Getting real with CBD- a veterinary surgeon’s perspective

Written by Shared Content

It was about the third week into Bastion’s recovery from his TPLO surgery, and he was already having a rough time. Bastion was a gregarious yellow Labrador who had injured his stifle about 25 days earlier. Fortunately, his family elected to have the stifle surgically reconstructed. Initially, he was recovering well from surgery, but one day in particular, he returned to the hospital because he’d had a brief setback. He was limping far more severely than would be normally expected at that stage of recovery.

It was about the third week into Bastion’s recovery from his TPLO surgery, and he was already having a rough time. Bastion was a gregarious yellow Labrador who had injured his stifle about 25 days earlier. Fortunately, his family elected to have the stifle surgically reconstructed. Initially, he was recovering well from surgery, but one day in particular, he returned to the hospital because he’d had a brief setback. He was limping far more severely than would be normally expected at that stage of recovery.

The osteotomy from his surgery had not yet completely healed, and he was still in the middle of his prescribed five weeks of strict exercise restriction. His family was trying their best, but Bastion wasn’t having it. He was too active at home, and his humans were growing frustrated. They’d received anti-anxiety medications but weren’t giving them. Instead, his family had decided to give him CBD oil at home. When I asked why, the client responded, “I found CBD oil at the local farmers’ market, and I figured it would work just as well.”

Like Bastion, an increasing number of pets are receiving cannabidiol (CBD) supplements. The popularity of CBD continues to rise, and many clients are incorporating it into the medication protocol for their pets, either as an adjunct or an alternative treatment option. Perhaps the initial interest in the benefits of CBD can be traced back to 1998, or possibly earlier, when scientists at the National Institutes of Health discovered that CBD could protect cells from oxidative stress.

These findings fueled interest in the human medical field and, in large part, that appeal has been transmuted into veterinary medicine. The regard for this molecule has risen to such levels that in many homes, CBD is being used as the sole treatment option for a variety of medical conditions. Veterinarians are becoming more fluent in the fascinating pharmacology regarding the use of this phytocannabinoid. A recent survey indicated that most veterinarians (61.5%) felt comfortable discussing the use of CBD with their colleagues, but only 45.5% felt comfortable discussing this topic with clients.1

Furthermore, veterinarians and clients in states with legalized recreational marijuana were more likely to talk about the use of CBD products to treat canine ailments than those in other states.2 Lastly, CBD was most frequently discussed as a potential treatment for pain management, anxiety, and seizures.1 At first glance, the use of CBD has tangential or limited relevance in the world of veterinary surgery. However, as one takes a closer look at the putative—and proven—benefits, it is clear that we are just scratching the surface of its therapeutic benefits.


Whether you perform surgery within a specialty discipline (oncology, orthopedics, neurology, soft tissue surgery, mixed animal, oral/dental, etc.), or surgery is only a small part of your general practice, every veterinarian endeavors to manage pain aggressively. The first choice for pain relief among many clinicians are the medications that have been more extensively studied, including but not limited to anti-inflammatories, gabapentinoids, opioids, local anesthetics, and other analgesics (acetaminophen, amantadine, Cerenia, etc.). These medications or a combination thereof have been prescribed to treat pain from orthopedic surgery, soft tissue surgery, intestinal surgery, and surgical neuropathic conditions, to name just a few. In the most basic schema, pain is divided into four categories: nociceptive pain (a response to damaged tissue), neuropathic pain (a response to directly-damaged sensory or spinal nerves), centralized pain (the result of pain signals being improperly amplified), and inflammatory pain.1

Cannabinoids may have a role to play in mediating all four of these types of pain states. When tissue is damaged, histamine, serotonin, TNF-alpha, IL-1-beta, IL-6 and Il -17 6 , and interleukin 17 are released.2  Cannabinoids bind to the CB1 receptors and attenuate the pain signal by slowing down the release of those neurotransmitters.3 This process can take place locally or in the central nervous system.3 Cannabinoids have also been shown to inhibit the release of GABA, a well-known neurotransmitter associated with pain.3 Although there is a paucity of clinical research on the use of CBD to treat postoperative pain in the veterinary medical setting, there has been heartening research conducted in humans. Indeed, the National Academies of Sciences, Engineering, and Medicine concluded that there is “substantial evidence that cannabis is an effective treatment for chronic pain in adults.”

Opioids have long been the go-to option or cornerstone of pain management, but the potential for the adverse events associated with the use of opioids in veterinary patients is universally accepted.38 I have seen how distressing it can be for a family to see their pet experiencing any of the unpleasurable side effects of opioids, including urine retention, delayed bowel movements, whining, panting, disorientation, or other manifestations of dysphoria. Those are just some of the challenges that clinicians face when using opioids for chronic pain management. Considering the ongoing consequences of the opioid epidemic, there is a search for pain management solutions that are innovative, prone to less adverse events, and are more effective. As the scientific community begins to evaluate the evidence for use of CBD, it is clear that more research is needed.

Anecdotal reports of CBD’s efficacy as a pain reliever are ubiquitous, but more practitioners are turning to scientific data for evidence of CBD’s efficacy. A study in 2020 evaluating effects of CBD hemp extract on opioid use and quality-of-life indicators in chronic pain patients found that over half of chronic pain patients (53%) reduced or eliminated their opioids within eight weeks after adding CBD-rich hemp extract to their regimens.5 Almost all CBD users (94%) reported quality-of-life improvements.5 A recent study evaluating orally consumed cannabinoids for long-lasting relief of allodynia in a mouse model found that cannabinoids reduced hyperalgesia, and a similar effect was not found with morphine.4 Mouse vocalizations were recorded throughout the experiment, and mice showed a large increase in ultrasonic, broadband clicks after sciatic nerve injury, which was reversed by THC, CBD, and morphine.4 The study demonstrated that cannabinoids provide long-term relief of chronic pain states.4 If research shows that use of cannabinoids in animals—specifically, CBD—can help to decrease the use of opioids for pain management, that would help make more animals comfortable and potentially help to fight the tragic epidemic of human prescription opioid abuse. Further research is needed in a variety of species, specifically, both the canine and feline species.

Bone Healing

Both general veterinary practitioners and veterinary surgeons commonly diagnose and treat fractures. No large retrospective study of fracture incidence in dogs in North America has been published since 1994; however, the findings from that year’s study are still informative regarding the frequency of bone injuries. The study demonstrated that approximately 24% of all patients in the population studied over a 10-year period were affected by a disorder of the musculoskeletal system, with fractures contributing the largest proportion (over 29%) of all of the diagnoses of the appendicular skeletal system.7 Although that research is dated, the conclusions from this study, at the very least, indicate that fractures are commonplace in the clinical veterinary setting.7 Fracture repair has gradually become more straightforward due to improvements in technology. Because of these innovations, specialty surgeons and general practitioners who repair fractures have begun to see better surgical outcomes. So whether you primarily stabilize fractures with implants, or if external coaptation of fractures with the intention to refer (or perhaps as the primary means of fixation) is your treatment of choice, all veterinary practitioners aim to help fractured bones heal quickly. Despite these technological improvements, bone healing can be protracted or non-existent with some fractures. There are a variety of options at a veterinarian’s disposal to kick-start the healing process, but perhaps in the near future, CBD may be added to that armamentarium . The effect of CBD in fracture healing has been investigated evaluating bone callus formation in femur fractures in a rat model.8 The findings demonstrated enhanced biomechanical properties of healing fractures in those given CBD compared with a control group.8 This effect was not found in those given only Δ9-THC. Moreover, the bone-forming (osteogenic) effects of CBD were weakened when test subjects were given equal amounts of CBD and Δ9-THC.6 Another in vivo research study indicated that when CBD is incorporated into a surface that promotes bone growth (osteoconductive scaffold) it can stimulate stem cell migration and osteogenic differentiation.9  Further studies are needed to better evaluate the role of CBD in healing and bone metabolism of companion animals so that these findings can be applied in the clinical setting.

Additionally, cannabis has been shown to be a useful addition in treatment plans to improve bone health in laboratory studies. Studies have endeavored to better understand the role of CB2 receptors in maintaining bone health. CB2 receptors in bone cells have been linked to maintaining bone density and stimulating growth and may therefore have a part in reversing the effects of osteoporosis.10  One study evaluating the role of CB2 receptors found that mice whose genes had been altered to remove the CB1 or CB2 receptors developed signs of bone weakness that were far more pronounced than those in the control group.12 Another study in 2009 investigated the relationship between CB2 expression and bone disease in humans. It found that people with dysfunctional CB2 receptors have significantly weaker hand bones.11


Osteoarthritis (OA) affects many dogs, large and small. Most often, OA is the consequence of a developmental orthopedic disease that affects a single joint or a pair of joints and, less often, affects multiple joints. It is axiomatic that ‘Mother Nature likes symmetry,’ thus developmental orthopedic diseases frequently affect both left and right joints. For example, hip dysplasia is reportedly bilateral in >60% of affected dogs,13 and elbow dysplasia is bilateral in approximately 50% of affected dogs.14Osteoarthritis occurs secondary to a myriad of primary orthopedic conditions that affect a variety of joints including: the hip (most common causes of OA in the hip: hip dysplasia, Perthes disease); stifle (patellar luxation, cranial cruciate ligament disease, osteochondritis dissecans [OCD]); elbow (elbow dysplasia, elbow OCD, fragmentation of the medial coronoid process, incomplete ossification of the humeral condyle); shoulder (shoulder OCD, developmental shoulder subluxation); tarsus (OCD of the talus), and carpus (carpal laxity, carpal subluxation secondary to chondrodystrophy); and metacarpophalangeal (MCP) and metatarsophalangeal (MTP) joint degenerative osteoarthritis (digital osteoarthritis).

Cannabinoids were found to treat pain secondary to inflammation in a variety of studies on humans. Some of the most compelling research has shown that cannabis can reduce the inflammation in the joint caused in human patients diagnosed with immune-mediated arthritis.15  One study found that cannabinoids could simultaneously reduce the secretion of cytokines involved in inflammation from one type of TH immune cells, which were being under-produced, while also increasing their numbers to correct their scarcity.15 Furthermore, in a study in 2003, researchers found that plant-based cannabinoids could suppress the expression of interleukin-1beta—one of the most prominent markers for inflammation in patients with rheumatoid arthritis—by as much as 50%.16 And finally, in 2006, transdermal applications of CBD were shown to decrease biomarkers that can contribute to neurogenic inflammation in a sample of arthritic rats.17

A report published in The Journal of PAIN and written by researchers at Baylor College of Medicine revealed the results of a large, double-blinded, placebo-controlled study on the positive effects CBD had in the fight against osteoarthritis.18 The study was designed with two main goals: The first portion of the research studied the effect CBD had on the inflammatory molecules and cells in mice.18 The second portion of the study investigated whether CBD improved the quality of life in dogs diagnosed with osteoarthritis. In lab tests and in mouse models, CBD significantly decreased the production of natural chemicals that promote inflammation, and it increased the natural chemicals that fight inflammation.18 Essentially, they saw a drop in proinflammatory cytokines and an increase in anti-inflammatory cytokines.18 For dogs with osteoarthritis, CBD significantly decreased pain and increased mobility in a dose-dependent fashion. Importantly, a lower dose of liposomal CBD was as effective as the highest dose of non-liposomal CBD, indicating that the effect of CBD was quicker and more powerful when CBD was delivered encapsulated in liposomes than without.18 Blood samples indicated no significant harmful side effects or adverse events over the 4-week analysis period.18 Although this study is very promising, and it supports the safety and therapeutic potential of hemp-derived CBD for relieving arthritic pain in dogs, it is important to consult with your pet’s veterinarian before giving any supplement or medication.

In the veterinary population, use of cannabidiol and other alternative treatments has the potential to obviate the need for other medications and thus spare patients from adverse effects associated with their use. More likely, the use of cannabinoids could be additive or synergistic in a multimodal treatment strategy and could increase quality-of-life issues associated with painful arthritic conditions.

Intervertebral Disk Disease

As our patients age, discs in their spines undergo degenerative changes. Thus, degeneration of intervertebral discs is inevitable. This process of degeneration is multifactorial, and it involves hypoxia, inflammation, neoinnervation, accelerated catabolism, and reduction in water and glycosaminoglycan content.39  The magnitude and severity of disc degeneration can vary widely between patients. The most common locations of clinically relevant disc disease are the cervical spine, thoracolumbar spine, and lumbosacral spine.40 Although there are various manifestations of disc disease, broad classifications of Hansen Type I and Type II are typically used to describe the condition. In short, disc material may either extrude (acute herniations) or protrude (chronic herniations), both of which compress the spinal cord, which can ultimately cause pain, paresis, paralysis, and other neurological deficits.40  The prevalence of thoracolumbar disc disease in dogs has been estimated at 3.5%.40 Depending on the neurologic examination, diagnosis, severity, prognosis, and other factors, surgery may be recommended to decompress the spinal cord. After surgical decompression, there is a host of challenges that the patient, the family, and the surgeon may have to work through, including a potentially protracted recovery, recurrence of neurological signs, post-surgical pain, spinal instability, urinary disorders, (cystitis, urinary tract infection, urinary retention, micturition disorders), ascending myelomalacia, and others.41 Could CBD play a part in helping to improve those affected by disc disease pre-, intra-, or post-operatively, and what types of spinal disorders could benefit from CBD? A study conducted on the use of CBD in mice with degenerative disc disease showed promise in mitigating the effect of disc damage and wear.19 Instead of being ingested orally, CBD was injected at the site of the disc. Researchers investigated the effects of cannabidiol intradiscal injection using a combination of MRI and histological analyses.19 A puncture was created in the disc, and then CBD was injected into the disc (30, 60 or 120 nmol) shortly after.19 The effects of intradiscal injection of cannabidiol were analyzed within 2 days by MRI.17 Fifteen days later, the group that received cannabidiol 120 nmol was resubmitted to MRI examination and then to histological analyses after the cannabidiol injection.19 They found that cannabidiol significantly decreased the effects of disc injury induced by the needle puncture.19 These results suggest that this compound could be useful in the treatment of intervertebral disc degeneration, perhaps using a novel route of administration. Unfortunately, the exact mechanism for how CBD oil helped alleviate disc damage is still being investigated. The hope is that the neuroprotective properties of cannabidiol can also be found in the study of canine and feline disc disease to ultimately improve functional recovery.

Neuropathic Pain

Fortunately, more effort, research, and attention is being paid to treating pain in veterinary medicine.Nociceptive pain is caused by external pressure, cold, heat, or internal trauma, stimulated by the release of compounds like bradykinin, prostaglandins, or leukotrienes.20 Humans may describe this pain as a sharp, aching, or throbbing sensation. In veterinary patients, nociceptive pain may be manifested by limping, sharp movements, lip smacking, panting, vocalization, or, in select cases, no obvious response. The function of nociceptive pain in humans, and presumably in pets, is to alert them that they are injured and hopefully prevent further injury.20

Neuropathic pain, caused by direct damage to sensory or spinal nerves, allows aberrant pain signals to be sent to the brain.21 In veterinary patients, a common example of neuropathic pain that I diagnose commonly is sciatic or radial nerve hyperpathia, but lumbar or cervical foraminal radiculopathies can also be relatively frequent causes of neuropathic pain. Neuropathic pain syndromes are often secondary to intervertebral disc disease, static and dynamic nerve foramen impingement, vertebral instability, recent surgery, trauma, abnormal conformation, abnormal gait, and chronic joint pain.21 A classic example of neuropathic pain in humans is diabetic neuropathy.

Unfortunately, there are some challenges to diagnosing and understanding neuropathic pain in the veterinary setting, particularly in the presence of an otherwise normal orthopedic exam. To be sure, neuropathic pain can be evoked by low- or high-intensity stimuli; it can be spontaneous and not stimulus-dependent; it is maladaptive (maintained in the absence of tissue trauma), and it responds poorly to opiates and anti-inflammatory drugs.21

CBD use has shown promise in the treatment of neuropathic pain. In a 2010 study, researchers looked at a sample of diabetic rats and administered daily doses of Cannabis sativa ranging from 25 to 100 mg/kg [AC6] of body weight.22 After fourteen days, the rats exhibited significant reductions in tingling, heat, and pain in the extremities associated with advanced diabetes.22 Another study, from 2015, compared descriptions of spontaneous pain among sixteen patients with painful diabetic peripheral neuropathy in a randomized, double-blinded setting.23 The study subjects were administered four single-dosing sessions of placebo or cannabis. Significant reduction in pain intensity varied directly with the size of their dose.23

As we begin to understand neuropathic pain in animals more clearly, treatment strategies and pharmaceutical alternatives will more adequately address their pain, possibly including the use of CBD or CBD alternatives. Additional research will hopefully actualize the promise and potential that CBD may have in treating the veterinary population in neuropathic pain.


 Exercise restriction is a critical component for successful surgical outcomes in many elective orthopedic surgeries. For example, post dynamic stifle stabilization surgery, I frequently recommend a minimum of five to eight weeks of strict monitoring and exercise restriction. This recommendation can be extremely challenging for families, because many of the animals are inclined to be active, are frequently powerful and athletic, and are young and unaccustomed to confinement. Implant failure or a poor surgical outcome overall can many times be ascribed to the challenges related to activity restriction. Difficulties with this process may lead to protracted recovery or even surgical treatment failure, necessitating a second surgical procedure.

Common pharmaceutical strategies employed to help with exercise restriction include the use of Trazodone and Acepromazine.24However, both of these medications can have variable effects depending on the individual, and in some cases, there are undesirable adverse effects (e.g. excessive sedation and paradoxical excitation with Acepromazine,  serotonin syndrome with Trazodone, etc.).24

Could CBD or CBD derivatives enhance calmness and alleviate anxiety in animals? Based on CBD’s proposed mechanism of action in mitigating anxiety, the answer may be encouraging. Higher levels of natural endocannabinoids in the human body are associated with an antidepressant effect.25 Cannabinoid receptors are found throughout the central nervous system and play a key part in maintaining our sense of well-being. They are particularly numerous in cells tasked with manufacturing serotonin where it is needed.25

Cannabidiol may also have an effect on the hippocampus, which is a region of the brain responsible for memory and mood. Glucocorticoids are secreted during stress, which may cause the hippocampus to atrophy.26  That shrinking process plays a role in diminished memory and depressed mood.26 Cannabinoids have shown an ability to counter this process through the phenomenon of hippocampal neurogenesis (regrowth and development in nerve tissue), which can be activated by the expression of cannabinoid type-1 receptors.26 Both natural endocannabinoids and plant-based cannabinoids have both been shown to accelerate this process.26

In another random-controlled trial performed on humans, subjects receiving a 600 mg CBD supplement also reported less subjective anxiety symptoms during public speaking than those who’d taken a placebo.27 CBD also shows activity specific to the limbic system in the brain. A study evaluating that effect on the limbic system found that CBD administration helped to reduce symptoms in people with social anxiety disorder.28 Indeed, the National Academies of Sciences, Engineering, and Medicine specifically referenced CBD’s effects in a statement about anxiety disorders, “…there is evidence that cannabidiol is an effective treatment for the improvement of anxiety symptoms, as assessed by a public speaking test in individuals with social anxiety disorders.”30

A 2019 study in mice simulated to have an anxiety disorder, (Fragile X Syndrome—a neurodevelopmental disorder that affects intellectual, social, and physical development due to a mutation of the FMR1 gene) were shown to have fewer anxiety-related behaviors across tests when given CBD.31 Furthermore, CBD decreased the anxiety response of all mice tested while not affecting their cognitive performance.31

The potential for CBD to be efficacious in treating anxiety in other species will be important to study, but its use as an anxiolytic and sedative is growing in popularity despite the paucity of research specific to this indication. As previously mentioned, anxiety was one of the most common reasons for veterinarians to discuss CBD.1 The most commonly used CBD formulations were oil/extract and edibles1 for the putative benefits of relieving anxiety, among others.1 As CBD research continues to gain steam, more attention will hopefully be directed towards how the full ensemble of cannabinoids, terpenes, and flavonoids seem to complement each other, working through multiple receptors at once, and often enhancing each other’s signals to the body (entourage effect).

Wound Healing

When it comes to wounds, all medical professionals are generally united in a common purpose: we want wounds to heal faster. Indeed, products that promote or accelerate wound healing have been of interest to veterinarians and physicians since the advent of wound treatment. Wound healing products and topical agents may target different phases of wound healing, including debridement, wound contraction, epithelialization, and granulation. Many products promote the formation of granulation tissue, while others are more effective after granulation tissue has formed (e.g. hyaluronic acid). For this reason, adapting the topical dressing specific to the stage and progress of wound healing is of utmost importance.

CBD has shown efficacy in the maturation phase of wound healing and some inflammatory skin conditions.33 In a 2019 study of 20 patients with two most frequent skin disorders—psoriasis (5 patients), atopic dermatitis (5), and resulting outcome scars (10)—the subjects were instructed to administer topical CBD-enriched ointment to lesioned skin areas twice daily for three months.33The results showed that topical treatment with CBD-enriched ointment significantly improved the skin parameters and the symptoms associated with the skin condition.33 This study concluded that the topical administration of CBD ointment, without any THC, is a safe, effective, and non-invasive alternative for improving the quality of life in patients with some skin disorders, especially inflammatory ones.33 Another study in 2019 investigated the potential effect of a Cannabis sativa L. ethanolic extract standardized in cannabidiol as anti-inflammatory agent in the skin.34 The study found that the extract inhibited the release of mediators of inflammation involved in wound healing and inflammatory processes occurring in the skin.34 The down-regulation of genes involved in wound healing and skin inflammation was at least in part due to the presence of cannabidiol.34 The findings provided new insights into the potential effect of Cannabis extracts against inflammation-based skin diseases.

Bacterial infiltration can negatively influence wound healing. Another area in which topical cannabis treatments show a great deal of potential is in the treatment of bacteria-related skin disorders. One study from 1976 indicated that isolates of THC and CBD were effective in reducing samples of staphylococci and streptococci, two bacteria associated with acne.35 Another study from 2008 found that the plant-based CBD, CBC, CBG, THC, and CBN were substantially potent against a variety of Staphylococcus aureus strains, which were resistant to the antibiotic methicillin (MRSA).36

However, a recent study perhaps underscores the importance of adjusting topical therapy according to the stage of healing. In 2020, the Australian Veterinary Journal reported a study on horses with wounds that were created in a laboratory setting and then deliberately contaminated. Each wound was assigned to a treatment group that contained 1% cannabidiol in three different manuka honey formulations.37 Treatments were applied topically daily for a total of 42 days. The results indicated that irrespective of the treatment, wounds did not retract as expected in the first seven days after wound creation.37 There was no difference in wound area, daily healing rate, or days to complete healing between treatment groups.37 This study highlights the importance for continued study on the correct time, concentration, and best practices when using CBD to accelerate wound healing.


Though the overall potential for cannabidiol to address specific surgical conditions is encouraging, strong double-blinded, placebo-controlled studies with large sample sizes are lacking. Based on the research that’s available in animal models and among human patients, there are large pockets of convincing research that inspire hope and promise in the use of CBD in veterinary surgery and veterinary medicine writ large. To be sure, the concept of scientific integrative medicine should be considered along with other first-line treatments for veterinary patients. Evidence-based solutions should be prioritized when treating disease, but innovative or novel treatments may have to be considered in patients with neuropathic pain, disc disease, anxiety, or debilitating arthritis. New discoveries in the world of cannabis-based medicine may be just what the doctor ordered for an effervescent Labrador like Bastion.


  1. Kogan, L., Schoenfeld-Tacher, R., et al. (2018) US Veterinarians’ Knowledge, Experience, and Perception Regarding the Use of Cannabidiol for Canine Medical Conditions.  Frontiers in Veterinary Science, 5:338.

  2. Abd-Elsayed, A., Deer, T.R. (2019) Different Types of Pain. In: A. Abd-Elsayed (Ed.) Pain. Heidelberg: Springer.

  3. Manzanares, J., Julian, M.D., Carrascosa, A. (2006) Role of the Cannabinoid System in Pain Control and Therapeutic Implications for the Management of Acute and Chronic Pain Episodes. Current Neuropharmacology, 4(3), 239–257.

  4. Abraham, A.D., Leung, E.J., Brenden, A., Wong, B.A., Rivera, Z.M., Kruse, L.C., et al. (2020) Orally consumed cannabinoids provide long-lasting relief of allodynia in a mouse model of chronic neuropathic pain. 45(7):1105-1114. DOI: 10.1038/s41386-019-0585-3. Epub 2019 Dec 7.

  5. Capano, A., Weaver, R., Burkman, E. (2020) Evaluation of the effects of CBD hemp extract on opioid use and quality of life indicators in chronic pain patients: a prospective cohort study. Postgraduate Medical Journal.132(1):56-61. DOI:10.1080/00325481.2019.1685298. Epub 2019 Nov 12.

  6. Abraham, A.D., Leung, E.J., Wong, B.A., Rivera, Z.M., Kruse, L.C., Clark, J.J., Land, B.B. (2020) Orally consumed cannabinoids provide long-lasting relief of allodynia in a mouse model of chronic neuropathic pain. Neuropsychopharmacology, 45:1105–1114.

  7. Johnson, J., Austin, C., & Breur, G. (1994) Incidence of Canine Appendicular Musculoskeletal Disorders in 16 Veterinary Teaching Hospitals from 1980 through 1989. Veterinary and Comparative Orthopaedics and Traumatology, 07(02), 56–69. DOI:10.1055/s-0038-1633097

  8. Kogan, N.M., Melamed, E., Wasserman, E. (2015) Cannabidiol, a Major Non-Psychotropic Cannabis Constituent Enhances Fracture Healing and Stimulates Lysyl Hydroxylase Activity in Osteoblasts. Journal of Bone and Mineral Research, 30(10):1905-13. DOI: 10.1002/jbmr.2513. Epub 2015 May 10.

  9. Kamali, A., Oryan, A., Hosseini, S., Ghanian, M. H., Alizadeh, M., Baghaban Eslaminejad, M., & Baharvand, H. (2019) Cannabidiol-loaded microspheres incorporated into osteoconductive scaffold enhance mesenchymal stem cell recruitment and regeneration of critical-sized bone defects. Materials Science and Engineering, 101, 64–75. DOI:10.1016/j.msec.2019.03.070

  10. Bab, I., Zimmer, A. (2007) Cannabinoid Receptors and the Regulation of Bone Mass. British Journal of Pharmacology, 153:182-188. DOI:10.1038/sj.bjp.0707593

  11. Idris, A.I. (2010) Cannabinoid Receptors as Target for Treatment of Osteoporosis: A Tale of Two Therapies. Current Neuropharmacology, 8(3), 243–253. DOI:10.2174/157015910792246173

  12. Karsak, M., et al. (2009) The Cannabinoid Receptor Type 2 (CNR2) Gene Is Associated with Hand Bone Strength Phenotypes in an Ethnically Homogeneous Family Sample. Human Genetics, 5:629-36. DOI:10.1007/s00439-009-0708-8.

  13.  Loder, R.T. & Todhunter, R.J. (2017) The Demographics of Canine Hip Dysplasia in the United States and Canada. Journal of Veterinary Medicine, 1–15. DOI:10.1155/2017/5723476

  14. O’Neill, D.G., Brodbelt, D.C., Hodge, R., Church, D.B., Meeson, R.L. (2020) Epidemiology and clinical management of elbow joint disease in dogs under primary veterinary care in the UK. Canine Medicine and Genetics, volume 7:1

  15. Pross, S.H., et al. (1990) Differential Suppression of T-cell Subpopulations by THC (delta-9- tetrahydrocannabinol). International Journal of Immunopharmacology, 12, no. 5: 539-44. DOI:10.1016/0192-0561(90)90118-7

  16.  Zurier, R.B., et al. (2003) Suppression of Human Monocyte Interleukin-1β Production by Ajulemic Acid, a Nonpsychoactive Cannabinoid. Biochemical Pharmacology, 4:649-55. DOI:10.1016/s0006-2952(02)01604-0.

  17. Hammell, D.C., et al. (2015) Transdermal Cannabidiol Reduces Inflammation and Pain-related Behaviours in a Rat Model of Arthritis. European Journal of Pain, 6:936-48. DOI:10.1002/ejp.818

  18. Verrico, C.D., Wesson, S., Konduri, V., Hofferek, C.J., Vazquez-Perez, J., et al. (2020) A randomized, double-blind, placebo-controlled study of daily cannabidiol for the treatment of canine osteoarthritis pain. Pain. DOI:10.1097/j.pain.0000000000001896

  19. Silveira, J.W., Issy, A.C., Castania, V.A., Salmon, C.E.G., Nogueira-Barbosa, M. H., et al. (2014) Protective Effects of Cannabidiol on Lesion-Induced Intervertebral Disc Degeneration. PLOS One, 9:12. DOI:10.1371/journal.pone.0113161

  20. Yam, M., Loh, Y., Tan, C., Khadijah Adam, S., Abdul Manan, N., et al. (2018) General Pathways of Pain Sensation and the Major Neurotransmitters Involved in Pain Regulation. International Journal of Molecular Sciences, 19(8), 2164.DOI:10.3390/ijms19082164

  21. Costigan, M., Scholz, J., & Woolf, C. J. (2009) Neuropathic Pain: A Maladaptive Response of the Nervous System to Damage. Annual Review of Neuroscience, 32(1), 1–32. DOI:10.1146/annurev.neuro.051508.135531

  22. Arora, A., Taliyan, R., Sharma, P.L. (2010) Ameliorative Potential of Cannabis Sativa Extract on Diabetes Induced Neuropathic Pain in Rats. International Journal of Pharmaceutical Sciences and Research, 1.

  23. Wallace, M.S., et al. (2015) Efficacy of Inhaled Cannabis on Painful Diabetic Neuropathy. Pain, 16(7): 616-27. DOI:10.1016/j.jpain.2015.03.008.

  24. Gruen, M. E., Roe, S. C., Griffith, E., Hamilton, A., & Sherman, B.L. (2014) Use of Trazodone to facilitate postsurgical confinement in dogs. Journal of the American Veterinary Medical Association, 245(3), 296–301. DOI:10.2460/javma.245.3.296

  25. Serra, G. & Fratta, W. (2007) A possible role for the endocannabinoid system in the neurobiology of depression. Clinical Practice and Epidemiology in Mental Health, 3(1), 25. DOI:10.1186/1745-0179-3-25

  26. Kim, E. J., Pellman, B., & Kim, J.J. (2015) Stress effects on the hippocampus: a critical review. Learning & Memory, 22(9), 411–416. DOI:10.1101/lm.037291.114

  27. Demirakca, T., Sartorius, A., Ende, G., et al. (2010) Diminished gray matter in the hippocampus of cannabis users: Possible protective effects of cannabidiol. Drug and Alcohol Dependence. DOI:10.1016/j.drugalcdep.2010.09.020

  28. Bergamaschi, M.M., et al. (2011) Cannabidiol Reduces the Anxiety Induced by Simulated Public Speaking in Treatment-Naïve Social Phobia Patients. Neuropsychopharmacology, 36(6):1219-26 DOI:10.1038/npp.2011.6.

  29. Crippa, J.A.S., et al. (2010) Neural Basis of Anxiolytic Effects of Cannabidiol (CBD) in Generalized Social Anxiety Disorder: A Preliminary Report. Journal of Psychopharmacology, 25:1 DOI:10.1177/0269881110379283.

  30. National Academies of Sciences, Engineering, and Medicine, 120.

  31. Zieba, J., Sinclair, D., Sebree, T., Bonn-Miller, M. (2019) Cannabidiol (CBD) reduces anxiety-related behavior in mice via an FMRP1-independent mechanism. Pharmacology Biochemistry and Behavior. DOI:10.1016/j.pbb.2019.05.002

  32.  Pamplona, F.A., da Silva, L.R., & Coan, A.C. (2018) Potential Clinical Benefits of CBD-Rich Cannabis Extracts Over Purified CBD in Treatment-Resistant Epilepsy: Observational Data Meta-analysis. Frontiers in Neurology, 9. DOI:10.3389/fneur.2018.00759

  33. Palmieri, B., Laurino, C., Vadalà, M. (2019) A therapeutic effect of CBD-enriched ointment in inflammatory skin diseases and cutaneous scars. La Clinica Terapeutica, Mar-Apr, 170(2):e93-e99. DOI: 10.7417/CT.2019.2116.

  34. Sangiovanni, E., Fumagalli, M., Pacchetti, B., Piazza, S., et al. (2019) Cannabis sativa L. extract and cannabidiol inhibit in vitro mediators of skin inflammation and wound injury. Phytotherapy Research. DOI:10.1002/ptr.6400

  35. Van Klingeren, B. & Ten Ham, M. (1976) Antibacterial Activity of ∆9-tetrahydrocannabinol and Cannabidiol. Antonie Van Leeuwenhoek, 42(1-2): 9-12. DOI:10.1007/bf00399444.

  36. Appendino, G., et al. (2008) Antibacterial Cannabinoids From Cannabis Sativa: A Structure—Activity Study. Journal of Natural Products, 71(8):1427-430. DOI:10.1021/np8002673

  37. McIver, V., Tsang, A., Symonds, N., Perkins, N., et al. (2020) Effects of topical treatment of cannabidiol extract in a unique manuka factor 5 manuka honey carrier on second intention wound healing on equine distal limb wounds: a preliminary study. Australian Veterinary Journal. DOI:10.1111/avj.12932

  38. White, D.M., Mair, A.R., & Martinez-Taboada, F. (2017) Opioid-free anaesthesia in three dogs. Open Veterinary Journal, 7(2), 104. DOI:10.4314/ovj.v7i2.5

  39. Hansen, T., Smolders, L.A., Tryfonidou, M.A., et al. (2017) The Myth of Fibroid Degeneration in the Canine Intervertebral Disc: A Histopathological Comparison of Intervertebral Disc Degeneration in Chondrodystrophic and Nonchondrodystrophic Dogs. Veterinary Pathology, 54 (6): 945-952.

  40. Jeffery, N.D., Levine, J.M., Olby, N.J., et al. (2013) Intervertebral disk degeneration in dogs: consequences, diagnosis, treatment, and future directions. Journal of Veterinary Internal Medicine, 27 (6):1318-33.

  41. Balducci, F., Canal, S., Contiero, B., et al. (2017) Prevalence and Risk Factors for Presumptive Ascending/Descending Myelomalacia in Dogs after Thoracolumbar Intervertebral Disk Herniation. Journal of Veterinary Internal Medicine,  31 (2):498-504.

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