Transepidermal Potential of the Stretched Skin.

The electrical response of the skin to mechanical stretches is reported here. The electrical potential difference across the epidermis, i.e., transepidermal potential (TEP) of porcine skin samples subjected to cyclic stretching, was measured in real time to observe electrochemical change in epidermal tissue. In addition to a conventional method of TEP measurement for the whole of skin sample, a probe-type system with a fine-needle salt bridge was used for direct measurement of TEP at a targeted local point of the skin. TEP decreased with the increased mechanical stretches, and the change of TEP was found to be mostly occurred in the epidermis but not dermis nor hypodermis by comparing the results of conventional and the probe-type methods. The observed change of TEP value was quick, reversible, and strain-dependent. Considering from such characteristic behaviors, one of the possible mechanisms of the modulation of TEP would be influence of the streaming potential caused by the fluid flow during the physical deformation of the epidermis.

Minimally-invasive transepidermal potentiometry with microneedle salt bridge.

A commercial painless microneedle was filled with physiological saline agar, and this needle-based salt bridge was inserted into the skin (a piece of porcine skin and a flank skin of a live mouse) to make an electrical contact with its subepidermal region. The transepidermal potential (TEP), the potential difference between the skin surface and the subepidermal region, was measured using this inner electrode and a conventional agar electrode on the surface of the skin. Control of penetration depth of the inner electrode with a spacer and hydrophilic pretreatment with ozone plasma were found to be necessary for stable measurement. The TEP was reduced upon damages on the skin surface by tape stripping and acetone defatting, which indicated the fabricated needle electrode is useful for the minimally-invasive measurement of TEP and evaluation of skin barrier functions. Furthermore, we showed that the device integrating two electrodes into a single compact probe was useful to evaluate the local barrier functions and their mapping on a skin. This device could be a personal diagnostic tool in the fields of medicine and cosmetics in future.

Electrical aspects of skin as a pathway to engineering skin devices.

Skin is one of the indispensable organs for life. The epidermis at the outermost surface provides a permeability barrier to infectious agents, chemicals, and excessive loss of water, while the dermis and subcutaneous tissue mechanically support the structure of the skin and appendages, including hairs and secretory glands. The integrity of the integumentary system is a key for general health, and many techniques have been developed to measure and control this protective function. In contrast, the effective skin barrier is the major obstacle for transdermal delivery and detection. Changes in the electrical properties of skin, such as impedance and ionic activity, is a practical indicator that reflects the structures and functions of the skin. For example, the impedance that reflects the hydration of the skin is measured for quantitative assessment in skincare, and the current generated across a wound is used for the evaluation and control of wound healing. Furthermore, the electrically charged structure of the skin enables transdermal drug delivery and chemical extraction. This paper provides an overview of the electrical aspects of the skin and summarizes current advances in the development of devices based on these features.

Red light-promoted skin barrier recovery: Spatiotemporal evaluation by transepidermal potential.

The light-promoted recovery of epidermal barrier of skin was evaluated by the associated recovery of transepidermal potential (TEP), the potential difference between the surface and dermis of skin, by using porcine skin samples. An accelerated recovery of TEP was observed by irradiation of red light with the irradiance of 40 mW/cm2 and a duration of > 10 min. The influence of the light stimulation to the surroundings (~ 20 mm) was also observed. The irradiations of blue and purple lights were ineffective in accelerating the barrier recovery. These characteristics of the light stimulation would be useful for the design of effective and safe phototherapy devices for skin. The present study proves that the TEP can serve as a spatiotemporal indicator of the epidermal barrier function.

Portable Micropatterns of Neuronal Cells Supported by Thin Hydrogel Films.

A grid micropattern of neuronal cells was formed on a free-standing collagen film (35 µm thickness) by directing migration and extension of neurons along a Matrigel pattern previously prepared on the film by the microcontact printing method. The neurons migrated to reach the nodes on the grid pattern and extended neurites to bridge cell bodies at the nodes. The resulting neuronal micropattern on the collagen film containing culture medium can be handled and deformed with tweezers with maintenance of physiological activity of the neurons, as examined by response of cytosolic Ca2+ concentration to a dose of bradykinin. This portability is the unique advantage of the present system that will open novel possibility of cellular engineering including the on-demand combination with analytical devices. The repetitive lamination of the film on a microelectrode chip was demonstrated for local electrical stimulation of a specific part of the grid micropattern of neurons, showing Ca2+ wave propagation along the neurites. The molecular permeability is the further advantage of the free-standing hydrogel substrate, which allows external supply of nutrients and dosing with chemical stimulants through the film even under rolled and laminated conditions.