Sensory neuron activation from topical treatments modulates the sensorial perception of human skin.

Neural signaling of skin sensory perception from topical treatments is often reported in subjective terms such as a sensation of skin "tightness" after using a cleanser or "softness" after applying a moisturizer. However, the mechanism whereby cutaneous mechanoreceptors and corresponding sensory neurons are activated giving rise to these perceptions has not been established. Here, we provide a quantitative approach that couples in vitro biomechanical testing and detailed computational neural stimulation modeling along with a comprehensive in vivo self-assessment survey to demonstrate how cutaneous biomechanical changes in response to treatments are involved in the sensorial perception of the human skin. Strong correlations are identified between reported perception up to 12 hours post treatment and changes in the computed neural stimulation from mechanoreceptors residing deep under the skin surface. The study reveals a quantitative framework for understanding the biomechanical neural activation mechanism and the subjective perception by individuals.

From decoding the perception of tightness to a clinical proof of soothing effects derived from natural ingredients in a moisturizer.

OBJECTIVE: To decode the feeling of skin tightness after application of a cosmetic product and how to soothe this discomfort. To pursue this aim, we considered the ingredient's effect on stratum corneum (SC) biomechanics to differentiate between consumers prone to tightness from those that are not and correlate these effects with mechanoreceptor activation. METHODS: In vivo clinical trials were used to assess the tightness perception dichotomy between groups of Caucasian women; in vitro experiments were used to measure the mechanical stresses induced in the SC after cleanser and moisturizer application; and in silico simulations were used to illustrate how the measured mechanical stresses in the SC result in the development of strains at the depth of cutaneous mechanoreceptors, triggering tightness perceptual responses. RESULTS: Before any cream application, women prone to tightness tend to have a more rigid SC than their less sensitive counterparts, however cleanser application increases SC stiffness in all women. Surprisingly, no correlation was found between tightness perception and hydration measurements by the Corneometer or barrier function, as evaluated by transepidermal water loss. Self-declared tightness and dryness scores were strongly associated with a self-described sensitive skin. After application of the optimized moisturizing formula, Osmoskin® containing natural waxes with good filming properties, consumers report a strong decrease in tightness and dryness perception. These results match with laboratory experiments where the cleanser was shown to increase SC drying stresses by 34%, while subsequent application of Osmoskin® decreased stresses by 48%. Finite element modelling, using experimental results as input, elucidates the differences in perception between the two groups of women. It makes clear that Osmoskin® changes the mechanical status of the SC, producing strains in underlying epidermis that activates multiple cutaneous mechano-receptors at a level correlated with the self-perceived comfort. CONCLUSION: Integration of the in vivo, in vitro and in silico approaches provides a novel framework for fully understanding how skin tightness sensations form and propagate, and how these sensations can be alleviated through the design of an optimized moisturizer.

OBJECTIF: Décoder l'impression de tiraillement de la peau après l'application d'un produit cosmétique et la manière d'apaiser cette sensation désagréable. Pour poursuivre cet objectif, nous avons pris en compte l'effet de l'ingrédient sur la biomécanique de la couche cornée afin de différencier les consommatrices sujettes à un tiraillement de celles qui ne le sont pas et de corréler ces effets avec l'activation des mécanorécepteurs. MÉTHODES: Des essais cliniques in vivo ont été utilisés pour évaluer la dichotomie de perception de tiraillement entre des groupes de femmes de race caucasienne; des expériences in vitro ont été utilisées pour mesurer les contraintes mécaniques induites dans la couche cornée après application d'un produit nettoyant et d'un produit hydratant; et des simulations in silico ont servi à illustrer comment les contraintes mécaniques mesurées dans la couche cornée entraînent le développement de souches à la profondeur des mécanorécepteurs cutanés, qui déclenchent les réponses perceptives de tiraillement. RÉSULTATS: Avant toute application de crème, les femmes sujettes au tiraillement tendent à avoir une couche cornée plus rigide que leurs homologues moins sensibles, mais l'application d'un produit nettoyant augmente la raideur de la couche cornée chez toutes les femmes. Étonnamment, aucune corrélation n'a été observée entre la perception de tiraillement et les mesures d'hydratation réalisées par le cornéomètre ou la fonction barrière, évaluée par la perte d'eau transépidermique. Les scores de tiraillement et de sécheresse auto-déclarés étaient fortement corrélés à une peau décrite par les sujets elles-mêmes comme sensible. Après application de la formule hydratante optimisée, Osmoskin®, qui contient des cires naturelles ayant de bonnes propriétés de dépôt de film, les consommateurs rapportent une forte diminution de la sensation de tiraillement et de sécheresse. Ces résultats concordent avec les expériences en laboratoire où le produit nettoyant s'est avéré augmenter les contraintes de séchage de la couche cornée de 34 %, tandis que l'application ultérieure d'Osmoskin® a réduit les contraintes de 48 %. La modélisation à éléments finis, en utilisant les résultats expérimentaux comme données, élucide les différences de perception entre les deux groupes de femmes. Il est clair qu'Osmoskin® modifie l'état mécanique de la couche cornée, et produit des souches dans l'épiderme sous-jacent qui activent plusieurs mécano-récepteurs cutanés à un niveau corrélé au confort perçu par la patiente. CONCLUSION: La combinaison des approches in vivo, in vitro et in silico fournit un nouveau cadre pour comprendre pleinement comment les sensations de tiraillement de la peau se forment et se propagent, et comment elles peuvent être soulagées en mettant au point une crème hydratante optimisée.

Biomechanical Analysis of the Ross Procedure in an Ex Vivo Left Heart Simulator.

BACKGROUND: Neo-aortic pulmonary autografts often experience root dilation and valve regurgitation over time. This study seeks to understand the biomechanical differences between aortic and neo-aortic pulmonary roots using a heart simulator. METHODS: Porcine aortic, neo-aortic pulmonary, and pulmonary roots (n = 6) were mounted in a heart simulator (parameters: 100 mm Hg, 37 °C, 70 cycles per minute, 5.0 L/min cardiac output). Echocardiography was used to study root distensibility (percentage change in luminal diameter between systole and diastole) and valve function. Leaflet motion was tracked with high-speed videography. After 30 min in the simulator, leaflet thickness (via cryosectioning), and multiaxial modulus (via lenticular hydrostatic deformation testing) were obtained. RESULTS: There were no significant differences between aortic and neo-aortic pulmonary leaflet motion, including mean opening velocity (218 vs 248 mm/s, P = .27) or mean closing velocity (116 vs 157 mm/s, P = .12). Distensibility was similar between aortic (8.5%, 1.56 mm) and neo-aortic pulmonary (7.8%, 1.12 mm) roots (P = .59). Compared to virgin controls, native pulmonic roots exposed to systemic pressure for 30 min had reduced leaflet thickness (630 vs 385 µm, P = .049) and a reduced Young's modulus (3,125 vs 1,089 kPa, P = .077). In contrast, the aortic roots exposed to pressure displayed no significant difference in aortic leaflet thickness (1,317 vs 1,256 µm, P = .27) or modulus (5,931 vs 3,631 kPa, P = .56). CONCLUSIONS: Neo-aortic pulmonary roots demonstrated equivalence in valve function and distensibility but did experience changes in biomechanical properties and morphology. These changes may contribute to long-term complications associated with the Ross procedure.

Proceed with Caution: Mouse Deep Digit Flexor Tendon Injury Model.

The purpose of this study was to determine the feasibility of using mouse models for translational study of flexor tendon repair and reconstruction. METHODS: Quantitative data detailing the gross anatomy, biomechanical characteristics, and microscopic structure of the deep digit flexor tendon (DDF) of the mouse hindpaw were obtained. Histological characterization of the DDF and the anatomy of the digit in the mouse hindpaw are detailed. Biomechanical testing determined the load-to-failure, stress, elastic modulus, and the site of tendon failure. RESULTS: In gross anatomy, the origins and insertions of the mouse deep digit flexor tendon are similar to those of the human digit, surrounded by a synovial sheath that is only 1- to 2-cells thick. A neurovascular network runs on each side of the digit outside the synovial sheath, but does not clearly penetrate it. The thickness of the DDF is 0.14 ± 0.03 mm and the width is 0.3 ± 0.03 mm. The thickness of the DDF is less than that of 9-0 nylon needle. The mean failure force of the deep flexor tendon was 2.79 ± 0.53N. CONCLUSIONS: The gross anatomy of the mouse hindpaw digit is similar to that of the human digit except for key differences seen in the synovial sheath and vascular supply. The dimensions of the mouse DDF make it challenging to create a clinically translatable repair model using currently available surgical techniques. Despite the similarities between the human and mouse anatomy, and the powerful basic science tools available in murine models, mice are an unreliable model for assessing flexor tendon injury and repair.

Multiaxial Lenticular Stress-Strain Relationship of Native Myocardium is Preserved by Infarct-Induced Natural Heart Regeneration in Neonatal Mice.

Neonatal mice exhibit natural heart regeneration after myocardial infarction (MI) on postnatal day 1 (P1), but this ability is lost by postnatal day 7 (P7). Cardiac biomechanics intricately affect long-term heart function, but whether regenerated cardiac muscle is biomechanically similar to native myocardium remains unknown. We hypothesized that neonatal heart regeneration preserves native left ventricular (LV) biomechanical properties after MI. C57BL/6J mice underwent sham surgery or left anterior descending coronary artery ligation at age P1 or P7. Echocardiography performed 4 weeks post-MI showed that P1 MI and sham mice (n = 22, each) had similar LV wall thickness, diameter, and ejection fraction (59.6% vs 60.7%, p = 0.6514). Compared to P7 shams (n = 20), P7 MI mice (n = 20) had significant LV wall thinning, chamber enlargement, and depressed ejection fraction (32.6% vs 61.8%, p < 0.0001). Afterward, the LV was explanted and pressurized ex vivo, and the multiaxial lenticular stress-strain relationship was tracked. While LV tissue modulus for P1 MI and sham mice were similar (341.9 kPa vs 363.4 kPa, p = 0.6140), the modulus for P7 MI mice was significantly greater than that for P7 shams (691.6 kPa vs 429.2 kPa, p = 0.0194). We conclude that, in neonatal mice, regenerated LV muscle has similar biomechanical properties as native LV myocardium.

Comment on "Light-induced lattice expansion leads to high-efficiency perovskite solar cells".

Tsai et al (Reports, 6 April 2018, p. 67) report a uniform light-induced lattice expansion of metal halide perovskite films under 1-sun illumination and claim to exclude heat-induced lattice expansion. We show that by controlling the temperature of the perovskite film under both dark and illuminated conditions, the mechanism for lattice expansion is in fact fully consistent with heat-induced thermal expansion during illumination.