Reconstructed Epidermis Model Research Articles

Noninvasive evaluation of the skin barrier in reconstructed human epidermis using speckle analysis: Correlation with Raman microspectroscopy.

Reconstructed epidermis models, obtained from 3D keratinocytes culture, have gained significant prominence as prototypes for safety and efficacy testing in skin research. To effectively evaluate these models, it is essential to perform molecular and functional characterization. The skin's barrier function is one of the essential aspects of the epidermis that needs to be assessed. A noninvasive method is thus required for the evaluation of the skin barrier in these models. With this perspective, the aim of this feasibility study is to apply the speckle technique for the assessment of the skin barrier in the Reconstructed Human Epidermis (RHE). Speckle analysis as well as Raman microspectroscopy were performed on RHE samples at two maturation days, D17 and D20. Between D17 and D20, our study showed an increase in various Raman parameters, including stratum corneum percentage, lateral lipid packing, lipid-to-protein ratio, and protein secondary structure. Furthermore, the degree of light polarization and the speckle grain size also increased over this period. The speckle technique proved to be effective for evaluating the skin barrier in Reconstructed Human Epidermis (RHE) models. Comparison with Raman validates this approach and provides comprehensive molecular and functional characterization of reconstructive skin models.

Protective effect of soy germ-fermented postbiotics derived from Lacticaseibacillus paracasei DCF0429 (SGPB-DCF0429) in human reconstituted skin

Postbiotics are non-viable microorganisms and their components that provide health benefits to their hosts. At this time, the potential effects of food-based postbiotics have not been reported. This study was designed to isolate lactic acid bacteria (LAB) from traditional Korean fermented foods and to evaluate the beneficial properties of soy germ-fermented postbiotics produced using LAB in a reconstructed epidermis model. Among the LABs isolated from traditional Korean fermented foods, Lacticaseibacillus paracasei DCF0429 showed the highest antioxidant and β-glucosidase activities without any harmful enzyme activities. Additionally, L. paracasei DCF0429 increased the isoflavone aglycone content and antioxidant activity of soy germ during postbiotic production. Finally, the soy germ-fermented postbiotic DCF0429 (SGPB-DCF0429) was investigated for its skin barrier properties. SGPB-DCF0429 protected epidermis tissue against oxidative stress by increasing the cell viability and regulating pro-inflammatory cytokines. These results suggest that SGPB-DCF0429 could serve as a promising protective effect in oxidative stress-induced epidermis tissue.

A modified protocol for studying filaggrin degradation using a reconstructed human epidermis model under low and high humidity.

Filaggrin (FLG) is an essential protein that plays a vital role in maintaining skin barrier function and moisture levels, allowing the skin to adapt to dry environments. However, the precise temporal dynamics of FLG metabolism in the human epidermis remain poorly understood, and suitable tools to study these time-dependent effects are currently lacking. To investigate the molecular mechanisms and time course of FLG metabolism and skin barrier function under high- and low-humidity conditions, utilizing a reconstructed epidermis model. EpiSkin specimens cultured under humid or dry conditions for varying durations (2-48 h) were compared by assessing FLG degradation and skin barrier formation using immunofluorescence staining and western blotting. Under conditions of low humidity, the proteolysis of FLG in EpiSkin increased between 4 and 12 h and was accompanied by elevated levels of cysteine-aspartic protease (caspase)-14. The expression of peptidyl arginine deiminase 1 and calpain 1 also increased at 4 h. However, after 24 h, the expression of these three FLG-degrading proteins significantly decreased. Conversely, the levels of pyrrolidone-5-carboxylic acid and urocanic acid initially decreased at 2 h and then increased between 12 and 24 h. Additionally, the expression of skin barrier proteins, such as FLG, transglutaminase 5, loricrin and zonula occludens-1, decreased starting from 12 h. Notably, epidermal cell viability and activity were also inhibited. We propose a reliable and ethical model to study the temporal dynamics of FLG metabolism and its role in skin barrier function. Using a commercially reconstructed epidermis to mimic dry skin formation obviates the need for animal and human testing.

Chronological aging impacts abundance, function and microRNA content of extracellular vesicles produced by human epidermal keratinocytes.

The disturbance of intercellular communication is one of the hallmarks of aging. The goal of this study is to clarify the impact of chronological aging on extracellular vesicles (EVs), a key mode of communication in mammalian tissues. We focused on epidermal keratinocytes, the main cells of the outer protective layer of the skin which is strongly impaired in the skin of elderly. EVs were purified from conditioned medium of primary keratinocytes isolated from infant or aged adult skin. A significant increase of the relative number of EVs released from aged keratinocytes was observed whereas their size distribution was not modified. By small RNA sequencing, we described a specific microRNA (miRNA) signature of aged EVs with an increase abundance of miR-30a, a key regulator of barrier function in human epidermis. EVs from aged keratinocytes were found to be able to reduce the proliferation of young keratinocytes, to impact their organogenesis properties in a reconstructed epidermis model and to slow down the early steps of skin wound healing in mice, three features observed in aged epidermis. This work reveals that intercellular communication mediated by EVs is modulated during aging process in keratinocytes and might be involved in the functional defects observed in aged skin.

Apparent limitations of OECD TG 431 for classification of acrylic- and methacrylic-based adhesives

For years, the strive for in vitro methods for toxicological assessment suitable to replace animal studies gained progressive importance. OECD Test Guideline (TG) 431 was implemented in 2004, allowing to circumvent animal testing according to OECD TG 404 while reliably predicting skin corrosion potential of many substances and products. However, non-animal assays often show protocol-dependent limitations, that complicate or even prevent the testing of several groups of substances. In this study, the suitability of the OECD TG 431 for assessment of the skin corrosion potential of known acidic, thus often skin corrosive or irritating acrylic and methacrylic acid-based adhesives and monomers, was investigated. The commercially available Phenion® Open Source Reconstructed Epidermis (OS-REp) model, developed at Henkel & Co. KGaA, was used. The EpiDerm™ prediction model was considered most applicable to the Phenion® OS-REp model. All Proficiency Substances listed in OECD TG 431, amongst them six acids, were correctly classified and subcategorized as Skin Corr. 1 A or 1B/C corrosives. The OS-REp model was shown to be suitable for the assessment of skin corrosion potential in accordance with OECD TG 431. However, our results also indicate that acrylic and methacrylic monomer-based adhesives might fall outside the applicability domain of this guideline.

The impact of airborne ultrafine particulate matter on human keratinocyte stem cells.

Air pollution is today fully acknowledged to be a significant public health problem. Rapid urbanization exposed us to a variety of unhealthy ambient air pollutants at high concentrations. The emergence of airborne ultrafine particles has added an additional dimension to this already complex problem of air pollution. The skin has different functions, one of them being the protection against the deleterious effect of external agents. The aim of this study is to evaluate the impact of airborne ultrafine particles (UFP) pollution on skin aging and on keratinocyte differentiation. Ex vivo human skin biopsies and cultured keratinocytes stem cells (KSC) were submitted to diesel exhaust-derived UFP. Reactive oxygen species (ROS) production was assessed with the MitoSOX™ probe. Keratinocyte stemness potential was evaluated by the immunodetection of keratin 15 (K15) and p63 (∆N isoforms). Effect of UFP on the epithelial niche maintenance was evaluated by immunodetection of Sox9. Reconstructed epidermis model was used to assess the impact of UFP on keratinocyte differentiation and aging. UFP exposure induced ROS production and disturbed K15, ∆Np63 and Sox9 expression in KSC or ex vivo skin. Finally, investigations on reconstructed epidermis revealed a phenotype marked by impaired keratinocyte differentiation. These results indicate that UFP pollution is a potent extrinsic factor of skin aging, affecting the keratinocyte stem cell potential and the skin renewal process.

Investigating the surfactant antagonism with the Open Source Reconstructed Epidermis (OS-Rep) model

Under the current EU chemicals legislation, in vitro test methods became the preferred methods to identify and classify the skin irritation potential of chemicals and mixtures. Among these, especially in vitro skin models are widely used. For surfactants, a well-known group of typically irritating chemicals, it is a long-standing experience that the irritation potential of a mixture of surfactants is typically lower than the irritation potential of the single surfactants, an effect usually described as surfactant antagonism. In order to evaluate if this effect can be observed in skin model systems as well, the irritation potential of the surfactants and of their mixtures was determined in the Open Source Reconstructed Epidermis (OS-REp) models. Combinations of sodium dodecyl sulfate or linear alkylbenzene sulfonate with cocoamidopropyl betain and alkyl polyglycosid, respectively, resulted in a clear decrease of the irritation potential compared to the irritation exerted by the single surfactants. The effect appeared to be primarily driven by the mixture's lower ability to damage the skin model's barrier, as shown by a reduced fluorescein permeation.

234 EV.E.I.L.S research program on infant skin from birth : Contribution to characterize different skin types

We conducted a research program focused on infant skin types (normal, dry, sensitive, atopic), using similar in vitro models and non-invasive clinical assessments. All infants had clinical examination, skin barrier function and hydration assessment. Other markers were selected depending on skin types. In vitro models were mostly based on patented age-dependent reconstructed epidermis, customized for each skin problem, plus an innervated reconstructed epidermis model. Skin surface is immature until 2 years (Confocal microscopy) and hydration dysbalanced (Raman spectroscopy) with high NMF content at birth and a rapid decrease till 6 months.

The moisturizing effect of Capparis spinosa fruit extract targeting filaggrin synthesis and degradation.

Small molecular natural products, such as betaine, have unique moisturizing advantages. Capparis spinosa L. fruit is rich in quaternary ammonium alkaloids such as betaine and stachydrine. However, few studies investigated its efficacy and mechanism on human skin. Polysaccharides-free C. spinosa fruit extract (CS) was obtained to study its moisturizing effect and mechanisms focusing on filaggrin (FLG) synthesis and degradation. The clinical moisturizing test was carried out on human arms, calves, and faces after CS treatment for 0.5-6h. The change in the level of FLG, caspase 14, loricrin, and transglutaminase 5 (TGM 5) was measured by immunofluorescence after CS treatment for 4 and 24 h in a reconstructed epidermis model. Also, the content of pyrrolidone carboxylic acid (PCA) in the stratum corneum was tested by high-performance liquid chromatography (HPLC) both in the epidermis model and human calves. Compared with glycerin (positive control), 5% CS showed a strong skin hydration effect on arms and calves when applied for 0.5-6h. Also, the face hydration increased at 0.5 and 4 h. In addition, 3% CS applied to the recombinant epidermis model under low humidity promoted the immunodetected levels of caspase 14 and PCA content but reduced the levels of FLG at 4h, however, the levels of FLG, loricrin, and TGM 5 were promoted at 24 h. Meanwhile, CS treatment for 4h in human calves increased the PCA content in the stratum corneum by 29.9%. Topical application of CS on human skin showed an instant and long-lasting increase in skin hydration by regulating the FLG network. It promoted FLG degradation to form PCA at 4h both in vivo and in vitro, increasing FLG synthesis after 24 h, potentially reforming the FLG monomer reservoir to alleviate the skin's dry condition.

3D CULTURE OF HaCaT KERATINOCYTE CELL LINE AS AN in vitro TOXICITY MODEL

Ex vivo dermal toxicology analyses are crucial for replacement of in vivo test methods and have been of interest in recent years for testing cosmetics, drugs, and chemicals. Development of an appropriate reconstructed epidermis model might overcome the limitations of monolayer culture systems. In the current study, we used the immortalized human keratinocyte cell line (HaCaT) to develop an ex vivo 3D cell culture system for keratinocyte-based toxicity analysis. Mouse embryonic fibroblast-conditioned medium and Matrigel matrix-based 3D HaCaT cell culture systems expressed skin-related genes and proteins in culture. The 3D HaCaT cultures demonstrated a skin-like phenotype and response against selected test compounds. Reliable results were obtained compared to monolayer HaCaT cells which were exposed to selected chemicals for 1 h and 24 h. Gene expression profiles of 3D HaCaT cell cultures and monolayer cultures were completely different after administration of the test compounds.Overall, our results showed that a 3D HaCaT cell culture system generated in Matrigel matrix exerted a skin epidermis-like phenotype. Consequently, 3D HaCaT cell cultures may be an acceptable test method for conducting in vitro toxicology experiments.

Intelligent Paper-Free Sprayable Skin Mask Based on an In Situ Formed Janus Hydrogel of an Environmentally Friendly Polymer.

Traditional skin care masks usually use a piece of paper to hold the aqueous essences, which are not environmentally friendly and not easy to use. While a paper-free mask is desired, it is faced with a dilemma of moisture holding and rapid release of encapsulated bioactive substances. Herein, a paper-free sprayable skin mask is designed from an intelligent material-a thermogel which undergoes sol-gel-suspension transitions upon heating-to solve this dilemma. A synthesized block copolymer of poly(ethylene glycol) and poly(lactide-co-glycolide) with appropriate ratios can be dissolved in water, and thus easily mixed with a biological substance. The mixture is sprayable. After spraying, a Janus film is formed in situ with a physical gel on the outside and a suspension on the inside facing skin. Thus, both moisture holding and rapid release are achieved. Such a thermogel composed of biodegradable amphiphilic block copolymers loaded with nicotinamide as a skin mask is verified to reduce pigmentation on a 3D pigmented reconstructed epidermis model and further in a clinical study. This work might be stimulating for investigations and applications of biodegradable and intelligent soft matter in the fields of drug delivery and regenerative medicine.

144 Barrier disruption and inflammatory skin models to evaluate cosmetic formulations on lipid metabolism

Primary function of the skin is to protect the body from environment and excessive water loss. Skin is characterized by active lipid metabolism and lipids play crucial roles both in terms of structural integrity and functionality. Lipid metabolism can be modified by skin barrier alteration and inflammation leading to modification of ceramides and free fatty acids ratio inducing barrier dysfunction. Aim of this study was to investigate, on 3-dimentional skin model, barrier alteration effect and inflammation on lipid metabolism (enzymes expression and lipid levels) and to evaluate different formulations in order to balance negative impact of the stress. Ex vivo human skin model exposed to SDS and reconstructed epidermis model with TNFα stress were used. Enzyme expression (ALOX12B and EVOL1) was performed by immunofluorescence staining with confocal microscopy. Ceramides, free fatty acids and cholesterol synthesis were analysed using chromatographic method. Mass spectrometry imaging (MSI) allowed to follow skin penetration of lipophilic ingredients of formulations. SDS barrier alteration decreased significantly ALOX12B expression and increased EVOL1 expression. Epidermal lipids synthesis was also modified after inflammatory stress, in particular, ceramides ratio leading to impairment of the barrier function. Same trends were described in vivo for pathologies like ichthyosis, atopic dermatitis and psoriasis. The different lipidic constituents of formulations penetrated and were localized into the SC and viable epidermis by MSI. Rhealba® oat plantlets extract formulation permitted to restore lipid metabolic disorders and balance ceramides ratio. Skin models demonstrated the impact of barrier alteration and inflammation on lipid metabolism. These skin models can be used to evaluate cosmetic formulations on lipid metabolism to preserve barrier function with can be specifically altered in different inflammatory pathologies.

In vitro skin irritation assessment becomes a reality in China using a reconstructed human epidermis test method

The in vitro EpiSkin™ test method was validated in 2007 by the European Union Reference Laboratory for alternatives to animal testing (EURL ECVAM) as a full replacement method for the Draize acute skin irritation test and adopted in the OECD Test Guideline 439 in 2009. Based on the EpiSkin™ technology, the production of a reconstructed epidermis model has been established and standardized in China. The evaluation of the in vitro skin irritation test method using this EpiSkin™ model produced in China was performed on a set of 45 chemicals. Good predictive capacity was obtained with 94% (n=17) for sensitivity, 75% (n=28) for specificity and 82% for accuracy. The accuracy of the included 20 OECD reference chemicals also met the OECD acceptance criteria, indicating that this testing method based on the EpiSkin™ model produced in China can be used as a stand-alone test method to predict skin irritation. The availability and validity of in vitro epidermis model and testing method are of great significance for extending the applications of non-animal alternative testing methods in China.

Preliminary data on the successful micronucleus testing with the EPISKIN® reconstructed epidermis model

Preliminary data on the successful micronucleus testing with the EPISKIN® reconstructed epidermis model

Preliminary performance data of the RHE/IL-18 assay performed on SkinEthic™ RHE for the identification of contact sensitizers.

The purpose of this study was to evaluate the performances of the RHE/IL-18 assay using the SkinEthic™ RHE model for the identification of contact sensitizers. A set of 18 substances and mixtures was tested on this epidermal model, following the RHE/IL-18 protocol. The final results of the assay were obtained following 5 interpretation schemes, to determine the optimal prediction model for this assay with this specific test system. The data were analysed with a special focus on the basal level of IL-18 release and on the performance obtained with respect to three different gold standards: LLNA, HRIPT and an integrated reference, constructed from all available results. No important differences were found in the performance levels depending on the three gold standards. The performances obtained with the SkinEthic™ RHE model support that this model may be considered as an alternative to different reconstructed epidermis models (EpiDERM™ , EpiCS™ and VUMC-EE) for the performance of RHE/IL-18 assays. The prediction model to be used was refined, and more substances have to be tested in order to gather enough data for this evaluation and to determine the right criteria applicable for this assay using the SkinEthic™ RHE test system.

Hesperidin Suppresses Melanosome Transport by Blocking the Interaction of Rab27A-Melanophilin

We investigated the inhibitory effects of hesperidin on melanogenesis. To find melanosome transport inhibitor from natural products, we collected the structural information of natural products from Korea Food and Drug Administration (KFDA) and performed pharmacophore-based in silico screening for Rab27A and melanophilin (MLPH). Hesperidin did not inhibit melanin production in B16F10 murine melanoma cells stimulated with α-melanocyte stimulating hormone (α-MSH), and also did not affect the catalytic activity of tyrosinase. But, hesperidin inhibited melanosome transport in melanocyte and showed skin lightening effect in pigmented reconstructed epidermis model. Therefore, we suggest that hesperidin is a useful inhibitor of melanosome transport and it might be applied to whitening agent.

Successful micronucleus testing with the EPI/001 3D reconstructed epidermis model: Preliminary findings

Currently, the cosmetics industry relies on the results of in vitro genotoxicity tests to assess the safety of chemicals. Although the cytokinesis-block micronucleus (CBMN) test for the detection of cells that have divided once is routinely used and currently accepted by regulatory agencies, it has some limitations. Reconstituted human epidermis (RHE) is widely used in safety assessments because its physiological properties resemble those of the skin, and because it allows testing of substances such as hydrophobic compounds. Thus, the micronucleus test is being adapted for application in RHE-reconstructed tissues.Here we investigated whether two different reconstructed epidermis models (EPI/001 from Straticell, and RHE/S/17 from Skinethic) are suitable for application of the micronucleus test. We found that acetone does not modify micronucleus frequency, cell viability, and model structure, compared with non-treated RHE. Treatment of the EPI/001 model with mitomycin C and vinblastine resulted in a dose-dependent increase of micronucleus frequency as well as a decrease of tissue viability and of binucleated cell rate, while no changes of the epidermal structure were observed. The number of binucleated cells obtained with the RHE/S/17 model was too small to permit micronucleus testing. These results indicate that the proliferative rate of the tissue used is a critical parameter in performing the micronucleus test on a 3D model.

Lysyl Oxidase silencing impairs keratinocyte differentiation in a reconstructed‐epidermis model

Lysyl Oxidase (LOX) is an extracellular enzyme involved in the maturation of connective tissues. It also acts in many cell types as a regulator of cell behaviour and phenotype through intracellular signalling pathways. Recently, LOX was shown to be present in human epidermis where its precise functions remain unclear. We showed here that in confluent monolayer cultures of normal human keratinocytes (KCs) and N/TERT-1-immortalized KCs, LOX expression was induced during the first differentiation steps. Moreover, the silencing of LOX by stable RNA interference disrupted the expression of early differentiation markers. In a reconstructed-epidermis model, LOX silencing did not impair the stratification process nor the formation of the first differentiated layers. However, terminal differentiation was strongly impaired, as shown by a decreased expression of late differentiation proteins and by the absence of stratum corneum. Nonetheless, inhibition of LOX enzymatic activity by β-aminopropionitrile did not affect the differentiation process. Therefore, LOX protein acts during the first steps of KC differentiation and is important for subsequent commitment into terminal differentiation. Taken together, these results suggest that a finely regulated expression of LOX is necessary for normal KC differentiation and thus for maintenance of epidermal homeostasis.

Dermal penetration and metabolism of p-aminophenol and p-phenylenediamine: Application of the EpiDerm™ human reconstructed epidermis model

To address the provision of the 7th Amendment to the EU Cosmetics Directive banning the use of in vivo genotoxicity assays for testing cosmetic ingredients in 2009, the 3D EpiDerm reconstructed human skin micronucleus assay has been developed. To further characterise the EpiDerm tissue for potential use in genotoxicity testing, we have evaluated the dermal penetration and metabolism of two hair dye ingredients, p-aminophenol (PAP) and p-phenylenediamine (PPD) in this reconstructed epidermis model. When EpiDerm tissue was topically exposed to PAP or PPD for 30 min (typical for a hair dye exposure), the majority (80->90%) of PAP or PPD was excluded from skin tissue and removed by rinsing. After a 23.5h recovery period, the PAP fraction that did penetrate was completely N-acetylated to acetaminophen (APAP). Similarly, 30 min topical application of PPD resulted in the formation of the N-mono- and N,N'-diacetylated metabolites of PPD. These results are consistent with published data on the dermal metabolism of these compounds from other in vitro systems as well as from in vivo studies. When tissue was exposed topically (PAP) or via the culture media (PPD) for 24h, there was good batch-to-batch and donor-to-donor reproducibility in the penetration and metabolism of PAP and PPD. Overall, the results demonstrate that these two aromatic amines are biotransformed in 3D EpiDerm tissue via N-acetylation. Characterising the metabolic capability of EpiDerm tissue is important for the evaluation of this model for use in genotoxicity testing.

Potential method to determine irritant potency in vitro – Comparison of two reconstructed epidermal culture models with different barrier competency

Testing chemicals for their ability to cause skin irritation is required for all ingredients of products that come into contact with the skin. Here, we describe a potential method for determining the irritant potency of a chemical in vitro and apply the method to two different reconstructed epidermis models which exhibit different barrier properties. Two surfactants: sodium dodecyl sulphate, Triton X100 and two non-surfactants: 2-4-di-nitro-chloro-benzene, cinnamaldehyde were applied topically in a dose response for 24h. Biomarkers IL-1alpha, IL-1RA, IL-8 and MTT were assessed and EC(50) values determined. Variation in barrier properties between the epidermal models led to variation in the extent of penetration of surfactants, but not of non-surfactants which in turn influenced the EC(50) value obtained from surfactants. Furthermore, EC(50) values showed that no single biomarker could be classed as the most sensitive biomarker since biomarker sensitivity differed between the different chemicals studied. However, the ranking of the chemicals in order of strong to weak irritant was the same irrespective of the model used and also independent of the biomarker used (Triton X100>DNCB>SDS>CA). This study describes a method which not only distinguishes an irritant from a non-irritant but which may possibly also be used to determine irritant potency.