Bubble growth within the skin by rectified diffusion might play a significant role in sonophoresis.

Low frequency ultrasound has successfully been used for enhancing transdermal transport of a variety of different molecules. This phenomenon is referred to as sonophoresis. Several attempts have been made to investigate the enhancing mechanism in order to modulate the overall process. In this study we assess whether rectified diffusion is a process that occurs within the skin, which could eventually lead to channeling and thereby to transdermal sonophoresis. The model presented in this paper is based on the following postulate: gas bubbles are randomly distributed within the lipid bilayers of the stratum corneum (SC). As the skin is subjected to ultrasound, gas bubbles grow by rectified diffusion. During this period, bubbles may merge with the outer or inner boundaries of the SC, or merge with neighboring bubbles. Eventually, channels are created, allowing drugs to easily penetrate through the most significant barrier to transdermal delivery, the SC. As a result, transdermal transport rate is enhanced. In this work, a mathematical model has been formulated, in which permeability enhancement of the SC is linked to channels, possibly created by means of rectified diffusion. Sonophoresis may result from various mechanisms that act in synergy. The present model predicts that rectified diffusion might be one of the factors that lead to sonophoresis during ultrasound treatment.

The nature of ultrasound-SLS synergism during enhanced transdermal transport.

Ultrasound and sodium lauryl sulfate (SLS) exhibit a synergistic effect on transdermal transport, when applied simultaneously on the skin. The synergistic mechanism is not fully understood. Previous studies have shown that application of ultrasound simultaneously with SLS, results in enhanced mass transfer and improved penetration and dispersion of the surfactant. In this study we demonstrate that simultaneous application of ultrasound and SLS leads to modification of the pH profile of the stratum corneum. This pH modification within the stratum corneum's microenvironment, can affect both the structure of the lipid layers and the activity of SLS as a chemical enhancer due to its improved lipophilic solubility. The altered pH profile that results in improved SLS lipophilic solubility, together with improved SLS penetration and dispersion, can explain the synergistic enhancing effect of ultrasound and SLS on transdermal transport.

Ultrasound and transdermal drug delivery.

Transdermal drug delivery offers an attractive alternative to the conventional drug delivery methods of oral administration and injection. However, the stratum corneum acts as a barrier that limits the penetration of substances through the skin. Application of ultrasound to the skin increases its permeability (sonophoresis) and enables the delivery of various substances into and through the skin. This review presents the main findings in the field of sonophoresis, namely transdermal drug delivery and transdermal monitoring. Particular attention is paid to proposed enhancement mechanisms and future trends in the field of cutaneous vaccination and gene delivery.

Combined ultrasonic and enzymatic debridement of necrotic eschars in an animal model.

Several methods are used to debride burn eschars, however, most are ineffective for ischemic eschars. We investigated a novel combination of enzymatic and ultrasonic debridement for ischemic eschars. A previously described ischemic flap model in rats was used to compare the time to flap debridement or perforation of enzymatic (Debrase, a derivative of bromelain), ultrasonic, or combined debridement (Hybrid Debridement Technology). We also evaluated the effects of ultrasonic intensity, probe size, probe housing, and operation mode (pulsatile vs. continuous) on the time to full eschar perforation. Ultrasonic and enzymatic debridement alone did not result in flap perforation even after 15 minutes. Combined ultrasonic and enzymatic debridement resulted in flap perforation within 2 to 5 minutes in the four flap zones (P < 0.001 for all four flap zones compared with ultrasound alone). The most rapid debridement was observed with an ultrasonic intensity of 3.2 W/cm, applied using a 4.9 cm probe. The temperature elevation associated with ultrasonication was controlled by perfusion of fresh Debrase solution and alternating the ultrasound energy. Combination of ultrasonic and enzymatic debridement of ischemic flap eschars in rats with Debrase is more rapid and effective than either method alone.