Introduction
Aesthetic dermatology has been on the rise for years. Micro-needling is a relatively new procedure. First described in 1995, it became more popular after the 2006 introduction of the product that later became the Dermaroller®.1–3
Micro-needling is safe and cost efficient. It is used to treat different dermatologic conditions, such as scars, alopecia and hyperhidrosis.1,2,4,5 In cosmetic dermatology micro-needling is used for skin rejuvenation.6 The 0.5–1.5 mm long needles penetrate the skin and the resulting lesions, although superficial, initiate the wound healing cascade.7 Activation of various growth factors leads to increased collagen synthesis.6 Gene expression and histopathological changes caused by micro-needling have been studied in animals, 3D skin models and humans.6–11 Upregulation of genes associated with wound healing, epithelial proliferation/differentiation, immune cell recruitment and tissue remodeling genes has been described.6 Micro-needling has relatively few side effects compared to other cosmetic procedures such as ablative laser treatment or dermabrasion.12 The importance of adequate post-procedural aftercare in cosmetic dermatology to prevent adverse events and optimize outcome is well documented.13–15 However, it is not known to date whether topical wound healing agents after micro-needling treatment may influence the effectiveness of the procedure. This study investigates the histological and underlying molecular effects of post-treatment after micro-needling applications with a dexpanthenol-containing ointment (DCO) using 3D skin models. Since we have previously shown that micro-needling mediates most of its effect on dermis remodeling via upregulation of pro-inflammatory genes, which then lead to chemotaxis of immune cells, it was important to prove that this initial inflammatory effect is not attenuated by topical aftercare.6
Material and Methods
Isolation and Cultivation of Normal Human Epidermal Keratinocytes (NHEK) and Normal Human Dermal Fibroblasts (NHDF)
Primary NHDF and NHEK cells were isolated and cultivated as described previously.16–18 This study was conducted in accordance with the Declaration of Helsinki. The ethics committee of University Hospital RWTH Aachen approved this study prior to its conduction. A written informed consent was obtained from all participants.
3D Skin Models and Micro-Needling Procedure
Full-thickness 3D skin models were developed as previously described.6 Construction of the dermal part was done by using a collagen-elastin scaffold (MatriDerm®, MedSkin Solutions Dr. Suwelack AG, Billerbeck, Germany) on which 2×105 NHDF cells were seeded in bovine collagen I solution (Vitrogen, Cohesion Technologies, Palo Alto, CA, USA). After incubating the models for two days at 37 °C and 5% CO2, 2×106 NHEK cells were seeded on top of the dermal equivalent. Next day, skin models were lifted to the air-liquid interface (ALI). On day 7 of ALI, micro-needling of the models was performed with amiea med® EXCEED (MT.DERM GmbH, Berlin, Germany) using a six needle plate (1.5 NM615LS16309, MT.DERM GmbH). One hundred insertions were made per second at a penetration depth of 1.0 mm and with three passes, according to the manufacturer´s and clinical treatment recommendations. Immediately after micro-needling, the models were topically treated with a dexpanthenol-containing wound care ointment (Bepanthen® wound and healing ointment; Bayer Vital, Leverkusen, Germany). After 24 and 48 hours models were harvested for histology and gene expression analyses. An untreated model was maintained as a negative control at any given time. Experiments were performed four times independently with three different cell donors.
RNA-Isolation and Microarray Analysis
Total RNA from the micro-needled 3D skin models was extracted with the Nucleo Spin RNA kit (Macherey and Nagel, Düren, Germany), according to the manufacturer’s instructions. Microarray analysis was done as previously described19 by using Clariom™ S assays (Thermo Fisher, Waltham, USA). Expression values of each probe set were determined and data were analyzed using the TAC software (Thermo Fisher Scientific) with normalization method quantile.
Real-Time PCR Analysis
Assessment of isolated RNA was carried out using NanoDrop (Thermo, Erlangen, Germany), and the RNA integrity was checked using the 2100 Bioanalyzer (Agilent Technologies, Palo Alto, CA, USA). Reverse transcriptase-PCR was performed with TaqMan Reverse Transcription Reagents (Applied Biosystems, Weiterstadt, Germany) and the qRT-PCR analyses were executed on an ABI PRISM 7300 Sequence Detection System (Applied Biosystems). Assay-on-Demand gene expression products (Applied Biosystems) were used to study quantitative expression of LOR (Hs01894962_m1), CXCL5 (Hs00171085_m1), CXCL8 (Hs00174103_m1), FLG (Hs00856927_g1), HRNR (Hs02385268_m1), IL36G (Hs00219742_m1), FGF2 (Hs00266645_m1), IL1A (Hs00174092_m1), IL1B (Hs00174097_m1), IL1RL1 (Hs00249384_m1), IL20 (Hs00218888_m1), IL37 (Hs00367201_m1), IL24 (Hs01114274_m1) and MMP3 (Hs00233962_m1).
Light Microscopy
For histological analyses, 5 µm cryosections of 3D skin models were embedded in Tissue-Tek O.C.T. ™ compound (Sakura Finetek). Sections were stained with haematoxylin and eosin (H&E) and subsequently assessed by a photomicroscope (DMIL, Leitz, Wetzlar, Germany).
Statistical Analyses
Data are given as arithmetical means ± standard deviation (SD). Mann–Whitney U-test was performed with GraphPad PRISM version 7 (La Jolla, CA, USA). Values of *p < 0.05 were considered significant and are indicated in the figures.
Results
Histological differences between the DCO post-treated and the DCO-untreated micro-needling skin models were visible (Figure 1). Complete wound closure was evident in the DCO post-treated models after 24 hours. In the DCO-untreated skin models, the micro-needling lesions were still clearly recognizable after 24 hours.
Enlarge this image.Figure 1 Histological analysis of micro-needling-treated 3D skin models. Upper row shows hematoxylin and eosin stainings of untreated controls and skin models immediately after micro-needling treatment (0 h). The middle row shows untreated controls, micro-needling-treated models, and models that were additionally post-treated with DCO, 24 h after treatment. The bottom row shows the corresponding models 48 h after treatment. Shown are representative images from four independent experiments. h = hours. Scale bar: 200 µm. The black arrows indicate the lesions.
Since there were no histological differences between the models after 48 hours, we focused our gene expression analysis at 24 hours after treatment (Figure 2).
Enlarge this image.Figure 2 Gene expression profiling in micro-needling-treated 3D skin models. Microarray analysis in models 24 h after (a) micro-needling treatment in comparison to untreated controls, (b) micro-needling treatment and additional post-treatment with a dexpanthenol-containing ointment (DCO) in comparison to untreated controls, and (c) micro-needling treatment and additional post-treatment with DCO compared to micro-needling-treated models without post-treatment.
In 3D-skin models that have been treated with micro-needling but have not received post-treatment with DCO, microarray analysis showed an upregulation of pro-inflammatory cytokines and chemokines (eg, IL1RL1, IL24, IL1a, CXCL8) compared to the controls that were not treated with micro-needling (Figure 2a). In addition, anti-inflammatory genes (IL37) as well as skin barrier and differentiation markers (filaggrin (FLG), loricrin (LOR), hornerin (HRNR)) were downregulated. Additional post-treatment of the micro-needling models with DCO also preserved the initial upregulation of inflammatory markers (eg, CXCL8, CXCL5, IL24), but revealed no downregulation of skin barrier and differentiation markers compared to untreated controls reflecting the accelerated wound closure (Figure 2b).
To study the effects of DCO separately, we also carried out a microarray analysis by examining gene regulation in micro-needling models post-treated with DCO compared to micro-needling models without post-treatment (Figure 2c). In particular, we detected an upregulation of skin barrier and epidermal differentiation-associated genes (eg HRNR, LOR, FLG) in the DCO post-treated models compared to the non-DCO post-treated micro-needling models.
Independent RT-PCR analyses confirmed the microarray data (Figure 3). While micro-needling caused a significant downregulation of differentiation markers (LOR, FLG) in contrast to the untreated controls, almost the same expression levels as in the untreated models were observed after treatment with DCO. On the other hand, post-treatment with DCO did not adversely regulate inflammation-associated genes (eg, CXCL5, IL36G, IL24) compared with models that received micro-needling alone.
Enlarge this image.Figure 3 RT-PCR analysis of four independent experiments displaying the expression of selected genes. Selective gene expressions in micro-needling-treated skin models and micro-needling-treated skin models that received post-treatment with DCO were normalized to untreated controls. *p < 0.05.
Discussion
Generally, the wound healing process is described in three overlapping phases. Inflammation phase begins immediately after injury occurs and usually lasts for 48–96 hours. The proliferative phase follows the inflammation phase and finally the wound enters its remodeling phase.20
Through micro-needling a controlled stimulus is set. This stimulus triggers the wound healing cascade. As mentioned above, an injury initially causes inflammation. Platelets and neutrophils migrate to the wound area.21 As a result, pro-inflammatory cytokines are released.21,22 The various growth factors activate epithelization23 and collagen synthesis is stimulated.24 The desired effect of micro-needling (collagen synthesis) is therefore created by the inflammatory stimulus.
In a previous paper we showed molecular changes at day 5 after micro-needling that are consistent with the timeline of the wound healing process described above. For instance, several collagen synthesizing genes (eg COL3A1, COL8A1) were upregulated. In contrast to ablative CO2 laser treatments these effects are not directly mediated, eg, by upregulation of heat shock proteins, but seem to be mainly conveyed indirectly by upregulation of inflammatory mediators and subsequent chemotaxis leading to the upregulation of collagen synthesis in dermal fibroblasts.6,17
Our present study, on the other hand, focused on investigating the molecular and histological changes in wound healing caused by post-treatment with DCO after micro-needling. We detected an upregulation of genes associated with epidermal differentiation and skin barrier forming (FLG, LOR) 24 hours after micro-needling and post-treatment with DCO.25,26
Aware of the wound healing cascade explained above, this is earlier than one would expect. Congruently, we did not detect an upregulation of such genes in the skin models not receiving DCO, strongly indicating that the molecular changes facilitating wound healing are attributed to DCO-post treatment. Topical dexpanthenol treatment has a variety of beneficial effects on intact skin. It moisturizes and hydrates, also minimizes transepidermal water loss.27,28 It is known that topical treatment with dexpanthenol accelerates wound healing in damaged skin. These insights have been demonstrated in several in vivo and in vitro studies.13,27,29,30
Moreover, and of high relevance, according to our findings, the desired inflammatory stimulus caused by micro-needling to trigger collagen synthesis remains unimpaired by applying DCO as aftercare. We conclude that DCO may provide an excellent after-treatment for micro-needling by accelerating wound healing while not interfering with molecular processes substantial to obtain optimal results regarding skin rejuvenation.
Conclusion
We provide evidence that post-treatment with a dexpanthenol-containing ointment after micro-needling facilitates epidermal wound healing without impairing the micro-needling-induced inflammatory response needed to achieve collagen induction. These findings can help to optimize the aftercare of micro-needling procedures in the future.
Acknowledgments
This work was supported by a grant from Bayer Vital GmbH.
Disclosure
The authors report no conflicts of interest in this work.
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