The human skin aging process is characterized by thinning dermis, atrophy of the extracellular matrix, and reduced collagen synthesis. Loss of collagen in the dermis is of aesthetic concern, as it is the main structural support in the dermis and its loss results in skin laxity. Photo-damaged skin, mostly due to UVR, causes degradation of elastic fibers. This is histologically seen as disorganized tangles of elastin. Additionally, as humans age, skin tends to appear more dry due to its poor hydration and turgor capacity. The use of minimally invasive aesthetic treatments in reducing signs of aging has been gaining in popularity over surgical treatments in recent years. Several energy types including, laser, radiofrequency, infrared, and ultrasound, have been developed for facial rejuvenation. These treatments induce controlled thermal damage into the dermis and cause collagen contraction and neocollagenesis resulting in skin tightening over several months. For improving appearance of other anatomical areas, micro-focused ultrasound has been the preferred method, but has shown limited success in tightening the suprapatellar skin. As with facial skin aging, the suprapatellar skin loses elasticity with age and begins to sag. Noninvasive treatments used for the face may also be used in other anatomical areas to produce the same effects of tightening. Minimally invasive bipolar radiofrequency produces a controlled thermal injury in a fractional manner without damaging the dermal-epidermal junction, epidermis or subcutis. Radiofrequency, unlike lasers, are chromophore-independent providing better penetration than lasers, and spare sweat glands, sebaceous glands, and hair follicles.
The Profound System is a bipolar fractional radiofrequency device which uses microneedles and thermal heat to stimulate neocollagenesis. Based on the its effect on facial skin, it can be hypothesized that bipolar fractional radiofrequency will stimulate similar effect on suprapatellar skin, lifting and reducing laxity of the skin in that region. This study intends to evaluate the effectiveness of the Profound System on suprapatellar skin, which has been FDA approved for treatment of facial wrinkles and improvement in the appearance of cellulite. This device is a well studied and frequently used on facial skin, however, there are no studies showing its effectiveness elsewhere on the body. There are alternative treatments that have been shown to decrease laxity of the suprapatellar skin, however, the studies include a small and limited population, and have not produced the desired effects in practice. The Profound device may be able to produce clinically significant improvement in laxity of the suprapatellar skin.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
TREATMENT
Masking
NONE
Enrollment
20
Profound system is a bipolar fractional radiofrequency device which uses microneedles and thermal heat to stimulate neocollagenesis. Based on the its effect on facial skin, it can be hypothesized that bipolar fractional radiofrequency will stimulate similar effect on suprapatellar skin, lifting and reducing laxity of the skin in that region. Bilateral suprapatellar regions will be identified and marked for treatment.
University of Texas Southwestern Medical Center
Dallas, Texas, United States
Photographic Knee Laxity and Texture Evaluation
Photographs will be used to evaluate efficacy of treatment. The photographs from final visit will be compared to their baseline photographs and visually evaluated by the study team. The study team will assess the laxity from baseline to 6 months.
Time frame: baseline and 6 months
Epidermal Thickness
Skin Elasticity will be measured via BTC2000 prior to treatment (baseline), 7 days, 3 weeks, 3 months and 6 months post treatment. The change from baseline was calculated at each time frame.
Time frame: baseline, 7 Days, 3 Weeks, 3 Months and 6 Months
Dermal Thickness
Dermal thickness will be masured via high resolution ultrasound prior to treatment (baseline), 7 days, 3 weeks, 3 months and 6 months post treatment. The change from baseline was calculated at each time frame.
Time frame: Baseline, 7 Days, 3 Weeks, 3 Months and 6 Months
Change in Blood Flow at 0.25mm
Blood Flow will be measured via optical coherence tomography prior to treatment (baseline), 7 days, 3 weeks, 3 months and 6 months post treatment.
Time frame: Baseline, Day 7, Week 3 Month 3 and Month 6
Transepidermal Water Loss
Transepidermal Water Loss will be masured via Aquaflux prior to treatment (baseline), 7 days, 3 weeks, 3 months and 6 months post treatment. The change from baseline was calculated at each time frame.
Time frame: Baseline, Day 7, Week 3, Month 3 and Month 6
Skin Elasticity
Skin Elasticity will be measured via BTC2000 prior to treatment (baseline), 7 days, 3 weeks, 3 months and 6 months post treatment. The change from baseline was calculated at each time frame.
Time frame: Baseline, Day 7, Week 3, Months 3 and Months 6
Change in Skin Laxity
BTC2000 will be used to measure skin laxity prior to treatment and post treatment. The BTC2000 is a non-invasive device that measures skin laxity by creating a negative pressure against the skin and calculates laxity when the pressure is released.
Time frame: baseline, 7 days, 3 weeks, 3 months and 6 months
Histological Analysis- Collagen 1
Relative changes in protein abundance in biopsies taken at post treatment compare to control or entreated group will be quantified using an image processing software based on fluorescence signal intensity. The change from baseline was calculated at each time frame.
Time frame: Baseline. Day 7 and 3 Months
Gene Expression- Collagen 1
Biopsies of the treated are will be taken prior to treatment and post treatment for gene expression analysis. This analysis will identify gene expression related to collagen formation and increased cell turnover. Fold change was calculated at each time point past baseline. Fold change = sample/average of the baseline.
Time frame: Day 7, Month 3
Epidermal Density
Epidermal thickness will be masured via high resolution ultrasound prior to treatment (baseline), 7 days, 3 weeks, 3 months and 6 months post treatment. The change from baseline was calculated at each time frame.
Time frame: Baseline, Day 7, Week 3, Month 3 and Month 6
Histological Analysis- Collagen 3
Relative changes in protein abundance in biopsies taken at post treatment compare to control or entreated group will be quantified using an image processing software based on fluorescence signal intensity. The change from baseline was calculated at each time frame. Sample/Average of the baseline.
Time frame: Baseline, Day 7, Month 3
Histological Analysis- Elastin
Relative changes in protein abundance in biopsies taken at post treatment compare to control or entreated group will be quantified using an image processing software based on fluorescence signal intensity. The change from baseline was calculated at each time frame. Samples/Average of the baseline
Time frame: Baseline, Day 7, Month 3
Gene Expression- Collagen 3
Biopsies of the treated are will be taken prior to treatment and post treatment for gene expression analysis. This analysis will identify gene expression related to collagen formation and increased cell turnover. Fold change = sample/average of the baseline.
Time frame: Day 7, Month 3
Gene Expression- Elastin
Biopsies of the treated are will be taken prior to treatment and post treatment for gene expression analysis. This analysis will identify gene expression related to collagen formation and increased cell turnover. Fold change = sample/average of the baseline.
Time frame: Day 7, Month 3
Gene Expression- Interluekin 6
Biopsies of the treated are will be taken prior to treatment and post treatment for gene expression analysis. This analysis will identify gene expression related to collagen formation and increased cell turnover. Fold change = sample/average of the baseline.
Time frame: Day 7, Month 3
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