Background BellaGel® is the only cohesive silicone gel-filled breast implant from a Korean manufacturer, and it was first developed in 2005. It was approved by the CE in 2008, thus becoming the first Asian breast implant available in the EU. We conducted this study to assess the safety of BellaGel® in patients receiving augmentation mammaplasty. Methods We evaluated a consecutive series of 239 patients (478 breasts) who received esthetic augmentation mammaplasty using the BellaGel® (round smooth, round textured, round nanotextured, and anatomical textured types of implant) (HansBiomed Co. Ltd., Seoul, Korea) at three clinics in Korea (JW Plastic Surgery Center, BS The Body Plastic Surgery Clinic and Grace Plastic Surgery Clinic) during a period from December 1, 2015 to January 31, 2018. Results A total of 239 patients with a mean age of 33.1 ± 8.5 years old were followed up during a mean period of 399.58 ± 232.71 days, where there were no cases of capsular contracture in our clinical series of the patients. Other complications include one case (0.4%) of seroma, three cases (1.3%) of hematoma, and one case (0.4%) of infection. Moreover, there were no significant differences in the cumulative incidences of complications between the four types of the BellaGel® (χ 2 = 2.322, df = 3, P = 0.508). Furthermore, the cumulative Kaplan-Meier survival rate was estimated at 0.979 (95% CI 0.961-0.997).Conclusions Our results indicate that the BellaGel® is such a safe breast implant that surgeons might consider using it for esthetic augmentation mammaplasty. Level of evidence: Level III, risk/prognostic study.
Background Cryolipolysis, a preferred method for minimally invasive body contouring, involves the noninvasive cooling of adipocytes to induce lipolysis without damaging other tissues. This study aimed to evaluate the safety and efficacy of cryolipolysis for the treatment of excessive fat tissue. Methods Between May 2014 and December 2017, 231 patients with 448 areas of interest were enrolled and their records were retrospectively reviewed. We used five different vacuum applicators, and the best-fitting applicator was used for each area. One cycle of cryolipolysis was applied at a cooling intensity factor of 41.6. The efficacy was evaluated 12 weeks after treatment via review of clinical photographs, the pinch test, and ultrasonographic measurements of fat thickness. The occurrence of any complications was also assessed.
ResultsThe volume was reduced in all of the areas to which cryolipolysis was applied. The rate of reduction of the fat layer as measured via the pinch test was 19.2%, and the rate of the decrease in fat layer thickness as measured via ultrasonography was 22.8%. Fat reduction of the upper arm differed significantly from that of the abdomen and flank, but no significant difference was found between sexes. The side effects were limited to erythema, edema, bruising, and numbness at the treatment site and resolved without treatment. Conclusions Cryolipolysis, with new and better-fitting applicators, is safe, fast, and effective for the reduction of excessive fat tissue on the abdomen, back, flank, and extremities. It is a good option for treating excess adipose tissue in Asian patients.
Background
Adipose tissue-derived microvascular fragments are functional vessel segments derived from arterioles, capillaries, and veins. Microvascular fragments can be used as vascularization units in regenerative medicine and tissue engineering containing microvascular networks. However, the in vivo therapeutic and vascularization properties of human microvascular fragments have not been investigated.
Methods
In this study, we isolated microvascular fragments, stromal vascular fractions, and mesenchymal stem cells from human lipoaspirate and studied their therapeutic efficacy and in vivo vasculogenic activity in a murine model of hindlimb ischemia. In addition, in vivo angiogenic activity and engraftment of microvascular fragments into blood vessels were measured using Matrigel plug assay.
Results
Both microvascular fragments and stromal vascular fractions contain not only mesenchymal stem cells but also endothelial progenitor cells. In a Matrigel plug assay, microvascular fragments increased the number of blood vessels containing red blood cells more than mesenchymal stem cells and stromal vascular fractions did. The engraftment of the microvascular fragments transplanted in blood vessels within the Matrigel plug significantly increased compared to the engraftment of mesenchymal stem cells and stromal vascular fractions. Moreover, intramuscular injection of microvascular fragments markedly increased blood flow in the ischemic hindlimbs and alleviated tissue necrosis compared to that of mesenchymal stem cells or stromal vascular fractions. Furthermore, transplanted microvascular fragments formed new blood vessels in ischemic limbs.
Conclusions
These results suggest that microvascular fragments show improved engraftment efficiency and vasculogenic activity in vivo and are highly useful for treating ischemic diseases and in tissue engineering.
Graphical Abstract
Adipose tissue-derived microvascular fragments are vascularization units in regenerative medicine and tissue engineering containing microvascular networks. Intramuscular injection of microvascular fragments markedly increased blood flow in the ischemic hindlimbs and alleviated tissue necrosis. The present study suggests that microvascular fragments show improved engraftment efficiency and vasculogenic activity in vivo and are highly useful for treating ischemic diseases and in tissue engineering.
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