. Anxiolytic-Like Effects of Bergamot Essential Oil Are Insensitive to Flumazenil in Rats – 2019

 

Terpenes – Infectious Diseases

  1. Phytochemical Analysis and in vitro Antiviral Activities of the Essential Oils of Seven Lebanon Species – 2008
  2. Antiviral effect of phytochemicals from medicinal plants – Applications and drug delivery strategies – 2020
  3. Essential Oils and Coronaviruses – 2020

 

Terpenes – Pain:

  1. Analgesic-like Activity of Essential Oils Constituents – 2011
  2. Analgesic-Like Activity of Essential Oil Constituents – An Update – 2017
  3. Medicinal Plants of the Family Lamiaceae in Pain Therapy – A Review – 2018
  4. Analgesic Potential of Essential Oils – 2016
  5. Medicinal Plants of the Family Lamiaceae in Pain Therapy – A Review – 2018
  6. Patterns of medicinal cannabis use, strain analysis, and substitution effect among patients with migraine, headache, arthritis, and chronic pain in a medicinal cannabis cohort – 2018
  7. Terpenoids, Cannabimimetic Ligands, beyond the Cannabis Plant – 2020
  8.  The Molecular Mechanisms That Underpin the Biological Benefits of Full-Spectrum Cannabis Extract in the Treatment of Neuropathic Pain and Inflammation – PubMed – 2020
  9. Cannabis-based medicines and the perioperative physician – 2019
  10. Cannabis‐based medicines for chronic neuropathic pain in adults – 2018
  11. Medicinal Properties of Cannabinoids, Terpenes, and Flavonoids in Cannabis, and Benefits in Migraine, Headache, and Pain – An Update on Current Evidence and Cannabis Science – 2018
  12. Role of Cannabinoids and Terpenes in Cannabis-Mediated Analgesia in Rats – PubMed – 2019
  13. Antinociceptive effect of inhalation of the essential oil of bergamot in mice – 2018
  14. Analgesic Potential of Essential Oils – 2016
  15. Analgesic-Like Activity of Essential Oil Constituents – An Update – 2017

 

 

Terpenes – Headaches:

  1.  Medicinal Properties of Cannabinoids, Terpenes, and Flavonoids in Cannabis, and Benefits in Migraine, Headache, and Pain – An Update on Current Evidence and Cannabis Science – 2018
  2. Patterns of medicinal cannabis use, strain analysis, and substitution effect among patients with migraine, headache, arthritis, and chronic pain in a medicinal cannabis cohort – 2018

 

Terpenes – Inflammation:

  1. Evaluation of the anti-inflammatory, anti-catabolic and pro-anabolic effects of E-caryophyllene, myrcene and limonene in a cell model of osteoarthritis. – 2015 
  2. Cannabis sativa L. and Nonpsychoactive Cannabinoids – Their Chemistry and Role against Oxidative Stress, Inflammation, and Cancer – 2018
  3. Patterns of medicinal cannabis use, strain analysis, and substitution effect among patients with migraine, headache, arthritis, and chronic pain in a medicinal cannabis cohort – 2018
  4. Therapeutic Potential of Volatile Terpenes and Terpenoids from Forests for Inflammatory Diseases – 2020
  5.  The Molecular Mechanisms That Underpin the Biological Benefits of Full-Spectrum Cannabis Extract in the Treatment of Neuropathic Pain and Inflammation – PubMed – 2020
  6. Evaluation of the anti-inflammatory, anti-catabolic and pro-anabolic effects of E-caryophyllene, myrcene and limonene in a cell model of osteoarthritis. – 2015
  7. Cannabis, Cannabinoids, and the Endocannabinoid System—Is there Therapeutic Potential for Inflammatory Bowel Disease? – 2019
  8. Therapeutic Applications of Terpenes on Inflammatory Diseases – 2021

 

Esssential Oils

 

Essential Oils – Overviews

  1. Essential Oils, Part I Introduction – PubMed – 2016
  2. Essential Oils, Part II General Aspects – PubMed – 2016
  3. Essential Oils, Part III Chemical Composition – PubMed – 2016
  4. Essential Oils, Part IV Contact Allergy – PubMed- 2016
  5. Essential Oils, Part V Peppermint Oil, Lavender Oil, and Lemongrass Oil – PubMed 2016

 

 

Essential Oils – Bearded Irises

  1. Identification of Floral Scent Profiles in Bearded Irises – 2019

 

 

Essential Oils – Bergamot

  1. The Anxiolytic Effect of Aromatherapy on Patients Awaiting Ambulatory Surgery – A Randomized Controlled Trial – 2013
  2. Antinociceptive effect of inhalation of the essential oil of bergamot in mice – 2018
  3. Anxiolytic-Like Effects of Bergamot Essential Oil Are Insensitive to Flumazenil in Rats – 2019
  4. Bergamot – Natural Medicines – Professional.pdf
  5. Citrus bergamia essential oil – from basic research to clinical application – 2015
  6. Role of 5-HT1A Receptor in the Anxiolytic-Relaxant Effects of Bergamot Essential Oil in Rodent – 2020 Neuropharmacological Properties of the Essential Oil of Bergamot for the Clinical Management of Pain-Related BPSDs – PubMed – 2019
  7. Possible involvement of the peripheral Mu-opioid system in antinociception induced by bergamot essential oil to allodynia after peripheral nerve injury – PubMed – 2018
  8. Peripherally injected linalool and bergamot essential oil attenuate mechanical allodynia via inhibiting spinal ERK phosphorylation – PubMed – 2013
  9. Neuropharmacology of the essential oil of bergamot – PubMed – 2010
  10. Effect of Harvesting Time on Volatile Compounds Composition of Bergamot (Citrus × Bergamia) Essential Oil – 2019
  11. Chemical Composition and Biological Activities of Essential Oils from Peels of Three Citrus Species – 2020
  12. Chemical_Composition_of_Bergamot_Citrus_Bergamia_Risso_Essential_Oil_Obtained_by_Hydrodistillation – 2010
  13. Cannabinoid Signaling in the Skin – Therapeutic Potential of the “C(ut)annabinoid” System – 2019
  14. Rational Basis for the Use of Bergamot Essential Oil in Complementary Medicine to Treat Chronic Pain – PubMed – 2016

 

Essential Oils – Plumeria

  1. Constituents of essential oils from the leaf and flower of Plumeria alba grown in Nigeria – PubMed – 2014

 

Individual Terpenes

Terpenes: β-Caryophyllene:

  1. (−)-β-Caryophyllene, a CB2 Receptor-Selective Phytocannabinoid, Suppresses Motor Paralysis and Neuroinflammation in a Murine Model of Multiple Sclerosis – 2017
  2. Antiallodynic effect of β-caryophyllene on paclitaxel-induced peripheral neuropathy in mice. – PubMed – NCBI
  3. Acute administration of beta-caryophyllene prevents endocannabinoid system activation during transient common carotid artery occlusion and reperfusion – 2018
  4. Antiallodynic effect of β-caryophyllene on paclitaxel-induced peripheral neuropathy in mice. – PubMed – NCBI
  5. Cannabimimetic phytochemicals in the diet – an evolutionary link to food selection and metabolic stress adaptation? – 2016
  6. The anxiolytic-like effect of an essential oil derived from Spiranthera odoratissima A. St. Hil. leaves and its major component, β-caryophyllene, in male mice – 2012
  7. β‐caryophyllene and β‐caryophyllene oxide—natural compounds of anticancer and analgesic properties – 2016
  8. β-Caryophyllene, a CB2 receptor agonist produces multiple behavioral changes relevant to anxiety and depression in mice – 2014
  9. Toxicological Evaluation of β-Caryophyllene Oil: Subchronic Toxicity in Rats. – PubMed – NCBI 2016
  10. The cannabinoid CB₂ receptor-selective phytocannabinoid beta-caryophyllene exerts analgesic effects in mouse models of inflammatory and neuropathic… – PubMed – NCBI – 2014
  11. The cannabinoid CB2 receptor-selective phytocannabinoid beta-caryophyllene exerts analgesic effects in mouse models of inflammatory and neuropathic pain – 2013
  12. SPC Liposomes as Possible Delivery Systems for Improving Bioavailability of the Natural Sesquiterpene β-Caryophyllene – 2018
  13. β-Caryophyllene Inhibits Dextran Sulfate Sodium-Induced Colitis in Mice through CB2 Receptor Activation and PPARγ Pathway – 2011
  14. Why wild giant pandas frequently roll in horse manure – 2020
  15. Beta-caryophyllene is a dietary cannabinoid – 2008
  16. Analgesia mediated by the TRPM8 cold receptor in chronic neuropathic pain. – 2006
  17. The menthol receptor TRPM8 is the principal detector of environmental cold – PubMed – 2007
  18. Molecular basis of peripheral innocuous cold sensitivity – 2018
  19. Involvement of peripheral cannabinoid and opioid receptors in β-caryophyllene-induced antinociception – PubMed – 2013
  20. NON-CANNABIS THERAPY – Cannabinoid Therapy Without Using Cannabis: Direct Effects™ Topical β-Caryophyllene
  21. Beta-caryophyllene enhances wound healing through multiple routes – 2019
  22. Preparation and Characterization of Liposomal β‐Caryophyllene (Rephyll) – 2020

 

Terpenes: Linalool:

  1. GS12-linalool
  2. Linalool – 1997
  3. The “Entourage Effect”: Terpenes Coupled With Cannabinoids for the Treatment of Mood Disorders and Anxiety Disorders – PubMed – 2020
  4. An olfactory stimulus modifies nighttime sleep in young men and women. – PubMed – NCBI
  5. Lavender and sleep – A systematic review of the evidence – 2012
  6. Lavender and the Nervous System – 2013
  7. Effects of odorant administration on objective and subjective measures of sleep quality, post-sleep mood and alertness, and cognitive performance – 2003
  8. In-vitro inhibition of human erythrocyte acetylcholinesterase by salvia lavandulaefolia essential oil and constituent terpenes. – PubMed – NCBI – 2000
  9. Odors enhance slow-wave activity in non-rapid eye movement sleep – 2016
  10. A question of scent – lavender aroma promotes interpersonal trust – 2015
  11. Is Lavender an Anxiolytic Drug? A Systematic Review of Randomised Clinical Trials – 2012
  12. Efficacy of Silexan in subthreshold anxiety – meta-analysis of randomised, placebo-controlled trials – 2019
  13. Essential oil of lavender in anxiety disorders – Ready for prime time? – 2017
  14. Linalool is a PPAR ligand that reduces plasma TG levels and rewires the hepatic transcriptome and plasma metabolome – 2014
  15. A Review of the Potential Use of Pinene and Linalool as Terpene-Based Medicines for Brain Health – Discovering Novel Therapeutics in the Flavours and Fragrances of Cannabis – 2021
  16. The Efficacy of Lavender Aromatherapy in Reducing Preoperative Anxiety in Ambulatory Surgery Patients Undergoing Procedures in General Otolaryngology – 2017
  17. Efficacy, Safety and Tolerability of Aroma Massage with Lavender Essential Oil – an Overview – 2020
  18. Antinociceptive and anticonvulsant effects of the monoterpene linalool oxide – 2017
  19. Exploring Pharmacological Mechanisms of Lavender (Lavandula angustifolia) Essential Oil on Central Nervous System Targets – 2017
  20. Linalool Ameliorates Memory Loss and Behavioral Impairment Induced by REM-Sleep Deprivation through the Serotonergic Pathway – 2018
  21. Effects of lavender on anxiety, depression and physiologic parameters – Systematic Review and Meta-Analysis – 2021
  22. Lavender and sleep – A systematic review of the evidence – 2012
  23. Lavender and the Nervous System – 2013
  24. A question of scent – lavender aroma promotes interpersonal trust – 2015

 

 

Terpenes, Linalool:Silexan

  1. A Multi-Center, Double-Blind, Randomised Study of the Lavender Oil Preparation Silexan in Comparison to Lorazepam for Generalized Anxiety Disorder – 2010
  2. Is Lavender an Anxiolytic Drug? A Systematic Review of Randomised Clinical Trials – 2012
  3.  An Orally Administered Lavandula Oil Preparation (Silexan) for Anxiety Disorder and Related Conditions- An Evidence Based Review – 2013
  4. Lavender oil preparation Silexan is effective in generalized anxiety disorder – a randomized, double-blind comparison to placebo and paroxetine – 2014
  5. Silexan in anxiety disorders – Clinical data and pharmacological background – 2017
  6. Effectiveness of Silexan Oral Lavender Essential Oil Compared to Inhaled Lavender Essential Oil Aromatherapy for Sleep in Adults- A Systematic Review – 2018
  7. Silexan in anxiety disorders Clinical data and pharmacological background – PubMed – 2018
  8. Efficacy and safety of lavender essential oil (Silexan) capsules among patients suffering from anxiety disorders – A network meta-analysis – 2019
  9. Efficacy of Silexan in subthreshold anxiety – meta-analysis of randomised, placebo-controlled trials – 2019
  10. Therapeutic effects of Silexan on somatic symptoms and physical health in patients with anxiety disorders – A meta- analysis – 2020
  11. Silexan, an orally administered Lavandula oil preparation, is effective in the treatment of ‘subsyndromal’ anxiety disorder a randomized, double-blind, placebo controlled trial – PubMed – 2010
  12. A multi-center, double-blind, randomised study of the Lavender oil preparation Silexan in comparison to Lorazepam for generalized anxiety disorder – PubMed – 2009
  13. No Abuse Potential of Silexan in Healthy Recreational Drug Users – A Randomized Controlled Trial – 2021

 

Terpenes – Limonene

  1. Evaluation of the anti-inflammatory, anti-catabolic and pro-anabolic effects of E-caryophyllene, myrcene and limonene in a cell model of osteoarthritis. – 2015
  2. Neuroprotective Potential of Limonene and Limonene Containing Natural Products – 2021

 

Terpenes: Myrcene

  1. β-MYRCENE – IARC MONOGRAPHS
  2. Evaluation of the anti-inflammatory, anti-catabolic and pro-anabolic effects of E-caryophyllene, myrcene and limonene in a cell model of osteoarthritis. – 2015
  3. Myrcene—What Are the Potential Health Benefits of This Flavouring and Aroma Agent? – 2021

 

Terpenes: Pinene

  1. A Review of the Potential Use of Pinene and Linalool as Terpene-Based Medicines for Brain Health – Discovering Novel Therapeutics in the Flavours and Fragrances of Cannabis – 2021

 

 

Medical Marijuana – Product Evaluation

  1. The Cannabinoid Content of Legal Cannabis in Washington State Varies Systematically Across Testing Facilities and Popular Consumer Products – 2018
  2. Quality Control of Traditional Cannabis Tinctures – Pattern, Markers, and Stability – 2016
  3. Cannabinoid, Terpene, and Heavy Metal Analysis of 29 Over-the-Counter Commercial Veterinary Hemp Supplements – 2020

 

Emphasis on Education

 

Accurate Clinic promotes patient education as the foundation of it’s medical care. In Dr. Ehlenberger’s integrative approach to patient care, including conventional and complementary and alternative medical (CAM) treatments, he may encourage or provide advice about the use of supplements. However, the specifics of choice of supplement, dosing and duration of treatment should be individualized through discussion with Dr. Ehlenberger. The following information and reference articles are presented to provide the reader with some of the latest research to facilitate evidence-based, informed decisions regarding the use of conventional as well as CAM treatments.

 

For medical-legal reasons, access to these links is limited to patients enrolled in an Accurate Clinic medical program.

 

Should you wish more information regarding any of the subjects listed – or not listed –  here, please contact Dr. Ehlenberger. He has literally thousands of published articles to share on hundreds of topics associated with pain management, weight loss, nutrition, addiction recovery and emergency medicine. It would take years for you to read them, as it did him.

 

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