Phase Behavior of Stratum Corneum Lipid Mixtures Based on Human Ceramides: The Role of Natural and Synthetic Ceramide 1

In a recent study the lipid phase behavior of mixtures of human ceramides, cholesterol, and free fatty acids has been examined. We observed in cholesterol: human ceramide mixtures a prominent formation of the 12.8 nm lamellar phase (referred to as the long periodicity phase). Addition of free fatty acids promoted the formation of a 5.6 nm lamellar phase (referred to as the short periodicity phase) and increased the subpopulation of lipids forming a fluid phase. In this study we focused on the role of human ceramide 1, as the presence of this ceramide appeared to be crucial for proper lipid phase behavior in mixtures prepared with ceramide isolated from pig stratum corneum. In order to do this, mixtures of cholesterol and free fatty acids were prepared with human ceramides, in which natural human ceramide 1 was replaced by either synthetic CER1-linoleate (CER1-lin), or CER1-oleate (CER1-ol), or CER1-stearate (CER1-ste). After substitution of natural human ceramide 1 by synthetic ceramide 1 the following observations were made. (i) In the presence of synthetic CER1-ste no long periodicity phase and no liquid phase could be detected. (ii) In the presence of HCER1-ol a liquid phase was more prominently formed than in the presence of HCER1-lin. (iii) In cholesterol:human ceramide mixtures in the presence of CER1-lin the long periodicity phase was more prominently present than in the presence of CER1-ol. (iv) In the presence of CER1-ste neither a long periodicity phase nor a liquid lateral packing could be detected. The results of these studies further indicate that for the formation of the long periodicity phase a certain (optimal) fraction of lipids has to form a liquid phase. When the fraction forming this liquid phase is either too low or too high, the formation of the short periodicity phase is increased at the expense of the formation of the long periodicity phase. Based on the results of this and previous studies we offer an explanation for the deviation in lipid organization in diseased and in dry skin compared to normal skin

On-Line Diffusion Profile of a Lipophilic Model Dye in Different Depths of a Hair Follicle in Human Scalp Skin

In skin and hair research, drug targeting to the hair follicle is of great interest in the treatment of skin diseases. The aim of this study is to visualize on-line the diffusion processes of a model fluorophore into the hair follicle at different depths using fresh human scalp skin and confocal laser scanning microscopy. Up to a depth of 500 μm in the skin, a fast increase of fluorescence is observed in the gap followed by accumulation of the dye in the hair cuticle. Penetration was also observed via the stratum corneum and the epidermis. Little label reached depths greater than 2000 μm. Fat cells accumulated the label fastest, followed by the cuticular area and the outer root sheath of the hair follicle. Sweat glands revealed very low staining, whereas the bulb at a depth of 4000 μm was visualized only by autofluorescence. From this study, we conclude that on-line visualization is a promising technique to access diffusion processes in deep skin layers even on a cellular level. Furthermore, we conclude that the gap and the cuticle play an important role in the initial diffusion period with the label in the cuticle originating from the gap

Vogelgriepvirus kwam aanvliegen uit Azië

CVI acht besmetting via trekvogels 'waarschijnlijk.' Het virus komt oorspronkelijk uit China

Stratum Corneum Lipid Composition and Structure in Cultured Skin Substitutes is Restored to Normal after Grafting onto Athymic Mice

Restoration of an epidermal barrier is a definitive requirement for wound closure. Cultured skin substitutes grafted onto athymic nude mice were used as a model for a long-term study of stratum corneum barrier lipid metabolism and organization. Samples of stratum corneum collected after 12 and 21 d in vitro and 6, 11, and 24 mo postgrafting were examined for their lipid and fatty acid composition, and their lipid organization and structure using electron microscopy and small angle X-ray diffraction, respectively. All of these methods confirm the impaired barrier function of cultured skin substitutes in vitro, as judged from the deviations in lipid composition and from poor organization of the stratum corneum lipids that show no lamellar structure. At 6 mo postgrafting, the total stratum corneum lipid profiles of the epidermal grafts is close to that of the human stratum corneum with the exception of the presence of mouse specific lipids. The increase of ceramides 4–7 in cultured skin substitutes after grafting indicates restored activity of processes involved in the hydroxylation of fatty acids and sphingoid bases. Conversely, the ceramide profile still reveals some abnormalities (elevated content of ceramide 2 and slightly lower content of ceramide 3) and the content of long-chain fatty acids remains below its physiologic level at 6 mo postgrafting, but normalizes by 2 y postgrafting. The ultramicroscopic observations revealed the formation of lamellar extracellular lipid domains by 4 mo postgrafting. Despite these findings, the X-ray diffraction showed differences in the diffraction pattern at 2 y after grafting, suggesting that the organization of stratum corneum lipids in all epidermal grafts differs from that of the native skin. Journal of Investigative Dermatology Symposium Proceedings 3:114–120, 199

Hyaluronic acid-recombinant gelatin gels as a scaffold for soft tissue regeneration

An array of different types of hyaluronic acid (HA)- and collagen-based products is available for filling soft-tissue defects. A major drawback of the current soft-tissue fillers is their inability to induce cell infiltration and new tissue formation. Our aim is to develop novel biodegradable injectable gels which induce soft tissue regeneration, initially resulting in integration and finally replacement of the gel with new autologous tissue. Two reference gels of pure HA, monophasic HA-1 and micronised HA-2, were used. Furthermore, both gels were mixed with recombinant gelatin (RG) resulting in HA-1+RG and HA-2+RG. All gels were subcutaneously injected on the back of rats and explanted after 4 weeks. Addition of RG to HA-1 resulted in stroma formation (neovascularisation and ECM deposition) which was restricted to the outer rim of the HA-1+RG gel. In contrast, addition of RG to HA-2 induced stroma formation throughout the gel. The RG component of the gel was degraded by macrophages and giant cells and subsequently replaced by new vascularised tissue. Immunohistochemical staining showed that the extracellular matrix components collagen I and III were deposited throughout the gel. In conclusion, this study shows the proof of principle that addition of RG to HA-2 results in a novel injectable gel capable of inducing soft tissue regeneration. In this gel HA has a scaffold function whereas the RG component induces new tissue formation, resulting in proper vascularisation and integration of the HA-2+RG gel with the autologous tissue

Transmission tree of the highly pathogenic avian influenza (H5N1) epidemic in Israel, 2015

The transmission tree of the Israeli 2015 epidemic of highly pathogenic avian influenza (H5N1) was modelled by combining the spatio-temporal distribution of the outbreaks and the genetic distance between virus isolates. The most likely successions of transmission events were determined and transmission parameters were estimated. It was found that the median infectious pressure exerted at 1 km was 1.59 times (95% CI 1.04, 6.01) and 3.54 times (95% CI 1.09, 131.75) higher than that exerted at 2 and 5 km, respectively, and that three farms were responsible for all seven transmission events. ELECTRONIC SUPPLEMENTARY MATERIAL: The online version of this article (doi:10.1186/s13567-016-0393-2) contains supplementary material, which is available to authorized users

Evidence of hydrocarbon nanodrops in highly ordered stratum corneum model membranes

Drug Delivery Technolog

Effects of ozone on stratum corneum lipid integrity and assembly

The stratum corneum (SC) acts as the main barrier of the skin against exogenous substances (e.g. air pollutants) and against the loss of endogenous substances such as water. The SC consists of keratin-rich dead cells surrounded by crystalline lamellar lipid regions. The main lipid classes are ceramides (CERs), free fatty acids (FFAs), and cholesterol (CHOL). Tropospheric ozone (O3) is a potent oxidant compound that reacts instantly with biological molecules such as lipids and proteins. Although it has been reported that O3 induces biological responses at the cellular level, to the best of our knowledge, there is no information related to the damages O3 can cause at the level of the SC extracellular lipid matrix. The aim of our work was to investigate which SC lipid subclasses are prone to oxidation when exposed to O3 and how the changes in chemical structures affect the lipid organization in a stratum corneum substitute (SCS) membrane. Ultimately, the barrier properties of the SCS were examined. Our studies revealed that O3 induces chemical modifications of the unsaturated bonds in CERs and CHOL. The appearance of carbonyl groups at the headgroup level and the removal of the linoleate moiety of omega‑O‑acylceramides (CER EOS) impact the lamellar organization of the lipid assembly and to a lesser extent the lateral packing of the lipids. Unexpectedly, these changes improved the barrier function of the SCS.Drug Delivery Technolog