Natural product topical therapy in mitigating imiquimod-induced psoriasis-like skin inflammation-underscoring the anti-psoriatic potential of Nimbolide

Exploring acemannan-loaded nanogel formulation for the treatment of IMQ-induced psoriasis-like inflammation: In vitro characterization and in vivo efficacy assessment

This study aimed to explore a nanogel formulation containing acemannan as a carrier for the treatment of psoriasis-like skin inflammation. Several acemannan concentrations, such as F1 (2.5 %) and F2 (5 %), were used to prepare the nanogel formulation by homogenization. The formulation was then assessed for in-vitro performance. Four groups of animals were randomly assigned to the animals: Cluster I consisted of normal saline control; Cluster II was assigned Imiquimod (IMQ) control (5 %); Cluster III was assigned IMQ + 2.5 % acemannan (F1); and Cluster IV was assigned IMQ + 5 % acemannan (F2). The effectiveness of the gel in the in vivo study was evaluated in terms of body weight, scaly skin, skin redness, inflammation, patches, moisturizing effect, pro-inflammatory cytokines, nitric oxide, and histopathological examination. The prepared nanogel possessed the desired characteristics in terms of in vitro evaluation parameters. The average particle size was around 199.6 nm, with a polydispersibility index (PDI) of 0.338 and a zeta potential of -65.9 mV. The nanogel formulation significantly (P < 0.05) regulated in vivo performance, including redness, scaly skin, inflammation, patches, moisturizing effect, pro-inflammatory cytokines, and nitric oxide. The histopathological findings suggested that acemannan was effective in rejuvenating the affected skin.

Outline of Therapeutic Potential of Different Plants Reported Against Psoriasis via In Vitro, Pre-Clinical or Clinical Studies

Psoriasis is a noncontagious, autoimmune chronic inflammatory disease with an unknown root cause. It is classified as a multifactorial and chronic skin disorder that also affects the immune system and is genetic. Environmental factors such as stress, infections, and injuries all play an important role in the disease's development. Although there is no cure for this disease, topical, oral, and systemic whole-body treatments are available to relieve symptoms. Several plants and phytochemicals which have been found effective in the management of the psoriasis experimentally (preclinical and clinical). These plants/phytochemicals have applications in topical, oral, and systemic treatments. Traditionally, some of the plants have been utilized as the primary treatment, including their extracts and/or phytochemicals, for individuals with moderate to severe psoriasis (due to fewer side effects), while phototherapy is generally reserved for more advanced cases. This report describes various plants and phytochemicals that have been found to be effective against psoriasis in in vitro, preclinical, and clinical studies. This review summarizes the key findings from experimental studies on various pathological aspects of psoriasis and may be useful, effective, and informative for future research.

Niosomal gel improves dermal delivery of nimbolide: a promising approach for treatment of psoriasis

Aim: Psoriasis is a chronic inflammatory skin disorder characterized by the excessive proliferation of keratinocytes, forming thickened skin plaques due to immune-mediated cytokine responses. Delivering drugs through this barrier to target inflamed tissues remains challenging. Nimbolide (NIM), known for its anti-inflammatory and anticancer properties, shows promise in managing psoriasis. However, its efficacy is limited by its inability to penetrate the thickened horny layer of the skin. To overcome this obstacle, we have developed Nim-loaded niosomal (Nio) formulations (NIM Nio) aimed at improving dermal delivery and achieving localized sustained release at psoriasis-affected sites.Methods: The formulation characteristics were assessed using Zeta sizer, Transmission Electron Microscopy (TEM), and High-performance liquid chromatography (HPLC). The optimized formulation was evaluated for anti-psoriatic potential compared to Nim alone by using molecular techniques such as Confocal Microscopy, Flow cytometry, enzyme-linked immunosorbent assay (ELISA), and Western blotting.Results: NIM Nio showed effective penetration into psoriatic skin, resulting in reductions in keratinocyte hyperproliferation, oxidative stress, splenomegaly, inflammatory cytokines, Psoriasis Area and Severity Index (PASI), and rete ridges compared to NIM alone.Conclusion: Our findings underscore the significant anti-proliferative, antioxidant, and anti-inflammatory properties of NIM Nio in psoriasis, demonstrating its potential as a promising therapeutic option for this challenging condition.

Design and Evaluation of Tretinoin Fatty Acid Vesicles for the Topical Treatment of Psoriasis

The goal of the current study was to explore the potential benefits of Tretinoin (Tre) fatty acid vesicles (Tre-FAV) as a prospective antipsoriatic topical delivery system. This promising system can counteract the drug challenges in terms of its extremely low aqueous solubility, instability, skin irritation, and serious systemic adverse effects. Tre-loaded fatty acid vesicles were successfully developed and entirely characterised. The selected formulation was investigated for in vitro release, ex vivo skin retention and psoriasis efficacy studies. The characterisation results of Tre-FAV showed it has a globular shape with a particle size of 126.37 ± 1.290 nm (0.188 ± 0.019 PDI). The entrapment efficiency and zeta potential were discovered to be 84.26 ± 0.816% and -28.9 ± 1.92 mV, respectively. Encapsulation of the drug in the fatty acid vesicles was also strengthened by differential scanning calorimetric and powder FTIR diffraction studies. In vitro release results showed that Tre-FAV significantly increased skin absorption and retention in comparison to the Tre solution. The topical application of Tre-FAV to a mouse model confirmed that it has superior in vivo antipsoriatic properties in terms of well-demarcated papules, erythema and reduced epidermal thickness in comparison to other treatments. The weight of the spleen and the levels of the cytokines IL-17 and IL-6 decreased after treatment. In conclusion, FAV dramatically increased the water solubility and skin permeability of Tre and its anti-psoriasis activity.

Bibliometric Study of Adaptogens in Dermatology: Pharmacophylogeny, Phytochemistry, and Pharmacological Mechanisms

Background

Adaptogens are a class of medicinal plants that can nonspecifically enhance human resistance. Most of the plant adaptogens have relevant applications in dermatology, but there are still few studies related to their particular action and co-operative mechanisms in topical skin application.

Methods

Plant adaptogens related articles and reviews that published between 1999 and 2022 were obtained from the Web of Science Core Collection database. Various bibliographic elements were collected, including the annual number of publications, countries/regions, and keywords. CiteSpace, a scientometric software, was used to conduct bibliometric analyses. Also, the patsnap global patent database was used to analyze the patent situation of plant adaptogens in the field of cosmetics up to 2021.

Results

We found that the effects of plant adaptogens on skin diseases mainly involve atopic dermatitis, acne, allergic contact dermatitis, psoriasis, eczema, and androgenetic alopecia, etc. And the effects on skin health mainly involve anti-aging and anti-photoaging, anti-bacterial and anti-fungal, anti-inflammatory, whitening, and anti-hair loss, etc. Also, based on the results of patent analysis, it is found that the effects of plant adaptogens on skin mainly focus on aging retardation. The dermatological effects of plant adaptogens are mainly from Fabaceae Lindl., Araliaceae Juss. and Lamiaceae Martinov., and their mainly efficacy phytochemical components are terpenoids, phenolic compounds and flavonoids.

Conclusion

The plant adaptogens can repair the skin barrier and maintain skin homeostasis by regulating the skin HPA-like axis, influencing the oxidative stress pathway to inhibit inflammation, and regulating the extracellular matrix (ECM) components to maintain a dynamic equilibrium, ultimately achieving the treatment of skin diseases and the maintenance of a healthy state.