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Canna~Fangled Abstracts

The Pharmacological Effects of Plant-Derived versus Synthetic Cannabidiol in Human Cell Lines

By March 1, 2022No Comments

Journal List > Med Cannabis Cannabinoids > v.4(2); Winter 2021 > PMC8832208

 2021 Winter; 4(2): 86–96.
Published online 2021 Jul 29. doi: 10.1159/000517120
PMCID: PMC8832208
PMID: 35224428
Ryan F. Maguire, a Daniel J. Wilkinson, a Timothy J. England, a , b and Saoirse E. O’Sullivan a , c ,*
Author information Article notes Copyright and License information Disclaimer

Associated Data

Supplementary Materials

Abstract

Introduction

Cannabidiol (CBD) can be isolated from Cannabis sativa L. or synthetically produced. The aim of this study was to compare the in vitro effects of purified natural and synthetic CBD to establish any pharmacological differences or superiority between sources.

Methods

Six purified samples of CBD were obtained, 4 of these were natural and 2 synthetic. The anticancer effects of CBD were assessed in a human ovarian cancer cell line (SKOV-3 cells). The neuroprotective effects of CBD were assessed in human pericytes in a model of stroke (oxygen glucose deprivation [OGD]). The ability of CBD to restore inflammation-induced intestinal permeability was assessed in differentiated human Caco-2 cells (a model of enterocytes).

Results

(1) In proliferating and confluent SKOV-3 cells, all CBD samples similarly reduced resazurin metabolism as a marker of cell viability in a concentration-dependent manner (p < 0.001). (2) In pericytes exposed to OGD, all CBD samples similarly reduced cellular damage (measured by lactate dehydrogenase) at 24 h by 31–48% and reduced inflammation (measured by IL-6 secretion) by 30–53%. Attenuation of IL-6 was inhibited by 5HT<sub>1A</sub> receptor antagonism for all CBD sources. (3) In differentiated Caco-2 cells exposed to inflammation (TNFα and IFNγ, 10 ng/mL for 24 h), each CBD sample increased the speed of recovery of epithelial permeability compared to control (p < 0.05–0.001), which was inhibited by a CB<sub>1</sub> receptor antagonist.

Conclusion

Our results suggest that there is no pharmacological difference in vitro in the antiproliferative, anti-inflammatory, or permeability effects of purified natural versus synthetic CBD. The purity and reliability of CBD samples, as well as the ultimate pharmaceutical preparation, should all be considered above the starting source of CBD in the development of new CBD medicines.

Keywords: Cannabidiol, Synthetic cannabidiol, Plant, Pharmacology, Cannabinoid receptor 1, 5HT1A

Introduction

Preclinical and early clinical phase studies demonstrate the potential of cannabidiol (CBD) in cancer, stroke, anxiety, and pain [], and a purified form of CBD (98%, Epidiolex®) is already licensed to treat seizures associated with Dravet syndrome, Lennox-Gastaut syndrome, and tuberous sclerosis []. Around 65 molecular targets for CBD have been identified [] with different targets responsible for different therapeutic effects of CBD. For example, serotonin 1A receptor (5HT1A) activation is associated with reductions in anxiety, nausea, and neuroprotective effects []. Transient receptor potential cation channel subfamily V member 1 (TRPV1) interactions have been implicated in the antinociceptive effects of CBD []. Peroxisome proliferator-activated receptor gamma (PPARγ), cyclooxygenase-2 (COX-2), and GPR55 have been linked to the anticancer effects of CBD []. Cannabinoid receptor 1 (CB1) interactions have been linked with CBD’s ability to reduce intestinal permeability []. The polypharmacology of CBD may underpin its ability to affect many pathologies.

Over-the-counter CBD products are mainly produced from Cannabis sativa L. with a THC content below 0.2% (hemp). Epidiolex® is produced using C. sativa L. with a higher THC content. CBD can also be produced synthetically through a series of chemical reactions, yielding a highly pure form of CBD []. Natural CBD products are either refined to get purified CBD (97–99%), or crude extraction methods are used to yield CBD alongside other phytocannabinoids, terpenes, and flavonoids, which is known as a “CBD-rich extract.”

One complication that can arise in reviewing the effectiveness of CBD medicines is this range of products that include purified isolate forms or extracts containing other chemicals. Some suggest that CBD-rich extracts are therapeutically superior because of the “entourage” hypothesis. Scientific evidence, however, is equivocal. Gallily and colleagues [] showed CBD-rich extracts were more effective than purified CBD in attenuating inflammation and hyperalgesia in rats. Similarly, Pagano et al. [] showed a CBD-rich extract was more beneficial in attenuating intestinal inflammation and hypermobility in mice. In contrast, Scott et al. [] found purified CBD was more efficacious than a CBD-rich extract in glioblastoma cell lines. Ligresti and colleagues [] also found purified CBD was more potent in reducing proliferation in some cancer cell lines, while in others, the CBD-rich extract was more potent. Similarly, Raup-Konsavage and colleagues [] found that pure CBD was more efficacious than 3 different CBD extracts in reducing cancer cell viability. Thus, it is not yet clear whether purified or CBD extracts are superior, or whether this is different depending on the pathological situation in which CBD is being tested. There are also no controlled clinical trial data to support either argument.

Because of the perception that CBD extracts are superior to purified CBD, synthetic CBD products are sometimes perceived as inferior. A recent study in Germany asked 153 epileptic patients whether they worry about the origin of CBD. Seventy-three percent favored natural CBD []. The main reasons were a preference for a botanical origin, a perceived lack of toxicity relative to synthetic forms, and an absence of chemical reactions in the manufacturing process. Conversely, there is also a perception that contaminations of natural CBD products (such as pesticides, heavy metals, microbial pathogens, and carcinogenic compounds) during cultivation, manufacturing, and packaging may limit the pharmaceutical use of natural CBD []. There are no head-to-head clinical studies comparing plant versus synthetic CBD. However, studies assessing the efficacy, safety, and pharmacokinetic parameters of synthetic CBD in drug-resistant epilepsy [] found very similar characteristics relative to natural CBD [].

In light of the lack of data directly comparing purified CBD of various origins, this study aimed to establish whether the CBD source affects its pharmacological effects in human cells. Our hypothesis was that there would be no difference in the effects produced between CBD samples of similar purity.

Methods

Materials

CBD derived from 2 different sources (4 natural and 2 synthetic) were obtained from 6 companies (see Table Table1).1). Only Logical confirmed to use a synthesis process selective for the naturally occurring (−) enantiomer of CBD. For natural CBD, manufacturers’ analysis demonstrated Medropharm (Medropharm GmbH) was 98.6% CBD, 0.2% CBD-C4 analog, 0.6% cannabidivarin (CBD-C3, CBDV), and 0.3% cannabigerol. Flora Fusion was 99.3% CBD and 0.2% CBDV. CBDepot was 98.7% CBD, 0.3% CBD-C4, and 0.6% CBDV. Ai Lab was 99.4% CBD and had no data regarding any impurities. Of the synthetic CBD, Logical was 98.9% and THC Pharm was 99.8% pure. The presence of impurities was not assessed in either synthetic CBD sample. CBD was in ethanol at 10−1 mol/L. For each experimental repeat, a new stock solution was made.

Table 1

Origin, manufacturer’s and our laboratory’s analytical data from each CBD sample, and summary of data generated in each cell type (percentage magnitude of change relative to vehicle)

Manufacturer (source) Purity

 Efficacy
CBD purity (our lab) CBD purity (manufacturer) GC/MS, HPLC, or CC CBD-C4 CBDV delta-9-THC delta-8-THC CBG proliferating SKOV-3 (resazurin, 48 h, 10 μM vs. veh) confluent SKOV-3 (resazurin, 48 h, 50 μM vs. veh) pericytes (LDH, 24 h, 100 nM vs. veh) pericytes (IL-6, 24 h, 100 nM vs. veh) Caco-2 (TEER, mean AUC, SEM, 10 μM vs. veh)
Medropharm (plant) 93.3%±1 GC/MS 98.6%±0.1 HPLC 0.2%±0.1 0.6%±0.1 >0.01% >0.01% 0.3%±0.1 −41±2 (p < 0.001) −90±5 (p < 0.001) −84±7.3 (p < 0.001) −106±12.2 (p < 0.01) 218±50 (p < 0.001)
Flora Fusion (plant) 100%±1.5 GC/MS 99.3%±0.1 CC nd 0.2%±0.1 nd nd nd −56±5 (p < 0.001) −85.2±0.7 (p < 0.001) −83±7.5 (p < 0.001) −104±12.7 (p < 0.0001) 292±36 (p < 0.0001)
CBDepot (plant) 97%±0.6 GC/MS 98.7%±0.1 HPLC 0.3%±0.1 0.6%±0.1 nd nd na −46±5 (p < 0.001) −93.4±2 (p < 0.001) −85±8.6 (p < 0.001) −99±11.0 (p < 0.001) 200±60 (p > 0.01)
Ai Lab (plant) 95%±1.1 GC/MS 99.4%±0.1 HPLC na na na na na −37±5 (p < 0.001) −94±0.3 (p < 0.001) −70±9.6 (p < 0.01) −111 ± 13.3 (p < 0.001) 598±172 (p < 0.01)
Logical (synthetic) na 98.9% GC/MS na na na na na −37±4 (p < 0.001) −91±0.2 (p < 0.001) −82±10.6 (p < 0.001) −115±9.4 (p < 0.0001) 413±106 (p < 0.01)
THC Pharm (synthetic) 111%±0.06 GC/MS 99.8% GC/MS na na na na na −37±4 (p < 0.001) −92±0.8 (p < 0.001) −67±11.2 (p < 0.0001) −114±12.1 (p < 0.0001) 319±72 (p < 0.001)

Where appropriate data were collated between identical experiments. All data are displayed as percentage change relative to vehicle (±SEM). CBD samples were compared to vehicle or each other using a one-way ANOVA alongside a multiple comparison. CBD, cannabidiol; na, not available; nd, not detectable; CBDV, cannabidivarin, THC, delta-9-tetrahydrocannabinol, CBG, cannabigerol; GC/MS, gas chromatography/mass spectrometry; HPLC, high-performance liquid chromatography; CC, convergence chromatography.

Antagonists of receptors known to mediate CBD effects were used at relevant concentrations: CB1 receptor antagonist, AM251 (100 nM); CB2 receptor antagonist, AM630 (100 nM); GPR18 antagonist, O-1918 (1 μM); GPR55 antagonist, CID16200 (5 μM); PPARα antagonist, GW6471 (100 nM); PPARγ antagonist, GW9662 (100 nM); TRPV1 receptor antagonist, SB-36679 (1 μM); and 5HT1A antagonist, WAY-100635 (300 nM). All antagonists were from Tocris (Abingdon, UK). When used, antagonists were applied 20 min before CBD.

Cell Culture

Cells were maintained in a humidified cell culture incubator at 37°C with 5% CO2 and cultured to 70–80% confluence in a T75 flask. SKOV-3 (The European Collection of Authenticated Cell Cultures [ECACC, Salisbury, UK], passages 24–31) cell lines were cultured to 70–80% confluence in Roswell Park Memorial Institute (RPMI) 1640 base medium containing L-glutamine and phenol red indicator (Gibco), supplemented with 10% heat-inactivated FBS and 1% penicillin-streptomycin (P/S). Human brain vascular pericytes (ScienceCell, Carlsbad, CA, USA, passages 3–6) were cultured in specialized pericyte medium (2% FBS, 1% pericyte growth supplement, and 1% P/S; ScienceCell, Carlsbad, CA, USA). Caco-2 cells (ECACC, Salisbury, UK) (passages 37–49) were cultured in Minimum Essential Medium Eagle (1% P/S, 1% nonessential amino acids, and 10% FBS).

Gas Chromatography/Mass Spectrometry

Test stock solutions of each CBD compound were made up at 50 µg/mL by weight in methanol. Twenty microliters of 10 µg/mL D3-CBD (Sigma-Aldrich, Poole, UK) was added to 100 µL of standard and test stock solution, mixed, and evaporated until dry under nitrogen at 30°C. Samples and standards were derivatized to their CBD-TMS esters by adding 70 µL of acetonitrile and 70 µL of BSTFA (Apollo Scientific, Manchester, UK) and incubating for 90 min at 90°C. 0.5 µL of each sample and standard was injected into a Trace 1310-TSQ 8000 GC-MS/MS (Thermo Scientific, Hemel Hempstead, UK) in SRM mode monitoring m/z transitions 390–319 for unlabeled CBD and 393–319 for D3-labeled CBD. Concentrations of test stock solutions were calculated from the standard curve of known CBD concentrations ranging from 20 to 80 µg/mL and % recovery calculated. Linearity of standard curves was assessed for each assay and accepted if R2 > 0.97. CV for repeat sample injections was 1%.

Anticancer Effects of CBD in SKOV-3 Cells

To identify the concentration of CBD to use in studies with SKOV-3 cells, a concentration-response curve was constructed with CBD from THC Pharm (see online suppl. Fig. 1; for all online suppl. material, see www.karger.com/doi/10.1159/0005171203). SKOV-3 cells were seeded into 96-well plates at a density of 10,000 cells/cm2 and left to adhere for 3 h. Media were replaced with fresh media containing either vehicle (ethanol) or CBD (10–50 µM). Plates were allocated into 2 time points: 24 and 48 h. At each time point, resazurin (Sigma-Aldrich, Poole, UK) dissolved in PBS (Thermo-Fisher, UK) was added to the wells to produce an in-well concentration of 100 µM and returned to the incubator for 2 h. Plates were read using a Fluoroskan Ascent microplate fluorometer (Thermoelectron Corporation, Waltham, MA, USA) at 560 nm excitation and 590 nm emission. Ten and 50 µM were identified as subeffective and effective concentrations for similar experiments comparing the different CBD samples.

In separate experiments, the cytotoxic effect of CBD was investigated using confluent SKOV-3 cells. Cells were seeded into 96-well plates and given 2 days to reach confluence. The media were aspirated and replaced with fresh media either containing ethanol (vehicle) or CBD (10 or 50 µM) for 24 or 48 h and resazurin metabolism measured as before.

Oxygen Glucose Deprivation Experiments in Pericytes

Human pericytes were exposed to oxygen glucose deprivation/reperfusion (OGD/R) as a model of stroke []. Cells were seeded at 20,000 cells/cm2 in a 96-well plate. Once confluent, cells were incubated for 24 h to establish baseline samples. The media were replaced with RPMI glucose-free media (Invitrogen, Carlsbad, CA, USA), containing either CBD (10 or 100 nM) or vehicle (ethanol) based on our unpublished work. Plates were sealed into GasPak EZ Anaerobe Pouches (Beckton Dickinson, Oxford, UK) and placed into the incubator, producing anoxic conditions within 20 min []. After 4 h, media were collected and replaced with complete pericyte growth medium containing either CBD (10 or 100 nM) or ethanol (vehicle) and returned to normoxic conditions for 20 h. Media concentrations of IL-6 (immediately after OGD and 24 h; R&D systems ELISA) and lactate dehydrogenase (LDH, 24 h only; Abcam) were measured as per manufacturer’s instructions.

Inflammation and Permeability Experiments in Caco-2 Cells

Caco-2 cells (P32–45) were seeded onto the apical compartments of polycarbonate transwell inserts (12-mm diameter, 0.4-µm pore diameter; Transwell; Corning Inc., Corning, NY, USA) at a density of 20,000 cells/cm2 with complete medium. Cells were differentiated over 21 days into gut enterocyte-like cells. Transepithelial electrical resistance (TEER, ohms, Ω) was used to quantify barrier integrity using STX2 chopstick electrodes attached to an Ohm meter (World Precision Instruments, Hitchin, UK) []. Wells with a resistance of over 999 Ω were used for experiments. The basolateral compartments of each well were treated with 10 ng/mL IFNγ, and 8 h later, with 10 ng/mL TNFα. Sixteen hours later, TEER was measured and the wells washed once with PBS. Fresh media containing CBD (10 µM) were applied to the apical membrane and TEER measured up to 72 h.

Data Analysis

Statistical analyses were performed using GraphPad Prism 8.2.0 and assessed for Gaussian distribution prior to analysis. Resazurin, LDH, and IL-6 datasets were analyzed using one-way ANOVA alongside a Dunnett’s post hoc test comparing CBD samples against vehicle controls, as well as a multiple comparison comparing each CBD sample at the respective concentrations and time points. Caco-2 time course data were analyzed using area under the curve (AUC), quantified using the trapezoidal method, and compared to vehicle using an unpaired t test. AUC data were compared by the CBD sample using a one-way ANOVA multiple comparison with a Dunnett’s post hoc test.

Results

Gas Chromatography/Mass Spectrometry

In general, the purity of each CBD was lower for our laboratory’s measurements than the manufacturers’ (Table (Table1).1). This could be due to different measurement techniques and/or degradation over time. Regardless, the purity of the CBD samples was independently confirmed in our lab using GC/MS. Logical CBD suffered from a poor percentage recovery in both runs, and unfortunately, the particular batch of Logical CBD used in the cellular experiments had been exhausted following these runs, so we were unable to obtain purity data with this sample.

Anticancer Effects of Natural and Synthetic CBD in SKOV-3 Cell Line

In proliferating SKOV-3 cells, at 24 h (Fig. (Fig.1a),1a), 10 µM Medropharm (−53% ± 6), Flora Fusion (−55% ± 6), and CBDepot (−59% ± 6) reduced resazurin metabolism relative to vehicle control (p < 0.0001). Logical CBD also reduced resazurin metabolism, albeit to a lesser extent (−33% ± 9, p < 0.05; Fig. Fig.1a).1a). At 24 or 48 h, 50 µM of all CBD sources produced similar reductions in resazurin metabolism compared to vehicle (p < 0.0001; Fig. 1a, b). No statistically significant differences existed between CBD samples.

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Effects of various CBD samples on SKOV-3 cellular metabolism using resazurin assays. CBD (10 or 50 µM) was applied to proliferating SKOV-3 cells for 24 (a) and 48 h (b) (n = 15 from 3 separate experiments). Effects of CBD (10 and 50 µM) on confluent SKOV-3 cells applied for 24 (c) and 48 h (d) (n = 10 from 2 separate experiments). Data are displayed as mean ± SEM % change from vehicle and were compared for statistical significance against vehicle using a one-way ANOVA. *p ≤ 0.05; ****p ≤ 0.0001. CBD, cannabidiol.

In fully confluent SKOV-3 cells, after 24 h, only 50 µM CBD reduced resazurin metabolism relative to vehicle (−55 to −74%, p < 0.0001; Fig. Fig.1c).1c). Similarly, after 48 h, only 50 µM CBD reduced resazurin metabolism relative to vehicle (−85 to −95%, p < 0.0001; Fig. Fig.1d).1d). No significant differences were observed at either concentration or time point between CBD samples. None of the selected antagonists (to 5HT1A, CB1, CB2, GPR18, GPR55, PPARα, PPARγ, and TRPV1 receptors) inhibited the reduction in metabolism associated with CBD (Fig. (Fig.22).

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Effects of CBD (THC Pharm) 25 µM on proliferating SKOV-3 cells after 24 or 48 h in the presence of WAY-100635, AM251, AM630, GW9662, O1918, SB366791 GW6471, or CID16020046 (n = 7 from 2 separate experiments). Data are displayed as mean ± SEM absorbance, and CBD + antagonist data were compared against CBD 25 µM alone using a one-way ANOVA. *p ≤ 0.05; ****p ≤ 0.0001. CBD, cannabidiol.

The Effects of CBD in Pericytes Exposed to OGD

IL-6 content immediately after OGD was 225% ± 63 (p < 0.05; Fig. Fig.3a)3a) higher than in normoxic control cells and at 24 h was 184% ± 26 higher (p < 0.01; Fig. Fig.3b).3b). At 24 h, LDH activity in media was 118% ± 18 higher than normoxic control cells (p < 0.01; Fig. Fig.3c3c).

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Effects of CBD in pericytes (p4–6) exposed to 4-h OGD. a Effect of CBD (10 or 100 nM) on LDH concentrations 24 h following initiation of OGD (n = 6, from 2 separate experiments). Effect of various CBD samples (10 or 100 nM) on media IL-6 concentrations immediately after OGD (b), or 24 h following the initiation of OGD (c) (n = 6, from 2 separate experiments). Data are displayed as mean ± SEM % change from normoxic control and were compared for statistical significance against the normoxic control (#) or OGD vehicle (*) using a one-way ANOVA. *p ≤ 0.05, **p ≤ 0.01, and ***p ≤ 0.001. CBD, cannabidiol; OGD, oxygen glucose deprivation.

IL-6 secretion immediately after OGD was not significantly raised in the presence any of the CBDs at 10 or 100 nM (Fig. (Fig.3a).3a). IL-6 secretion at 24 h following OGD was also not significantly raised relative to the normoxic control in the presence of CBD (100 nM). No statistical differences were present between CBD samples at their equivalent concentrations and time points.

LDH activity was also not significantly raised above normoxic control in the presence of CBD (24 h; Fig. Fig.3c).3c). At 100 nM, Medropharm (−91% ± 18, p < 0.05), Flora Fusion (−96% ± 9, p < 0.01), CBDepot (−104% ± 19, p < 0.05), and THC Pharm (−73% ± 18, p < 0.05) also significantly reduced LDH activity relative to the OGD vehicle.

CBD 100 nM was coapplied with the 5HT1A antagonist WAY-100635 []. As before, IL-6 secretion was blunted by CBD (Fig. (Fig.4a,4a, 50–63% relative to vehicle). However, in the presence of WAY-100635, this effect was reduced such that an increase in IL-6 secretion was observed (Fig. (Fig.4a).4a). There was no obvious effect of WAY-100635 on LDH activity (Fig. (Fig.4b4b).

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Effects of natural and synthetic CBD (100 nM) on LDH and IL-6 concentrations in pericytes exposed to 4-h OGD in the presence or absence of the 5HT-1A antagonist WAY-100635 (300 nM). a IL-6 concentrations 24 h following the initiation of OGD (n = 11–13, from 3 separate experiments). b LDH concentrations in media from 24 h following initiation of OGD (n = 12–13, from 3 separate experiments). Data are expressed as mean ± SEM % change from normoxic and were compared to normoxic control (#) or OGD vehicle (*) using a one-way ANOVA with a multiple comparison. *p ≤ 0.05, **p ≤ 0.01, ***p ≤ 0.001, and ****p ≤ 0.0001. M, Medropharm; F, Flora Fusion; C, CBDepot; A, Ai Lab; L, Logical; T, THC Pharm; CBD, cannabidiol; OGD, oxygen glucose deprivation.

CBD Effects on Caco-2 Barrier Integrity following Inflammation

Following an inflammatory protocol, barrier resistance was reduced by ∼30%, indicating increased permeability []. When analyzed as the total effect over time (AUC) (%·min−1), all CBD samples increased TEER following inflammation relative to their vehicle control (Fig. 5b–f; Table Table11 for pooled data). No statistical differences were present between CBD samples in their ability to restore intestinal permeability. As before (Fig. (Fig.5),5), when CBD was administered alone, it successfully increased the recovery of TEER values following a 24-h inflammatory protocol. However, when CBD was coadministered with AM251 (1 µM), this effect was inhibited (Fig. (Fig.66).

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Effects of natural (a–d) and synthetic CBD (ef) on intestinal permeability following a 24-h inflammatory protocol (IFNγ and TNFα, shown as the solid bar) in differentiated Caco-2 cells. Data are displayed as mean ± SEM % change from baseline inserts (n = 5–6, from 3 separate experiments). Time course data are displayed as AUC and analyzed using a one-way ANOVA. CBD samples were compared to vehicle or each other using a multiple comparison *p ≤ 0.05, **p ≤ 0.01, and ***p ≤ 0.001. AUC, area under the curve; CBD, cannabidiol.

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Effects of natural (a–d) and synthetic (ef) CBD on intestinal permeability following a 24-h inflammatory protocol (IFNγ and TNFα, shown as the solid bar) in differentiated Caco-2 cells in the presence or absence of the CB1 receptor antagonist AM251 (—). Time course data are displayed as AUC and analyzed using a one-way ANOVA. CBD samples were compared to vehicle or each other using a multiple comparison **p ≤ 0.01, ***p ≤ 0.001, and ****p ≤ 0.0001. AUC, area under the curve; CBD, cannabidiol.

Discussion

The aim of this study was to investigate whether CBD derived from different sources (natural or synthetic) would behave similarly in 3 human cell models of disease. Across all experiments, all CBD samples at their respective concentrations and time points produced very similar effects. Whilst some minor variability existed in the magnitude of effect and percentage purity of CBD samples, none of these differences manifested in one particular sample of CBD being superior. These data support our hypothesis that there is no pharmacological difference between purified natural and synthetic CBD in vitro.

CBD has antiproliferative [] and apoptotic features [] in multiple cancer cell lines. We explored the effects of CBD in the ovarian cancer cell line SKOV-3 and whether the CBD origin influenced results. Ten micromolar CBD reduced cell viability in proliferating cells, and 50 µM CBD was cytotoxic in proliferating and confluent cells. The effects of CBD were greater at 48 h. None of the purified CBD samples differed in their efficacy across concentrations or time points, suggesting regardless of how CBD is produced, its antiproliferative/cytotoxic effects remain the same, at least in the SKOV-3 cell line. Since the effects of CBD were not attenuated by the range of antagonists used and the high concentration of CBD required, it is likely this is a nonreceptor-mediated mechanism, for example, on mitochondria membrane potential and/or ROS generation [], which should be investigated in future experiments.

CBD possesses several properties that could be useful in treating ischemia and reperfusion injuries including modulation of intracellular calcium [], attenuating BBB permeability [], improving glucose metabolism, and optimizing energy production [] and as an antioxidant molecule []. The aim of the present experiments was to investigate the effects of different natural and synthetic CBD samples on cell damage in pericytes exposed to OGD and reperfusion. All CBD samples were able to prevent OGD-induced increases in IL-6 and LDH, and the anti-inflammatory effect of CBD was partially reduced by 5HT1A antagonism, as previously observed []. This suggests both synthetic and natural CBDs can activate 5HT1A, which is the molecular target underpinning many therapeutic effects including stroke, anxiety, and pain. As far as we are aware, this is the first study showing the protective properties of CBD in pericytes exposed to OGD/R injury.

As we have previously shown [], Caco-2 barrier integrity could be restored by administering CBD to the apical compartment of transwell inserts following a 24-h inflammatory protocol. Further work by our laboratory demonstrated these effects of CBD extend to human colon explants exposed to inflammation []. In both studies, the ability of CBD to restore barrier integrity was inhibited by CB1 antagonism []. Most recently, we showed that CBD (600 mg) was protective against aspirin-induced permeability increases in healthy volunteers in vivo []. In this present set of experiments, all CBD samples restored barrier integrity of differentiated Caco-2 cells following inflammation to a similar extent, and the effects on barrier integrity were reduced by antagonism of the CB1 receptor for all CBD samples. These results suggest natural and synthetic CBDs have similar pharmacological effects in a cellular model of acutely inflamed small intestine.

One caveat to consider is that natural CBD can contain other phytocannabinoids, albeit in small amounts (see Table Table1).1). However, the concentration of these compounds would be moderate with high concentrations of CBD. For example, the most abundant contaminant was CBDV (0.6%). At 50 µM, the corresponding concentration of CBDV would be ∼300 nM. The CBDV pharmacology is not well characterized, but binding assays demonstrated a Ki of 14.7 µM at CB1 and 570 nM at CB2 []. We believe it is unlikely that the small concentrations of CBDV, or indeed other Cannabis constituents, influenced our results at a pharmacodynamic level. Whether there are pharmacokinetic interactions between these compounds in vivo remains to be tested.

This study demonstrates for the first time that the anticancer, neuroprotective, and intestinal barrier protective properties of purified CBD are similar regardless of the source from which CBD is derived. From a pharmacological perspective, where a molecular target is implicated (i.e., 5HT1A in stroke and CB1 in gut permeability), the effects of CBD were similar. This suggests that any beneficial effects that could be achieved in a clinical setting for purified CBD are likely to be similar at a pharmacodynamic level. Based on this analysis, the economic, environmental impact, purity, reliability, and consistency of CBD, either natural or synthetic, as well as the ultimate pharmaceutical preparation, should all be considered above the starting origin of the CBD in the development of new CBD medicines.

Statement of Ethics

The cell line used in this study was purchased from the European Collection of Authenticated Cell Cultures (SKOV-3 and Caco-2 cells) and ScienceCell, USA (Human brain vascular pericytes). Ethical approval for the use of these cells is not required in accordance with local/national guidelines.

Conflict of Interest Statement

S.E.O’S. is an independent consultant and paid scientific advisor to Artelo Biosciences.

Funding Sources

R.M.’s PhD was funded by Artelo Biosciences, and S.E.O’S. is a paid scientific advisor to Artelo Biosciences.

Author Contributions

R.F.M. and D.J.W. performed the analysis and interpretation described in the manuscript. T.J.E. and S.E.O’S. made substantial contribution to the conception and design of the work. All authors were involved in drafting and reviewing the work and approved the final manuscript.

Supplementary Material

Supplementary data

Supplementary data

References

1. Blessing EM, Steenkamp MM, Manzanares J, Marmar CR. Cannabidiol as a potential treatment for anxiety disorders. Neurotherapeutics. 2015 Oct 4;12((4)):825–36. [PMC free article] [PubMed[]
2. Cherniakov I, Izgelov D, Domb AJ, Hoffman A. The effect of pro nanolipospheres (PNL) formulation containing natural absorption enhancers on the oral bioavailability of delta-9-tetrahydrocannabinol (THC) and cannabidiol (CBD) in a rat model. Eur J Pharm Sci. 2017 Nov 15;109:21–30. [PubMed[]
3. Devinsky O, Cilio MR, Cross H, Fernandez-Ruiz J, French J, Hill C, et al. Cannabidiol: pharmacology and potential therapeutic role in epilepsy and other neuropsychiatric disorders. Epilepsia. 2014 Jun;55((6)):791–802. [PMC free article] [PubMed[]
4. Dumitru CA, Sandalcioglu IE, Karsak M. Cannabinoids in glioblastoma therapy: new applications for old drugs. Front Mol Neurosci. 2018;11:159. [PMC free article] [PubMed[]
5. Gofshteyn JS, Wilfong A, Devinsky O, Bluvstein J, Charuta J, Ciliberto MA, et al. Cannabidiol as a potential treatment for febrile infection-related epilepsy syndrome (FIRES) in the acute and chronic phases. J Child Neurol. 2017;32((1)):35–40. [PubMed[]
6. Hayakawa K, Mishima K, Fujiwara M. Therapeutic potential of non-psychotropic cannabidiol in ischemic stroke. Pharmaceuticals. 2010;3((7)):2197–212. [PMC free article] [PubMed[]
7. Śledziński P, Zeyland J, Słomski R, Nowak A. The current state and future perspectives of cannabinoids in cancer biology. Cancer Med. 2018 Mar;7((3)):5859–75. [PMC free article] [PubMed[]
8. Syed YY, McKeage K, Scott LJ. Delta-9-tetrahydrocannabinol/cannabidiol (sativex®): a review of its use in patients with moderate to severe spasticity due to multiple sclerosis. Drugs. 2014 Apr 27;74((5)):563–78. [PubMed[]
9. Freeman TP, Hindocha C, Green SF, Bloomfield MAP. Medicinal use of cannabis based products and cannabinoids. BMJ. 2019 Apr 4;365:l1141. [PMC free article] [PubMed[]
10. Ibeas Bih C, Chen T, Nunn AV, Bazelot M, Dallas M, Whalley BJ. Molecular targets of cannabidiol in neurological disorders. Neurotherapeutics. 2015 Oct 12;12((4)):699–730. [PMC free article] [PubMed[]
11. Elsaid S, Le Foll B. The complexity of pharmacology of cannabidiol (CBD) and its implications in the treatment of brain disorders. Neuropsychopharmacology. 2020;45:229–30. [PMC free article] [PubMed[]
12. de Mello Schier AR, de Oliveira Ribeiro NP, Coutinho DS, Machado S, Arias-Carrión O, Crippa JA, et al. Antidepressant-like and anxiolytic-like effects of cannabidiol: a chemical compound of cannabis sativa. CNS Neurol Disord Drug Targets. 2014;13((6)):953–60. [PubMed[]
13. Hayakawa K, Mishima K, Nozako M, Hazekawa M, Irie K, Fujioka M, et al. Delayed treatment with cannabidiol has a cerebroprotective action via a cannabinoid receptor-independent myeloperoxidase-inhibiting mechanism. J Neurochem. 2007 Sep 1;102((5)):1488–96. [PubMed[]
14. Rock EM, Bolognini D, Limebeer CL, Cascio MG, Anavi-Goffer S, Fletcher PJ, et al. Cannabidiol, a non-psychotropic component of cannabis, attenuates vomiting and nausea-like behaviour via indirect agonism of 5-HT(1A) somatodendritic autoreceptors in the dorsal raphe nucleus. Br J Pharmacol. 2012 Apr;165((8)):2620–34. [PMC free article] [PubMed[]
15. Costa B, Giagnoni G, Franke C, Trovato AE, Colleoni M. Vanilloid TRPV1 receptor mediates the antihyperalgesic effect of the nonpsychoactive cannabinoid, cannabidiol, in a rat model of acute inflammation. Br J Pharmacol. 2004 Sep;143((2)):247–50. [PMC free article] [PubMed[]
16. Ramer R, Heinemann K, Merkord J, Rohde H, Salamon A, Linnebacher M, et al. COX-2 and PPAR-γ confer cannabidiol-induced apoptosis of human lung cancer cells. Mol Cancer Ther. 2013 Jan 1;12((1)):69–82. [PubMed[]
17. Alhamoruni A, Wright KL, Larvin M, O’Sullivan SE. Cannabinoids mediate opposing effects on inflammation-induced intestinal permeability. Br J Pharmacol. 2012 Apr 1;165((8)):2598–610. [PMC free article] [PubMed[]
18. Couch DG, Cook H, Ortori C, Barrett D, Lund JN, O’Sullivan SE. Palmitoylethanolamide and cannabidiol prevent inflammation-induced hyperpermeability of the human gut in vitro and in vivo-a randomized, placebo-controlled, double-blind controlled trial. Inflamm Bowel Dis. 2019 May 4;25((6)):1006–18. [PubMed[]
19. Jung B, Lee JK, Kim J, Kang EK, Han SY, Lee H, et al. Synthetic strategies for (−)-cannabidiol and its structural analogs. Chem Asian J. 2019 Nov 4;14((21)):3749–62. [PubMed[]
20. Gallily R, Yekhtin Z, Hanuš LO. Overcoming the bell-shaped dose-response of cannabidiol by using cannabis extract enriched in cannabidiol. Pharm Pharmacol. 2015;6((2)):75–85. []
21. Pagano E, Capasso R, Piscitelli F, Romano B, Parisi OA, Finizio S, et al. An orally active cannabis extract with high content in cannabidiol attenuates chemically-induced intestinal inflammation and hypermotility in the mouse. Front Pharmacol. 2016;7:341. [PMC free article] [PubMed[]
22. Scott KA, Dalgleish AG, Liu WM. The combination of cannabidiol and Δ9-tetrahydrocannabinol enhances the anticancer effects of radiation in an orthotopic murine glioma model. Mol Cancer Ther. 2014 Dec 1;13((12)):2955–67. [PubMed[]
23. Ligresti A, Moriello AS, Starowicz K, Matias I, Pisanti S, De Petrocellis L, et al. Antitumor activity of plant cannabinoids with emphasis on the effect of cannabidiol on human breast carcinoma. J Pharmacol Exp Ther. 2006;318((3)):1375–87. [PubMed[]
24. Raup-Konsavage WM, Carkaci-Salli N, Greenland K, Gearhart R, Vrana KE. Cannabidiol (CBD) oil does not display an entourage effect in reducing cancer cell viability in vitro. Med Cannabis Cannabinoids. 2020;3((2)):95–102. [PMC free article] [PubMed[]
25. von Wrede R, Moskau-Hartmann S, Amarell N, Surges R, Erich Elger C, Helmstaedter C. Plant derived versus synthetic cannabidiol: wishes and commitment of epilepsy patients. Seizure. 2020 Aug 1;80:92–5. [PubMed[]
26. Montoya Z, Conroy M, Vanden Heuvel BD, Pauli CS, Park SH. Cannabis contaminants limit pharmacological use of cannabidiol. Front Pharmacol. 2020;11:571832. [PMC free article] [PubMed[]
27. Klotz KA, Grob D, Hirsch M, Metternich B, Schulze-Bonhage A, Jacobs J. Efficacy and tolerance of synthetic cannabidiol for treatment of drug resistant epilepsy. Front Neurol. 2019;10:1313. [PMC free article] [PubMed[]
28. Wheless JW, Dlugos D, Miller I, Oh DA, Parikh N, Phillips S, et al. Pharmacokinetics and tolerability of multiple doses of pharmaceutical-grade synthetic cannabidiol in pediatric patients with treatment-resistant epilepsy. CNS Drugs. 2019 Jun 5;33((6)):593–604. [PMC free article] [PubMed[]
29. Devinsky O, Patel AD, Cross JH, Villanueva V, Wirrell EC, Privitera M, et al. Effect of cannabidiol on drop seizures in the lennox-gastaut syndrome. N Engl J Med. 2018 May 17;378((20)):1888–97. [PubMed[]
30. Thiele EA, Marsh ED, French JA, Mazurkiewicz-Beldzinska M, Benbadis SR, Joshi C, et al. Cannabidiol in patients with seizures associated with lennox-gastaut syndrome (GWPCARE4): a randomised, double-blind, placebo-controlled phase 3 trial. Lancet. 2018 Mar 17;391((10125)):1085–96. [PubMed[]
31. Devinsky O, Patel AD, Thiele EA, Wong MH, Appleton R, Harden CL, et al. Randomized, dose-ranging safety trial of cannabidiol in dravet syndrome. Neurology. 2018 Apr 3;90((14)):e1204–11. [PMC free article] [PubMed[]
32. Szaflarski JP, Bebin EM, Comi AM, Patel AD, Joshi C, Checketts D, et al. Long-term safety and treatment effects of cannabidiol in children and adults with treatment-resistant epilepsies: expanded access program results. Epilepsia. 2018;59((8)):1540–8. [PMC free article] [PubMed[]
33. Hind WH, England TJ, O’Sullivan SE. Cannabidiol protects an in vitro model of the blood-brain barrier from oxygen-glucose deprivation via PPARγ and 5-HT1A receptors. Br J Pharmacol. 2016 Mar;173((5)):815–25. [PMC free article] [PubMed[]
34. Stone NL, England TJ, O’Sullivan SE. A novel transwell blood brain barrier model using primary human cells. Front Cell Neurosci. 2019 Jun 6;13:230. [PMC free article] [PubMed[]
35. Wells CL, van de Westerlo EM, Jechorek RP, Haines HM, Erlandsen SL. Cytochalasin-induced actin disruption of polarized enterocytes can augment internalization of bacteria. Infect Immun. 1998 Jun;66((6)):2410–9. [PMC free article] [PubMed[]
36. Alhamoruni A, Wright KL, Larvin M, O’Sullivan SE. Cannabinoids mediate opposing effects on inflammation-induced intestinal permeability. Br J Pharmacol. 2012 Apr 1;165((8)):2598–610. [PMC free article] [PubMed[]
37. De Petrocellis L, Ligresti A, Schiano Moriello A, Iappelli M, Verde R, Stott CG, et al. Non-THC cannabinoids inhibit prostate carcinoma growth in vitro and in vivo: pro-apoptotic effects and underlying mechanisms. Br J Pharmacol. 2013;168((1)):79–102. [PMC free article] [PubMed[]
38. Ligresti A, Moriello AS, Starowicz K, Matias I, Pisanti S, De Petrocellis L, et al. Antitumor activity of plant cannabinoids with emphasis on the effect of cannabidiol on human breast carcinoma. J Pharmacol Exp Ther. 2006;318((3)):1375–87. [PubMed[]
39. Ramer R, Heinemann K, Merkord J, Rohde H, Salamon A, Linnebacher M, et al. COX-2 and PPAR-γ confer cannabidiol-induced apoptosis of human lung cancer cells. Mol Cancer Ther. 2013 Jan 1;12((1)):69–82. [PubMed[]
40. Massi P, Solinas M, Cinquina V, Parolaro D. Cannabidiol as potential anticancer drug. Br J Clin Pharmacol. 2013 Feb;75((2)):303–12. [PMC free article] [PubMed[]
41. Ryan D, Drysdale AJ, Lafourcade C, Pertwee RG, Platt B. Cannabidiol targets mitochondria to regulate intracellular Ca2+ levels. J Neurosci. 2009 Feb 18;29((7)):2053–63. [PMC free article] [PubMed[]
42. Sun S, Hu F, Wu J, Zhang S. Cannabidiol attenuates OGD/R-induced damage by enhancing mitochondrial bioenergetics and modulating glucose metabolism via pentose-phosphate pathway in hippocampal neurons. Redox Biol. 2017;11:577–85. [PMC free article] [PubMed[]
43. Hampson AJ, Grimaldi M, Axelrod J, Wink D. Cannabidiol and (-)delta9-tetrahydrocannabinol are neuroprotective antioxidants. Proc Natl Acad Sci U S A. 1998 Jul 7;95((14)):8268–73. [PMC free article] [PubMed[]
44. Mishima K, Hayakawa K, Abe K, Ikeda T, Egashira N, Iwasaki K, et al. Cannabidiol prevents cerebral infarction via a serotonergic 5-hydroxytryptamine1A receptor-dependent mechanism. Stroke. 2005;36((5)):1077–82. [PubMed[]
45. Couch DG, Cook H, Ortori C, Barrett D, Lund JN, O’Sullivan SE. Palmitoylethanolamide and cannabidiol prevent inflammation-induced hyperpermeability of the human gut in vitro and in vivo-a randomized, placebo-controlled, double-blind controlled trial. Inflamm Bowel Dis. 2019 May 4;25((6)):1006–18. [PubMed[]
46. Rosenthaler S, Pöhn B, Kolmanz C, Huu CN, Krewenka C, Huber A, et al. Differences in receptor binding affinity of several phytocannabinoids do not explain their effects on neural cell cultures. Neurotoxicol Teratol. 2014 Nov 1;46:49–56. [PubMed[]
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