“Aims: Methicillin-resistant Staphylococcus aureus (MRSA) is a major cause of hospital-acquired pneumonia with resistance against beta-lactam antibiotics. New, potent antibiotics against MRSA with other mechanisms of action are thus urgently needed. Recently, cannabinoids have been evaluated for antimicrobial activity in the ongoing search for new anti-infective agents, but their anti-biofilm effect has not been extensively studied. In this study, five main phytocannabinoids – canndibidiol (CBD), delta-9-tetrahydrocannabinol (THC), cannabinol (CBN), cannabigerol (CBG), and cannabichromene (CBC) were examined for their activity against a MRSA biofilm.
Methods and results: The anti-biofilm activity was assessed by crystal violet staining, resazurin metabolic assay, reactive oxygen species (ROS) assay, and propidium iodide membrane integrity test. The minimum inhibitory concentrations of all tested cannabinoids were between 1-2 µg/mL. CBN showed the most potent anti-MRSA biofilm activity, significantly reducing biofilm biomass and bacterial viability. It also induced the highest intracellular ROS levels. In contrast, CBD was the least effective among the tested cannabinoids in most of the anti-biofilm assays, yet it caused the greatest membrane damage to bacteria within the biofilm.
Conclusions: This study showed that despite being chemically similar, the cannabinoids demonstrated different potency and potentially different mechanisms of action against MRSA. More research is needed to investigate how they act on this pathogen and its biofilm.”
“The endocannabinoid system (ECS) is a multicomponent signaling network that controls several physiological processes, including neurological, immune, cardiovascular, digestive, and ocular functions. The components of ECS (i.e., receptors, ligands, metabolizing enzymes, and carriers) are expressed in eye structures and neurological areas involved in the visual process. Experimental evidence supports ECS involvement in ocular pathophysiology.
Preclinical and clinical studies indicate that cannabinoids (CBs) lower intraocular pressure and exert vasoactive, anti-inflammatory, and protective effects in the retina and ocular surface. However, CBs elicit modest and transient effects while inducing tolerance, dependence, and adverse effects, which prevent their use in ophthalmic clinics.
This review summarizes experimental and clinical data on the role of ECS in ocular pathophysiology. It also reports research on the therapeutic potential of CBs in common eye disorders. Lastly, it highlights promising alternative strategies for modulating ECS and improving ocular drug delivery to improve therapeutic efficiency in ophthalmic clinics.”
“Background: Cannabis constituents, including Δ9-tetrahydrocannabinol (THC) and cannabidiol (CBD), show distinct pharmacological profiles with therapeutic relevance for neurological and psychiatric conditions. THC exerts euphoric effects primarily via CB1 receptor activation, while CBD displays non-euphoric properties affecting various pathways.
Aims: This study evaluated the effects of THC, CBD, and their combination on brain functional connectivity (FC) and cerebral blood flow (CBF) using multimodal neuroimaging.
Methods: Adult male Sprague Dawley rats received intraperitoneal doses of 10 mg/kg THC, 150 mg/kg CBD, 10.8:10 mg/kg THC:CBD, or vehicle. Resting-state blood oxygenation level dependent magnetic resonance imaging and arterial spin labelling assessed FC and CBF, approximately 2 h after drug administration. Graph-theory metrics and seed-based analyses identified connectivity and perfusion alterations, while plasma analyses determined cannabinoid concentrations.
Results: THC increased whole-brain FC and clustering coefficient, with elevated CBF in cortical and subcortical regions. CBD decreased FC metrics without affecting CBF, while THC:CBD induced moderate increases in both. Seed-based analysis revealed THC-driven increases in cortical-hippocampal and cortical-striatal connectivity, attenuated in the THC:CBD group. A multivariate combined analysis of FC and CBF revealed a divergent pattern of changes induced by each drug.
Conclusions: In conclusion, we show that THC and CBD induce distinct neurophysiological profiles in rats, with THC increasing both connectivity and perfusion, moderated by CBD when combined. These findings corroborate existing knowledge about the effects of cannabinoids on the brain, while also supporting the potential of preclinical functional neuroimaging to delineate cannabinoid-induced endophenotypes, offering insights for therapeutic development.”
“Growing evidence supports the therapeutic potential of cannabis and its constituent phytocannabinoids in treating a range of neurological and psychiatric conditions.”
“In summary, we have demonstrated that acute THC administration resulted in increases in FC and regional CBF, acute CBD administration resulted in an overall reduction in FC with negligible effect on CBF, and the combination drug THC:CBD resulted in effects similar to, but lower than THC alone. Our application of functional neuroimaging has thus identified differential pharmacodynamic signatures for THC and CBD in anaesthetised adult male rats. Further work should encompass an investigation of the effects of sub-chronic administration of phytocannabinoids on brain activity in animal models with relevance to selected disease indications to investigate changes on FC in a perturbed system, more applicable to the disease state. “
“This study aimed to design a THC-rich hydrogel to deliver cannabis derivatives topically. We developed hydrogels using polyvinyl alcohol (PVA) mixed with propylene glycol (PG), vegetable glycerin (VG), or both to facilitate the dissolution of delta-9-tetrahydrocannabinol (THC).
The hydrogels showed a brown color, confirming the presence of the cannabinoid. They exhibit a porous structure and better mechanical properties than PVA alone. Indeed, the hydrogel containing PG, VG, or both showed elastic deformation behaviors with lower water content. FTIR analysis demonstrated the presence of THC with two specific peaks at 1,575 and 1,619 cm-1, confirming the presence of THC in the hydrogels.
Human dermal fibroblast cultures onto the surface of all hydrogels confirmed the safety of the THC-rich hydrogel as the cell adhesion was comparable to the control (no THC). Furthermore, cells adhering to the hydrogels could proliferate, showing increased cell viability at 48 and 72 h, with a higher proliferation obtained with the THC-rich PVA-PG-VG hydrogels.
Such cell behavior could be due to the release of the THC in the culture medium, as demonstrated by ultra-high performance liquid chromatography (UPLC), showing the presence of THC in the culture medium, ranging from 203 to 290 μg after 24 h of incubation of the hydrogels containing PG and VG or both. In comparison, the released THC from the PVA hydrogel was higher, reaching 852 μg. It is interesting to note that the THC release at 24, 48, and 72 h was slower with the hydrogels containing PG, VG, and both, compared to PVA alone.
Overall, the present study has designed safe THC-rich PVA-PG-VG hydrogels as a functional delivery system for the topical use of cannabinoids to control tissue diseases, such as inflammation.”
“Cannabis has long been used to relieve symptoms such as pain, fever, anxiety, and diarrhea in the context of numerous diseases. Furthermore, cannabis products were reported to reduce inflammatory diseases. Over the past decades, it has been demonstrated that cannabinoids have anti-inflammatory effects, as ascertained by the decrease in the secretion of inflammatory mediators. The human body is subjected to various conditions (stress, autocrine/endocrine changes, exposure to exogenous stimuli, etc.) leading to organ and tissue inflammatory disorders, such as those in the skin and the oral cavity. Such tissue inflammation could be controlled using cannabis products.”
“Altogether, our results demonstrated the possible combination of PVA with PG and VG to generate useful THC-rich hydrogels for cannabinoid delivery. Because THC is lipophilic, our study suggests the possible delivery of THC when in topical contact with the tissues, including skin and oral mucosa, as the cells have lipid-rich membranes. Our THC-rich PVA-PG-VG hydrogels, therefore, may have the potential as a drug carrier for topical use to treat tissue inflammation.”
“Objectives: Triple-negative breast cancer (TNBC) is an aggressive subtype of breast cancer with limited treatment options. Cannabidiol (CBD) has demonstrated anticancer potential, but its clinical application is hindered by poor solubility and nonspecific distribution. This study aimed to develop a folic acid-modified chitosan (FA-CS) nanoparticle system to enhance the targeted delivery and therapeutic efficacy of CBD against TNBC.
Methods: FA-CS@CBD nanoparticles were synthesized and characterized for morphology, size distribution, zeta potential, and stability. Their in vitro anticancer effects were evaluated through cytotoxicity, cellular uptake, apoptosis, and reactive oxygen species (ROS) assays in 4T1 breast cancer cells. The in vivo antitumour efficacy and systemic toxicity were assessed using a TNBC mouse model.
Key findings: FA-CS@CBD nanoparticles exhibited uniform morphology, stable physicochemical properties, and efficient cellular uptake. Compared to free CBD, the nanoparticles significantly enhanced ROS production, induced apoptosis, and inhibited migration in 4T1 cells. In vivo studies demonstrated strong tumour-targeting capability and a tumour inhibition rate of 68.07%, with minimal systemic toxicity.
Conclusions: The FA-CS@CBD nanoparticle system improved the targeted delivery and therapeutic effects of CBD against TNBC while maintaining favorable biocompatibility. These findings highlight the potential of FA-CS-based nanocarriers for enhancing CBD clinical application in breast cancer therapy.”
“Cannabidiol (CBD) has gained a lot of interest in recent years for its purported medicinal properties. CBD has been investigated for the treatment of anxiety, depression, epilepsy, neuroinflammation, and pain.
Recently there has been an interest in CBD as a possible treatment for age-related disorders such as Alzheimer’s disease and related disorders (ADRD). Here we tested the hypothesis that chronic CBD administration would improve learning and memory in the SAMP8 mouse model of Alzheimer’s disease.
SAMP8 mice aged 11 months (at the start of the study) were administered vehicle or CBD (3 or 30 mg/Kg) daily via oral gavage for 2 months. Vehicle-treated young SAMP8 mice (age 3 months at the start of the study) served as unimpaired controls. After 30 days of treatment (4 and 12 months of age), learning and memory, activity, anxiety, strength and dexterity were assessed.
High dose CBD treatment significantly improved learning and memory of the 12-month-old mice in the T maze. Novel object recognition memory was also improved by CBD in aged CBD treated mice. Aged CBD treated mice also displayed less anxiety in the elevated plus maze test compared to controls. However, activity and strength levels were similar between groups. Biochemical analysis revealed decreased markers of oxidative stress, providing a possible mechanism by which CBD treatment impacts learning, memory, and anxiety.
These results highlight the potential use of CBD as a therapeutic for age related cognitive impairment and dementia.”
“Cannabidiol (CBD) is an abundant phytocannabinoid found in the Cannabis sativa plant.”
“CBD is thought by many to have medicinal properties. Except for a few conditions including two rare forms of epilepsy and multiple-sclerosis-associate spasticity, CBD has not been approved by the FDA”
“Here, we examine the potential use of CBD in treating age- related memory loss, anxiety, strength and dexterity impairment in the Senescence-accelerated mouse -prone 8(SAMP8) mice, a polygenic model of spontaneous onset AD.”
“Our results indicate that CBD can reverse age-related changes in the SAMP8 mice. CBD reversed memory impairment in both the T-maze and NOR with a 24-hour retention interval. These results indicate that CBD is able to reverse memory impairment in both spatial and recognition tasks. Taken together therefore, there appears to be an antioxidant effect of CBD contributing to the improvement in memory in the aged mice. These results show that CBD is an attractive therapeutic warranting further investigation in AD, and other neurodegenerative diseases.”
“Background: The 2018 Farm Bill states that cultivars of Cannabis sativa L. (industrial hemp) are legal for industrial use if total tetrahydrocannabinol (THC) concentrations are less than 0.30%. Due to this legislation, hemp cultivars with low total THC have found a wide range of uses, from animal feed to paper production. Although cannabinoids are the most widely studied compounds in hemp, hemp produces numerous other compound classes as well, and these phytochemicals may have uses in the functional food and pharmaceutical industry.
Methods: Initial liquid chromatography profiling of hemp root samples revealed a group of uncharacterized peaks, and these peaks were tentatively identified as neolignans by Oribitrap ID-X high resolution mass spectrometer. To further elucidate the structure of these neolignans, we used techniques in liquid-liquid extraction, as well as flash chromatography to isolate them in preparation for NMR analysis. We then tested their inhibitory concentration 50 (IC50) in a variety of cancer cell lines.
Results and discussion: Four neolignans were isolated from hemp roots and each differed in their molecular weight by 30 daltons. Two of the compounds were identified as dadahols A and B. We tested fractions of various purities containing neolignans against neuroblastoma cell lines CHLA15 and LAN5, hepatoblastoma cell line Hep3B, and Hodgkin’s lymphoma cell line L428. We found that semi-pure fractions containing dadahol A and/or dadahol B had the highest cytotoxic activity. We then tested pure dadahol A and dadahol B, and this revealed dadahol A exhibited the lowest IC50 values in all the cell lines.”
“We report, for the first time, that dadahols, using the methodologies described herein, have antiproliferative effects. While our findings demonstrate the cytotoxic effects of hemp-derived compounds on multiple pediatric cancer cell lines, the underlying mechanisms driving these effects remain to be elucidated.”
“This review aims to assess the therapeutic potential of cannabinoids as complementary treatments for atopic dermatitis. Atopic dermatitis (AD) is a skin disease characterized by the loss of skin barrier function that promotes subsequent symptoms such as intense itching, xerosis and inflammation. Several treatments are available, particularly topical approaches, which are crucial for both acute and chronic management of the disease.
The main objectives of topical treatments are to promote skin hydration and reduce itching and immune responses, typically through lotions and topical medications such as glucocorticoids. However, the long-term use of glucocorticoids presents certain disadvantages, highlighting the need for new therapeutic options to minimize adverse effects and providing a broader range of choices for both physicians and patients to find the best alternative for each case.
Research involving cannabinoids, which can be endogenous, plant-based or synthetic, has intensified in recent years to evaluate the therapeutic potential of these compounds for skin conditions, including AD. Studies suggest that phytocannabinoids such as cannabidiol (CBD) and Δ-9-tetrahydrocannabinol (THC), along with endogenous and synthetic compounds such as palmitoyletanolamide (PEA) and dronabinol, can improve AD symptoms, primarily because of their anti-inflammatory, antipruritic and antioxidant properties. Additionally, some cannabinoids exhibit antimicrobial effects.
Despite these promising results, the use of cannabinoids in AD treatment requires further investigation to better understand their efficiency and safety, necessitating high-accuracy clinical and preclinical trials.”
“Cannabinoids, whether of plant, endogenous, or synthetic origin, clearly possess significant therapeutic potential and should be further explored as complementary treatments for AD. The development of cannabinoid-based formulations for skin conditions is not limited to products classified as medicines by pharmaceutical regulatory agencies, but also includes their use as active ingredients in cosmetic formulations, such as soaps, shampoos, and especially moisturizing lotions and creams, for individuals with AD and other conditions requiring enhanced skin hydration.
Beyond the therapeutical potential of the classical phytocannabinoids CBD and THC, other components such as CBG and CBC have also been investigated for their dermatological benefits, including anti-inflammatory, antibacterial, and antioxidant properties that may contribute to skin health and the treatment of various skin disorders, including AD .”
“Extensively drug-resistant (XDR) Acinetobacter baumannii poses a serious clinical challenge due to its resistance to nearly all available antibiotics, including carbapenems and colistin. Cannabidiol (CBD), a non-psychoactive phytochemical from Cannabis sativa L., has recently shown promising antimicrobial activity.
This study evaluates the antibacterial and anti-biofilm effects of CBD against XDR A. baumannii isolates and explores its mechanism of action and potential as an adjunct therapeutic agent.
Twenty-six A. baumannii isolates collected from ICU medical devices were identified using MALDI-TOF/MS. Antimicrobial susceptibility was assessed by disk diffusion and broth microdilution to determine MICs and MBCs for CBD and standard antibiotics. Synergistic effects were evaluated via checkerboard assays and FICI values. Biofilm inhibition and eradication were assessed using crystal violet and MTT assays. Time-kill studies, membrane integrity assays (DNA/protein leakage, NPN uptake, membrane depolarization), and scanning electron microscopy (SEM) were employed to investigate bactericidal kinetics and membrane-disruptive mechanisms.
CBD exhibited activity against antimicrobial resistance isolates (MIC: 3.9 to > 500 µg/mL). Remarkably, CBD synergized with gentamicin, meropenem, and colistin, reducing their effective concentrations by up to 1,000-fold. Combination therapy significantly inhibited and eradicated biofilms. Time-kill assays demonstrated rapid, concentration-dependent killing, with complete bacterial clearance at 4× MIC within 2 h. Mechanistic assays and SEM confirmed that CBD induces extensive membrane damage.
These findings highlight CBD’s potential as an effective adjunct to conventional antibiotics for treating XDR A. baumannii infections, offering a novel strategy to counteract antimicrobial resistance.”
“Acinetobacter baumannii is an opportunistic, Gram-negative bacterium that has emerged as a major cause of hospital-associated infections (HAIs) worldwide, with no standard therapeutic recommendation for its management and control. It primarily affects critically ill and immunocompromised patients, leading to severe infections such as ventilator-associated pneumonia, bloodstream infections, urinary tract infections, meningitis, and wound infections. A. baumannii’s remarkable ability to survive in hospital environments, resist desiccation, and persist on medical equipment—particularly in intensive care units (ICUs)—makes it a persistent challenge in healthcare settings.”
“Our study demonstrates that CBD exhibits potent antibacterial and anti-biofilm properties against XDR A. baumannii, particularly when used in combination with conventional antibiotics such as gentamicin, meropenem, and colistin. Notably, its ability to disrupt membrane integrity represents a key mechanism in overcoming drug tolerance.
These findings provide a strong foundation for further investigation of CBD as a novel therapeutic strategy to combat antimicrobial resistance in clinical settings.”
“The last decades of research have shown that the endocannabinoid system may be a promising therapeutic target for the pharmacological treatment of cancer in human medicine and possibly in veterinary medicine as well.
Compared with the original cells, the expression of gene encoding for receptors and enzymes belonging to the endocannabinoid system has been found to be altered in several tumor types; it has been hypothesized that this aberrant expression may be related to the course of the neoplasm as well as to the patient’s prognosis.
Several studies, conducted both in vitro and in vivo, suggest that both endo- and phytocannabinoids can modulate signaling pathways, controlling cell proliferation and survival. In the complex process of carcinogenesis, cannabinoids seem to intervene at different levels by stimulating cell death, inhibiting the processes of angiogenesis and metastasis, and regulating antitumor immunity.
Although the molecular mechanisms by which cannabinoids act are not always clear and defined, their synergistic activity with the most used antineoplastic drugs in clinical oncology is showing promising results, thus providing veterinary medicine with alternative therapeutic targets in disease control.
This review aims to summarize current knowledge on the potential role of the endocannabinoid system and exogenous cannabinoids in oncology, with specific reference to the molecular mechanisms by which cannabinoids may exert antitumor activity. Additionally, it explores the potential synergy between cannabinoids and conventional anticancer drugs and considers their application in veterinary oncology.”
“Companion animals are more and more becoming considered family members, and their owners wish to offer them the same level of cure and care expected for a human being. The long life expectancy of dogs and cats is associated with new challenges: veterinary medicine must be prepared to diagnose and treat neoplastic pathology with the same high-standard procedures that are currently used in human medicine.
Chemotherapies aim to prolong as long as possible the life of companion animals affected by cancer, but several side effects can be experienced. Thus, an increasing interest in alternative and complementary treatments has arisen in the last years. Among a wide array, cannabinoids seem to be a promising tool to be included in therapeutic protocols since their administration could assist traditional chemotherapeutic agents, promoting a more successful antineoplastic effect, prolonging the prognosis, and contributing to patient well-being thanks to pain relief.
According to all the aforementioned factors, the present review aims to summarize how the endocannabinoid system and phytocannabinoids interact in the complex process of carcinogenesis, exploring current therapeutical applications and future perspectives in veterinary oncology.”
“From the above paragraphs, it can be concluded that cannabinoids show antitumor activity (decrease in tumor growth and invasiveness) in numerous cell lines and in various animal models of cancer, and that, although clinical studies conducted in human and animal patients are limited, the results obtained so far have demonstrated that cannabinoids appear to be safe and effective antineoplastic agents.
Moreover, most of the preclinical evidence currently available demonstrates that the greatest therapeutic potential of cannabinoids lies in their combination with existing chemotherapeutic drugs.
Interestingly, compared to conventional antineoplastic drugs, which have a plethora of side effects, cannabinoids (especially the non-psychoactive ones, such as CBD) have a broad safety margin. “
