High-intensity focused ultrasound for the reduction of subcutaneous adipose tissue using multiple treatment techniques.

BACKGROUND: High-intensity focused ultrasound (HIFU) is a noninvasive alternative to traditional invasive body sculpting procedures. OBJECTIVE: To assess the effectiveness and tolerability of HIFU treatment using high and low fluence settings with 2 treatment techniques, grid repeat (GR) and site repeat (SR). MATERIALS AND METHODS: Two multicenter studies were conducted. Subjects underwent 1 HIFU treatment with 1 of 5 treatment protocols (total fluence, 150-180 J/cm). Primary end point was change from baseline in waist circumference (CBWC) at 12 weeks. Secondary end points included CBWC at 4 and 8 weeks and investigator- and subject-assessed clinical improvement. Adverse events were monitored throughout the study. RESULTS: In the intent-to-treat (ITT) population, all subjects had a statistically significant mean circumferential reduction of -2.3 ± 2.9 cm (p < .0001) from baseline at 12 weeks, with no significant differences among the 5 treatment groups (ITT: p = .153). Analysis of secondary end points in the ITT population demonstrated a significant circumferential reduction starting as early as 4 weeks in all subjects (-1.1 ± 1.9 cm, p < .0001). Most subjects in all treatment groups showed improvements at 12 weeks as rated by the investigators and subjects. CONCLUSION: High-intensity focused ultrasound treatment using either a low or high fluence setting in a GR or SR method is effective for circumferential waist reduction, resulting in statistically significant CBWC in all treatment groups.

Immunohistochemical evaluation of the heat shock response to nonablative fractional resurfacing.

Despite the emergence of nonablative fractional resurfacing (NFR) as a new therapeutic modality for skin photoaging, little is known about the molecular events that underlie the heat shock response to different treatment parameters. Human subjects are treated with a scanned 1550-nm fractional laser at pulse energies spanning 6 to 40 mJ and a 140-µm spot size. The heat shock response is assessed immunohistochemically immediately through 7 days posttreatment. At the immediately posttreatment time point, we observe subepidermal clefting in most sections. The basal epidermis and dermal zones of sparing are both found to express HSP47, but not HSP72. By day 1, expression of HSP72 is detected throughout the epidermis, while that of HSP47 remains restricted to the basal layer. Both proteins are detected surrounding the dermal portion of the microscopic treatment zone (MTZ). This pattern of expression persists through day 7 post-NFR, although neither protein is found within the MTZ. Immediately posttreatment, the mean collagen denaturation zone width is 50 µm at 6 mJ, increasing to 202 µm at 40 mJ. The zone of cell death exceeds the denaturation zone by 19 to 55% over this pulse energy range. The two zones converge by day 7 posttreatment.

The effects of pulse energy variations on the dimensions of microscopic thermal treatment zones in nonablative fractional resurfacing.

BACKGROUND AND OBJECTIVES: We examined the effects of pulse energy variations on the dimensions of microscopic thermal injury zones (MTZs) created on human skin ex vivo and in vivo using nonablative fractional resurfacing. MATERIALS AND METHODS: A Fraxel SR laser system emitting at 1,550 nm provided an array of microscopic spots at variable densities. Pulse energies ranging from 4.5 to 40 mJ were tested on human abdominal skin ex vivo and in vivo. Tissue sections were stained with hematoxylin and eosin (H&E) or nitro blue tetrazolium chloride (NBTC) and MTZ dimensions were determined. Ex vivo and in vivo results were compared. Dosimetry analyses were made for the surface treatment coverage calculation as a function of pulse energy and collagen coagulation based on H&E stain or cell necrotic zone based on NBTC stain. RESULTS: Each MTZ was identified by histological detection of a distinct region of loss of tissue birefringence and hyalinization, representing collagen denaturation and cell necrosis within the irradiated field immediately, 1, 3, and 7 days after treatment. At high pulse energies, the MTZ depth could exceed 1 mm and width approached 200 microm as assessed by H&E. NBTC staining revealed viable interlesional tissue. In general, no statistically significant difference was found between in vivo and ex vivo depth and width measurements. CONCLUSIONS: The Fraxel SR laser system delivers pulses across a wide range of density and energy levels. We determined that increases in pulse energy led to increases in MTZ depth and width without compromising the structure or viability of interlesional tissue.

Laser-induced transepidermal elimination of dermal content by fractional photothermolysis.

The wound healing process in skin is studied in human subjects treated with fractional photothermolysis. In-vivo histological evaluation of vacuoles formed over microthermal zones (MTZs) and their content is undertaken. A 30-W, 1550-nm single-mode fiber laser system delivers an array of 60 microm or 140 microm 1e2 incidence microbeam spot size at variable pulse energy and density. Treatments span from 6 to 20 mJ with skin excisions performed 1-day post-treatment. Staining with hematoxylin and eosin demonstrates an intact stratum corneum with vacuolar formation within the epidermis. The re-epithelialization process with repopulation of melanocytes and keratinocytes at the basal layer is apparent by 1-day post-treatment. The dermal-epidermal (DE) junction is weakened and separated just above zones of dermal coagulation. Complete loss of dermal cell viability is noted within the confines of the MTZs 1-day post-treatment, as assessed by lactate dehydrogenase. All cells falling outside the irradiation field remain viable. Content within the epidermal vacuoles stain positively with Gomori trichrome, suggesting a dermal origin. However, the positive staining could be due to loss of specificity after thermal alteration. Nevertheless, this dermal extrusion hypothesis is supported by very specific positive staining with an antihuman elastin antibody. Fractional photothermolysis creates microthermal lesions that allow transport and extrusion of dermal content through a compromised DE junction. Some dermal material is incorporated into the microepidermal necrotic debris and shuttled up the epidermis to eventually be exfoliated through the stratum corneum. This is the first report of a nonablative laser-induced transport mechanism by which dermal content can be predictably extruded biologically through the epidermis. Thus, treatment with the 1550-nm fiber laser may provide the first therapeutic option for clinical indications, including pigmentary disorders such as medically recalcitrant melasma, solar elastosis, as well as depositional diseases such as mucinosis and amyloidosis.