Cannabinoid Compounds as a Pharmacotherapeutic Option for the Treatment of Non-Cancer Skin Diseases

3.2.9. Influence on Skin Ageing Processes

Early work on the involvement of cannabinoid receptors in skin ageing already showed that CB₁ knockout mice exhibited clear signs of earlier skin ageing with reduced width of the subdermal fat layer compared to wild-type mice [165]. Later work using knockout mice has shown that a lack of CB₁ receptors in the skin is associated with accelerated skin ageing due to increased production of ROS, a decrease in antioxidant defenses and a pro-inflammatory environment [166]. This finding could thus provide the basis for the use of topical cannabinoid applications to reduce skin ageing. In the cited study, collagen levels in the skin of CB₁ knockout mice were decreased, suggesting that the CB₁ receptor may be an endogenous “anti-ageing receptor”. However, it should be noted that these are animal experiments on a diabetes model, the transferability of which to humans would still have to be proven.

A recent study has further demonstrated that the CB₁ receptor on the outer mitochondrial membrane in human epidermal keratinocytes is a negative regulator of mitochondrial activity in the human epidermis, the activation of which could reduce excessive mitochondrial ROS production and thus exert a protective function against skin ageing or photodestruction [167]. In addition, extracts derived from Cannabis sativa have recently been shown to have an antioxidant capacity associated with an increase in superoxide dismutase, free radical scavenging, reduced elastase and collagenase activity, as well as in vivo water binding and a long-lasting moisturising effect [168]. However, this study did not address the role of cannabinoid receptors, and for the moisturising effect, the authors assume that cannabinoids act like an occlusive film on the skin surface and retain water.

4.1.2. Preclinical Findings on the Effect of Cannabinoids in Androgenetic Alopecia

Among the cannabinoid compounds, CBD has been shown to enhance hair growth (for review see [242]). As a possible mechanism of action, a recent investigation reported that CBD restores testosterone-induced loss of β-catenin in human dermal papilla cells, which is downregulated in alopecia by ubiquitination and subsequent proteasomal degradation [243]. However, the latter study did not address the involvement of CBD-triggered receptors. For CBD, which also has a negative allosteric effect on the CB₁ receptor [29] and should therefore actually promote hair growth via this mechanism, a complex mechanism besides the modulation of the cannabinoid receptors has been demonstrated: this cannabinoid inhibits hair shaft development at a concentration of 50 µM via TRPV4 agonism, but enhances it at submicromolar concentrations via activation of the adenosine receptor [232]. Interestingly, in a study investigating the effect of newly synthesised thienyl-substituted pyrazole carboxamide derivatives as CB₁ receptor antagonists against obesity, it was found that a compound (“compound 3”) structurally mimicking rimonabant induced exceptionally strong hair growth in C57BL/6J mice [244], supporting the assumption that CB₁ receptor antagonists increase hair growth accordingly [86].

4.2.2. Preclinical Findings on the Effect of Cannabinoids in Atopic Dermatitis

In the context of hypersensitive skin reactions, a study using a mouse model of Th2-type contact hypersensitivity with pathophysiological features of mouse atopic-like dermatitis found that animals in which the CB₁ receptor was knocked out showed a hypersensitivity reaction as measured by ear swelling, transepidermal water loss, Th2-type skin inflammatory reactions and serum IgE levels, all of which are appropriately characteristic of atopic dermatitis [264]. Furthermore, JTE-907 (Figure 1), a CB₂ receptor inverse agonist, reduced itch-related responses in a murine model of atopic dermatitis to an extent comparable to that of tacrolimus [265]. In another work, the CB₂ receptor agonist S-777469 showed an inhibitory effect on mite antigen-induced atopic dermatitis-like skin lesions in NC/Nga mice [5], with the latter exhibiting reduced eosinophil infiltration after treatment with S-77469. Collectively, these studies show conflicting results regarding the role of the CB₂ receptor in atopic dermatitis, as both the CB₂ receptor antagonist/inverse agonist JTE-907 and the CB₂ agonist S-777469 produced positive effects. Thus, the role of the CB₂ receptor seems to be a complex one here.

As a further mechanism of action one investigation found AEA and THC at submicromolar concentration were able to inhibit CGRP release from isolated rat and mouse skin preparations in a CB₁ receptor-dependent way [266]. In addition, AEA and the newly synthesised CB₁ agonists α-oleoyl oleoylamine ethanolamine (α-OOE; Figure 1) and α-OOS (Figure 1) suppressed mast cell proliferation, inhibited the release of inflammatory mediators and prevented the increase of skin fold thickness in mice with oxazolone-induced atopic dermatitis mice. These findings thus point to a crucial role of the CB₁ receptor in modulating antigen-dependent IgE-mediated mast cell activation [267]. In another study, the symptoms of oxazolone-induced atopic dermatitis were inhibited by α-OOS [128], as evidenced by α-OOS-reduced transepidermal water loss, skinfold thickness and skin surface pH, while skin capacitance was increased. Also worth mentioning in this context is a recent prospective, randomised, double-blind, placebo-controlled study in dogs with atopic dermatitis in which a mixed oil based on CBD and CBD acid was tested [268]. No effect of treatment on IL-6, -8, -31, -34 and MCP-2 serum levels or skin lesions could be detected, although an improvement in itching was observed.

4.3.2. Preclinical Findings on the Effect of Cannabinoids in Allergic Contact Dermatitis

The crucial role of cannabinoid receptors in contact dermatitis was shown in animal models of DNFB-induced ear inflammation in C57BL/6J mice serving as a model of cutaneous allergic contact hypersensitivity, in which a cannabinoid receptor double knockout induced greater sensitivity to inflammatory conditions accompanied by increased expression of MCP-2 [3]. Cannabinoid receptor activation here decreased Toll-like receptor 3 (TLR3) ligand polyinosinic polycytidylic acid (poly-(I:C))-induced MCP-2 expression in the keratinocyte cell line HaCaT. Stimulation with poly-(I:C) serves as an in vitro model for contact dermatitis in this context. In addition, the latter study demonstrated a reduced allergic response after DNFB exposure in FAAH knockout mice. In another investigation, the CB₂ receptor agonist S-777469 was shown to exert an inhibitory effect on DNFB-induced ear inflammation in dermatitis of Balb/c mice [5]. A contribution of TRPV1 to the anti-inflammatory properties of PEA was discovered, as PEA inhibits DNFB-induced ear inflammation in mice via a TRPV1-dependent mechanism [275]. The same group later found that CBD decreases MCP-2, IL-6, IL-8 and TNF-α via CB₂ and TRPV1 in human keratinocytes stimulated with poly-(I:C) [276]. The latter investigation further reported other cannabinoids such as CBC, CBG, THCV and CBGV to inhibit MCP-2, IL-6 and IL-8. Further work found that PEA reduced the number of ear scratches in mice exposed to DNFB, which was abolished by CB₂ and PPARα antagonists [277]. In this context, it should be mentioned that the rationale for the use of PEA in diseases such as allergic contact dermatitis lies not only in its endocannabinoid effect, but also in the fact that it is an essential component of the stratum corneum, which accordingly compensates for deficiencies when applied topically in diseased skin [278]. Finally, in a recent work, newly developed CB₂ receptor agonists were tested for their symptom-reducing properties in atopic contact dermatitis. Here, in agreement with the previously shown data, the CB₂ receptor full agonist “8g” was also demonstrated to reduce poly-(I:C)-induced MCP-2 expression in HaCaT cells [279].

In contrast to the beneficial effects of CB₂ receptor activation described above, another study found that the CB₂ receptor antagonist SR144528 inhibited the expression of pro-inflammatory cytokines, reduced the recruitment of eosinophils and attenuated ear swelling in a mouse model of oxazolone-induced contact dermatitis [171]. Consistent with this, the CB₂ receptor inverse agonist JTE-907 showed anti-inflammatory properties in the carrageenin-induced paw oedema test in mice [280] and inhibited DNFB-induced ear swelling of mice [281,282].

Just as in the case of atopic dermatitis presented above, it is difficult to assess the extent to which activation or inhibition of the CB₂ receptor brings perspective benefits for patients with allergic contact dermatitis. Particularly difficult in this context are findings that show on one occasion that CB₂ knockout mice exhibit greater ear swelling in the DNFB-induced model of allergic contact dermatitis [3] and on another occasion that the CB₂ knockout mice show less ear swelling in an IgE-dependent three-phase cutaneous response in the mouse ear [282]. The authors of the first mentioned study therefore suggested that CB₂ antagonism may be beneficial initially but detrimental with chronic blockade [3].

An important role in skin homeostasis has likewise been evidenced for the cannabinoid target PPARα, which is a major trigger of skin inflammation [283]. In this context, PPARα-deficient mice were reported to exhibit greater epidermal thickening and increased recruitment of inflammatory cells from the skin compared to their wild-type counterparts [182]. Consistent with these results and the above-mentioned functional role of PPARα in the beneficial effect of PEA on atopic contact dermatitis [277], inhibition of endogenous PEA degradation was shown to improve symptoms in the DNFB-induced murine dermatitis model via PPARα [284]. Application of the NAAA inhibitor ARN077, which resulted in a large increase in PEA, caused a reduction in pathological skin thickening, scratching behaviour, a reduction in circulating IL-4, IL-5 and IgE levels, and an increase in IFN-γ. A comparable reduction in skin thickening by ARN077 could no longer be observed in PPARα knockout animals. Finally, the crucial role of NAAA was demonstrated in this study by the fact that DNFB-treated NAAA knockout mice showed significantly less skin thickening and greatly reduced scratching behaviour compared to wild-type littermates.

Finally, topical N-palmitoyl serinol, previously described as a CB₁ agonist [132], was found to improve the epidermal permeability barrier and partially counteract transepidermal water loss and reduced hydration of the stratum corneum in DNFB-treated mice [285]. However, the latter study only speculated on a possible role of cannabinoid receptors in the N-palmitoyl serinol effect presented, without investigating it experimentally.

4.4.2. Preclinical Findings on the Effect of Cannabinoids in Psoriasis

An important factor and reason for the use of cannabinoids in psoriatic skin is their property to inhibit the proliferation of keratinocytes. This antiproliferative effect on keratinocytes was observed for the CB₂ agonist JWH-015 and the compound BML190 [6], which has been described as an inverse agonist at the CB₂ receptor [310,311,312]. A comparable antiproliferative effect was reported for the non-selective cannabinoid receptor agonist HU-210, in whose actions, however, cannabinoid receptors did not play a mediating role [6]. Instead, the authors of the study suspected PPARγ involvement in the described effect. Experiments with cultured normal human epidermal keratinocytes from human skin samples and HaCaT cells revealed that AEA sequentially initiates a signalling mechanism leading to activation of CB₁, TRPV1, calcium influx and finally cell death, thereby regulating epidermal homeostasis, which in turn prevents the initiation or exacerbation of chronic hyperproliferative, pruritic and/or proinflammatory skin diseases [313]. In another study, using CB₂ knockout mice, the CB₂ receptor was shown to play an important protective role in imiquimod-induced psoriasis through immunosuppression, mainly by regulating the proliferation and differentiation of CD4-positive T cells and inhibiting the expression of cytokines and chemokines [178]. Accordingly, in these animal studies, symptom exacerbation was observed in CB₂ knockout mice and in animals treated with the CB₂ antagonist AM-630, while symptom relief was recorded in animals treated with the CB₂ agonist JWH-133. In another report, AEA was noted to reduce the proinflammatory T-cell response via CB₁ receptor-induced upregulation of the mammalian target of rapamycin (mTOR) inhibitor FK506-binding protein (FKBP)12, leading to downstream inhibition of the release of IL-12 and IL-23 from keratinocytes, which results in reduced Th1 and Th17 polarisation intercellularly [314]. These CB₁ receptor-dependent regulations correspond to the regulatory profile required for the treatment of psoriasis.

In a recent report, CBD was found to reduce redox imbalance in UV-irradiated keratinocytes isolated from human skin tissue by decreasing ROS levels, increasing vitamin A and E, and specifically increasing the efficiency of the thioredoxin reductase system. Thioredoxin reductase is an enzyme whose activity is increased in keratinocytes from psoriasis patients. In this context, CBD increased thioredoxin reductase activity in keratinocytes from healthy individuals but decreased it in keratinocytes from psoriasis patients and UVB-irradiated samples [7]. In another recent publication, the lipidomic profile of keratinocytes from healthy individuals and patients with psoriasis was studied with and without UVB light in the presence and absence of CBD [315]. The study found that in the keratinocytes of patients with psoriasis, phosphatidylcholines, phosphatidylinositols, phosphatidylserines and ether-linked phosphoethanolamine are reduced and sphingomyelins are upregulated, while UVB, as used in UVB phototherapy, causes upregulation of phosphatidylcholine species, phosphatidylcholine plasmalogens and ether-linked phosphoethanolamine. The study revealed that CBD induced apoptosis in keratinocytes from psoriatic patients. However, in keratinocytes from patients irradiated with UVB, CBD enhanced the antioxidant properties and prevented the loss of transepidermal water. It is noteworthy that in the above studies, no experiments with receptor antagonists were performed to prove the causal involvement or non-involvement of receptors in the effects triggered by cannabinoids. However, Jarocka-Karpowicz et al. [7] showed that CBD increased AEA levels, upregulated CB₁ receptors in UV-irradiated keratinocytes from healthy and psoriasis patients, increased CB₂ receptors in keratinocytes from healthy and psoriasis patients and decreased CB₂ expression in UV-irradiated keratinocytes from psoriasis patients. TRPV1 was also upregulated by CBD here, but only in keratinocytes that were not exposed to UV light. In addition, a massive accumulation of CBD in the membranes of the keratinocytes was found, which was further enhanced by UVB irradiation. Recently, CBD has also been reported to activate antioxidant metabolic pathways in keratinocytes and to modulate pathways involved in keratinocyte differentiation, skin development and epidermal cell differentiation, with the latter effect occuring via nuclear export and proteasomal degradation of the transcriptional repressor BTB Domain And CNC Homolog (BACH)1 [161]. However, in this study, topical CBD (0.1% or 1%) resulted in hyperproliferation of keratinocytes and wound healing of the skin of mice, indicating a harmful rather than beneficial effect of CBD on psoriasis.

4.5.2. Preclinical Findings on the Effect of Cannabinoids in Acne

Several studies have shown that cannabinoids affect sebocytes, especially their inflammatory properties, and could therefore be a therapeutic option for skin conditions such as acne. In this context, CBD has been reported to exert homeostatic and anti-inflammatory effects on sebocytes [332]. Here, the authors found that CBD inhibited lipogenic effects and sebocyte proliferation in vitro via activation of TRPV4 and mediated anti-inflammatory effects in an adenosine A2a receptor-dependent manner via upregulation of the endoplasmic reticulum stress-associated factor pseudokinase tribbles homolog 3 (TRIB3) and inhibition of NF-κB signalling. In another study, the same group investigated the phytocannabinoids CBC, CBDV, CBG, CBGV and THCV for their effects on human sebocyte functions. All of the above cannabinoids caused a decrease in lipopolysaccharide (LPS)-induced release of the proinflammatory cytokines IL-6 and IL-8 and a decrease in mRNA expression of IL-1α, IL-1β and TNF-α. Among these, CBC, CBDV and THCV inhibited arachidonic acid-induced lipogenesis and THCV also reduced sebocyte proliferation [333]. The anti-inflammatory properties of topically applied phytocannabinoids such as CBC, CBCV, CBD, CBDV, ∆⁸-THCV, Δ⁸-THC and THC were further confirmed in the Croton oil mouse ear dermatitis test, measured as inhibition of the oedematous response [334]. Moreover, preclinical studies revealed a possible anti-acne effect of hemp seed hexane extracts due to their anti-microbial, anti-lipogenic and collagen-promoting properties [335]. Finally, some studies have focused on the effect of cannabinoids against bacterial-induced inflammation. In this context, CBD was found to inhibit inflammation induced by extracellular vesicles of Cutibacterium acnes [336]. In line with this notion, CBD and CBG were found to inhibit the release of IL-8 and IL-1 from normal human epidermal keratinocytes exposed to Cutibacterium acnes [154]. Moreover, CBD was recently reported to have selective activity against a subset of Gram-negative bacteria [337]. Collectively, the antimicrobial effect of various cannabinoids may play a role in the effect on acne, which would need to be further investigated in future studies.

4.6.2. Preclinical Findings on Effects of Cannabinoids in Skin Fibrosis/Systemic Sclerosis

In the following chapter, bleomycin-induced fibrosis is listed at various points as a model system for systemic sclerosis, which in this context is a suitable model for the transfer of knowledge from animals to humans, although in its original form it is also an extended model for pulmonary fibrosis [346].

In an attempt to evaluate the effects of cannabinoids on fibrosis in an in vivo model, a corresponding effect was investigated in a mouse model of diffuse systemic sclerosis by injections of hypochlorite, which induced characteristic skin and lung fibrosis [347]. Here, the application of the non-selective cannabinoid agonist WIN 55,212-2 or the selective CB₂ agonist JWH-133 reduced skin and lung fibrosis as well as fibroblast proliferation and the development of autoantibodies such as anti-DNA topoisomerase 1. The antifibrotic effect of WIN 55,212-2 was confirmed in the mouse model of bleomycin-induced systemic sclerosis [348]. Consistent with these findings, CB₂ knockout mice exhibited increased skin thickness and collagen content in the skin and lungs, as well as increased proliferation of fibroblasts, suggesting that the CB₂ receptor mediates an endogenous antifibrotic effect in the skin and lungs [347]. In line with this, another study reported that CB₂ knockout mice are more sensitive to bleomycin-induced skin fibrosis [349].

In a further investigation, the novel CBD aminoquinone VCE-004.8, a dual PPARγ and CB₂ receptor agonist, was shown to confer antifibrotic properties, such as reduction of differentiation of mouse embryonic fibroblasts into myofibroblasts. This was demonstrated by a reduction in α-smooth muscle actin (α-SMA) and inhibition of skin thickness, collagen accumulation around blood vessels, dermal mast cell degranulation and macrophage infiltration in the mouse model of bleomycin-induced fibrosis [12,13]. Using the same experimental model, EHP-101, a lipid formulation of VCE-004.8, was shown to inhibit skin and lung fibrosis and downregulate the expression of several fibrosis and inflammatory markers [14]. In a subsequent study, again based on the same experimental system, the authors revealed relief of skin fibrosis, reduction in skin thickness, recovery of lipoatrophy, reduction in Ashcroft score and dermal collagen content, and prevention of collagen accumulation around vessels with daily oral administration of EHP-101 (20 mg/kg body weight) or lenabasum (5 mg/kg body weight) [15]. In general, EHP-101 and lenabasum decreased the expression of genes involved in the inflammatory and fibrotic markers of systemic sclerosis, but EHP-101 was additionally able to upregulate factors related to angiogenesis and vasculogenesis. The property of EHP-101 to inhibit fibrosis in various tissues of mice was later also confirmed in a model of angiotensin II-induced fibrosis [350]. In the bleomycin-induced skin fibrosis model, celastrol, a natural compound isolated from the traditional Chinese medicinal plant Tripterygium wilfordii Hook F with the properties of a CB₂ receptor agonist, and WIN 55,212-2 were found to be effective against skin fibrosis [351]. Celastrol and WIN 55,212-2 reduced skin thickness and α-SMA, a biomarker for myofibroblasts that accumulates in the skin during systemic sclerosis, and decreased mRNA levels of several inflammatory and fibrosis markers such as TNF-α, collagen 1α and TGF-β. In general, celastrol was superior to WIN 55,212-2 in all inhibitions of systemic sclerosis markers. In addition, WIN 55,212-2 was reported to reduce the deposition of extracellular matrix in fibroblasts from patients with diffuse systemic sclerosis and to counteract their transdifferentiation into myofibroblasts and resistance to apoptosis as typical cellular abnormalties in systemic sclerosis [352]. These effects were not inhibited by cannabinoid receptor antagonists.

In one study, lenabasum was found to prevent skin fibrosis in a mouse model in which constitutively active TβRI was overexpressed [219]. Interestingly, the latter study was able to provide data showing that lenabasum reduces the amount of pro-collagen type I propeptide in the cell culture medium of fibroblasts from patients with diffuse cutaneous systemic sclerosis as a marker of collagen synthesis in a PPARγ-dependent manner. Notably, data from animal studies have shown that deletion of PPARγ leads to increased susceptibility to bleomycin-induced skin fibrosis, suggesting that PPARγ suppresses fibrogenesis [353].

The role of the CB₁ receptor in fibrotic diseases appears to be more in mediating a profibrotic effect. Accordingly, CB₁ receptor activation has been linked with the development of pulmonary fibrosis [354,355,356]. Consistent with these findings, silencing of FAAH was associated with increased skin fibrosis in a mouse model of bleomycin-induced fibrosis [357]. In this study, the CB₁ antagonist AM-281 reversed the profibrotic effects of FAAH inhibition, while the CB₂ antagonist AM-630 enhanced fibrosis, indicating an opposite unfavourable effect of the CB₁ receptor and a favourable effect of the CB₂ receptor. In another study, also using the bleomycin-induced fibrosis model, similar results were obtained with CB₁ receptor knockout mice that did not develop fibrosis, whereas activation of CB₁ with ACEA increased leukocyte infiltration and enhanced the fibrotic response to bleomycin [358]. In a recent report, the peripherally restricted CB₁/inducible nitric oxide synthase (iNOS) hybrid inhibitor zevaquenabant (MRI-1867) was found to reduce bleomycin-induced fibrosis in mice deficient in the multi-drug resistance gene 1 (MDR1), which encodes the drug efflux transporter p-glycoprotein (P-gp), but not in mice with intact MDR1 expression [169]. Consistent with the beneficial role of the CB₂ receptor, another recent investigation reported that a dermal formulation of the CB₂ receptor agonist GP1a reduced fibrosis in a mouse model of excitional wound healing [109].

4.7.2. Preclinical Findings on Effects of Cannabinoids in Dermatomyositis

Reference has already been made to the orphan drug designation of lenabasum in the treatment of dermatomyositis [9]. The substance, which acts as a CB₂ receptor agonist, suppressed the production of TNF-α, IFN-α and IFN-β in PBMCs of dermatomyositis patients [363]. In the context of dermatomyositis, lenabasum was also able to inhibit the expression of IL-31 in skin lesions, a cytokine upregulated in dermatomyositis patients suffering from pruritus, and to downregulate the release of IL-31 into the supernatants of PBMCs obtained from dermatomyositis patients and activated by the Toll-like receptor (TLR) 9 agonist CpG oligodeoxynucleotide [364]. In a recent publication, extensive profiling of dermatomyositis skin was performed and lenabasum was found to downregulate CD4-positive T cells, IFN-β, IFN-γ, IL-31 and pathophysiological CB₂ receptor expression, while a similar effect was not observed in healthy skin [8].

4.8.2. Case Reports on Cannabinoid Effects on Epidermolysis Bullosa

In relation to epidermolysis bullosa, where cannabinoids have been applied topically, case reports and retrospective observations showed promising effects. For example, in one observational study, topical CBD oil was found to reduce the symptoms of epidermolysis bullosa in three cases (a 6-month-old boy, a 3-year-old girl and a 10-year-old boy), which was associated with less concomitant analgesic medication, fewer blisters and a shorter healing time for active blisters [22]. A recent case report further found that a CBD oil formulation improved pain scores in a 21-year-old woman suffering from recessive dystrophic epidermolysis bullosa [371]. Here, CBD was administered at a dose of 124 mg (3.1 mg/kg body weight) twice daily. According to another case report, a sublingually administered THC/CBD combination in three patients with epidermolysis bullosa (a 64-year-old woman, a 41-year-old man and a 36-year-old man) also led to an improvement in pain scores, a reduction in itching and a reduction in the pain medication taken [19]. In this study, patient 1 received sublingual doses of a cannabinoid-based oil that were stepwise increased to 2.5 mg CBD and 1.625 mg THC, four times daily. Patient 2 reached the maximum dose of 3 mg CBD and 1.95 mg THC four times daily. Patient 3 ingested dried flowers of the female cannabis plant by inhalation and only later ingested an unspecified amount of the cannabinoid oil.

The results of a recently published international anonymous cross-sectional study on the use of medical cannabinoids showed an improvement in pain with a simultaneous reduction in pain medication, as well as a reduction of pruritus and an improvement of wound healing effects in patients with epidermolysis bullosa who used cannabinoid-based medications [20]. In this study, 71 surveys of patients taking cannabinoid-based medicines were evaluated. Both THC- and CBD-containing products were used, as well as those containing only CBD or only THC. However, a recently registered phase II/III study on the efficacy and safety of a CBD cream in epidermolysis bullosa patients was withdrawn [372]. Some hope rests on the use of CBD in this context. As noted in a commentary related to the use of cannabinoids in epidermolysis bullosa, it would be time “to start planning robust studies in patients with epidermolysis bullosa”, as the effects of pain are generally under-recognised in people suffering from epidermolysis bullosa [373].

4.9.2. Case Report on Cannabinoid Effects on Pyoderma Gangrenosum

A prospective case series of pyoderma gangrenosum [21] reported improvements, particularly in pain management, observed in three patients (a 50-year-old woman, a 76-year-old man and a 60-year-old woman) treated with cannabinoids. In one case, the topical oil ARGYLE™ (THC 5 mg/mL + CBD 6 mg/mL; 1.0 mL applied daily to the wound bed) and in the other two cases, the oil Bedrolite™ (THC 7 mg/mL + CBD 9 mg/mL; 0.5 to 1.0 mL applied twice daily to the wound bed plus once to three times daily for breakthrough pain) was used. Here, the case report showed an analgesic effect of topical medicinal cannabis associated with reduced opioid consumption, suggesting that cannabinoid therapies may also be beneficial and useful as topical applications for patients with pain-related skin conditions.