Synergistic Effects of Cryolipolysis and Shock Waves for Noninvasive Body Contouring
G. A. Ferraro • F. De Francesco • C. Cataldo •
F. Rossano • G. Nicoletti • F. D’Andrea
Abstract
Background Excess body fat, localized adiposity, and cellulite represent important social problems. To date, techniques using radiofrequencies, cavitation and nonca-vitation ultrasound, and carbon dioxide have been studied as treatments for noninvasive body contouring. Ice-Shock Lipolysis is a new noninvasive procedure for reducing subcutaneous fat volume and fibrous cellulite in areas that normally would be treated by liposuction. It uses a com-bination of acoustic waves and cryolipolysis. Shock waves, used normally in the treatment of renal calculi and mus-culoskeletal disorders, are focused on the collagen structure of cellulite-afflicted skin. When used on the skin and underlying fat, they cause a remodeling of the collagen fibers, improving the orange-peel appearance typical of the condition. Cryolipolysis, on the other hand, is a noninva-sive method used for the localized destruction of subcuta-neous adipocytes, with no effects on lipid or liver marker levels in the bloodstream. The combination of the two procedures causes the programmed death and slow resorption of destroyed adipocytes.
Methods In this study, 50 patients with localized fat and cellulite were treated with a selective protocol for the simultaneous use of two transducers: a Freezing Probe for localized fatty tissue and a Shock Probe for fibrous cellulite.
Results
The procedure significantly reduced the circum-ference in the treated areas, significantly diminishing fat thickness. The mean reduction in fat thickness after treat-ments was 3.02 cm. Circumference was reduced by a mean of 4.45 cm. Weight was unchanged during the treatment, and no adverse effects were observed. Histologic and immunohistochemical analysis confirmed a gradual reduction of fat tissue by programmed cell death. More-over, the reduction in fat thickness was accompanied by a significant improvement in microcirculation, and thus, the cellulite. The safety of the method also has been high-lighted because it is accompanied by no significant increase in serum liver enzymes or serum lipids.
Conclusion
The study aimed to observe the effects of the new technique in the treatment of localized fat associated with cellulite in order to assess adipose tissue alterations, cellular apoptosis, and levels of serum lipid or liver markers. The findings show that the action of Ice-Shock Lipolysis is a safe, effective, and well-tolerated noninva-sive procedure for body contouring. In particular, the authors believe that this could be an ideal alternative to liposuction for patients who require only small or moderate amounts of adipose tissue and cellulite removal or are not suitable candidates for surgical approaches to body contouring.
Keywords Cryolipolysis Extracorporeal shock waves Body contouring Fat reduction Cellulite
Excess body fat and localized adiposity represent great health problems frequently associated with dissatisfaction about body shape, altered self-esteem, and disadvantage in interpersonal relationships. The latter problem, often associated with being overweight, includes cellulite.
Cellulite is an alteration in the topography of the skin of the pelvic region, lower limbs, and abdomen. It is the irregular, dimpled-skin surface phenomenon that affects 85% to 98% of postadolescent woman of all races [1]. Cellulite, also called liposclerosis [2], edematofibroscle-rotic panniculopathy [3], and gynoid lipodystrophy (GLD)[4], is an aesthetic alteration of the cutaneous surface, and many patients affected by it seek plastic surgery to improve their appearance.
Various cosmetic procedures and devices have been developed to remove or reduce unwanted local subcuta-neous fat. Conventional fat removal is achieved surgically by lipectomy or liposuction [5]. Currently, they are by far the most common and effective procedure for body con-touring and completely safe. However, it remains an invasive procedure.
Noninvasive alternatives to liposuction have been attempted for body contouring, with variable, if any, scien-tific demonstration of safety. Although lipoplasty is pur-ported by some to be an excellent method for improving body contouring [6], others have reported increased skin dimpling after liposuction in patients with cellulite and localized fat deposits [7]. A few therapeutic options have been developed for the treatment of cellulite associated with localized fat deposits [8, 9] including bipolar radiofrequency (RF), infrared (IR) heat and pulsatile suction devices [10, 11], optical devices [12, 13], botanical extracts [14], mesotherapy [15], a combination of mesotherapy and phosphatidylcholine injections [16], and external ultrasound [17, 18]. Only some of these procedures have been approved by the U.S. Food and Drug Administration. In particular, novel applications using ultrasound without surgical intervention have been investi-gated for delivery of an energy signature through the skin to disrupt adipose tissue [19].
Cryolipolysis is a recent development in noninvasive lipoplasty whereby fat layer reduction is produced by selective destruction of fat cells [20]. This technique uses controlled cold exposure to obtain a gradual reduction of the subcutaneous fat layer without damage to other tissues. Fat cells, in fact, are much more sensitive to cold-induced apoptosis than other anatomic structures such as skin, dermis, vessels, nerves, and muscles [21].
The adipose tissue is placed in contact with iced plates using a pressure applicator that thermically ‘‘kills’’ fat without damaging the skin. The dead cells then are meta-bolically eliminated, exactly as occurs for the fat found in food. [22]. The positive sides of cryotherapy in terms of reduced body fat lead to a reduction in complications and risks related to plastic surgery procedures [23, 24].
On the other hand, extracorporeal shock waves (ESW) are electrical energy transformed by mechanical energy through the piezo effect. Shock waves have been used in the medical field since 1980 to treat lithiasic pathologies (for renal stone fragmentation) with the aim of destroying the targeted structures without damaging surrounding tis-sues [25].
In the mid-1980s, new studies opened ulterior horizons on the effective therapeutic potential of shock waves, particu-larly in the orthopedic field (pseudoarthrosis, tendinopathy)[26], for musculoskeletal diseases (calcaneal spur, tennis elbow, golf arm) [27] and for the cure of chronic soft tissue conditions [28] such as neuropathic ulcers of the foot [29]or burning [30]. Several studies have demonstrated that the biologic effects of ESW also are caused by the release of mediators, such as vascular endothelial growth factor (VEGF) [31], which significantly increase angiogenesis and local blood circulation [32]. Moreover, in aesthetic medi-cine, shock waves are used in painless methods for efficient contrast of beauty flaws and cellulite [33, 34].
This report describes a pilot study for a new noninvasive device that uses a combination of cryolipolysis and acoustic waves for body contouring through the reduction of localized fat deposits associated with cellulite in areas that normally would be treated by liposuction. Our study demonstrates, for the first time, that this new technology, termed Ice-Shock Lipoysis, provides a safe and effective noninvasive treatment for body contouring and cellulite.
Materials and Methods
Apparatus
The Proshockice apparatus (PromoItalia Group S.p.A, Naples, Italy) used in this study emits shock waves at a variable frequency (1 to 16 Hz), at a pressure variable from 50 to 500 Bar, and with impulses that have a duration of 8 ms. The temperature for cryolipolysis is variable, from ?5 down to -5C. The Proshockice device also is equip-ped with two probes: the Freezing Probe, which can be aimed at localized fat and can be used for vasoconstriction to accomplish vascular gymnastics, and the Shock Probe, which works on the fibrous component of fat and cellulite [32–35]. The use of the Proshockice device is innovative and has been patented as a combined technology termed Ice-Shock Lipolysis, which reduces subcutaneous fat vol-ume and fibrous cellulite. For the transducer (which emits the shock waves) to transfer the waves, a conductive gel must be used (Fig. 1).
In Vivo Experiments
Patients
The study enrolled 50 patients (37 women and 13 men) 21 to 62 years of age, all with localized fat and cellulite. This
cohort of patients was divided on the basis of the areas treated: abdomen, ankles, arms, buttocks, and outer thighs. Before assessment and treatment, all the patients received explanations about the procedure, after which they read and signed an informed consent. All the patients had a screening visit that included a physical examination and blood tests.
The exclusion criteria for this study ruled out osteopo-rosis; phlebitis and thrombophlebitis; patients carrying metallic fragments, articular prostheses, and intrauterine devices or pacemakers; pregnant women; patients with reduced nervous sensibility or neurologic pathologies; patients affected by obliterating arteriopathies; and patients affected by important inflammatory processes or neoplastic diseases.
During the period of treatment, it was very important to check that the patients drank at least 2 l of water per day and followed a moderated, hyperproteic diet. None of the patients underwent other slimming or aesthetic procedures (e.g., endermology, mesotherapy, radiofrequency) during the study.
Treatment and Evaluation Protocol
Each treatment was performed according to a default pro-tocol. The duration of treatment was set, depending on the width of the area to be treated, from a minimum of 20 min to a maximum of 60 min. The treatment was performed by placing two transducers on the skin contemporaneously. In particular, the Freezing Probe was used for treating fatty tissue. Ice lipolysis was performed for 30 min in the sliding mode on the area with slow movements and with a temperature range set between 0 and -5℃. The Shock Probe was used with a conductive gel for 10 to 15 min of shock therapy.
For edematous cellulite, the Freezing Probe was used for 5 min of ice lypolysis (vascular gymnastic rather than apoptosis), and then the Shock Probe was used for a further 5 min of shock therapy. The cycle of ice lipolysis and shock therapy was repeated four times (20 min per side).
Finally, for fibrous cellulite, the Shock Probe and the Freezing Probe were used for 10 min of shock therapy and ice lipolysis (to create a lipolytic effect). The alternation of ice lipolysis and shock therapy was carried out for 30 min per side. The maximum total time was 1 h.
At least 15 days elapsed between sessions to guarantee hepatic recovery, even in the case of an eventual presence of pathologies in a subclinical phase. The evaluation period lasted 8 consecutive weeks at the frequency of one session every 15 days, for a mean total of 3.73 sessions. Before the start of the treatment program and at the end of the treat-ment, each subject’s height and weight were recorded, and perimetric measurements and photos were taken of the area treated. The perimetric measurements were performed with the patients standing up, feet apart often at the same dis-tance, height marked from the floor up to the area of concern, and measurements taken just below the marking, making sure that the measuring tape was parallel to the floor. The photos were taken with the subject standing up, feet apart often at the same distance; camera distance from the subject always the same; camera height, angle, and focal length often the same; light always the same, with four flashlights in slave mode (2 behind the subject and 2 on either side of the camera); and four photos taken during each evaluation period (1 of the front, 1 of the back, and 1 each of the right and left sides).
Evaluation by the Surgeons and the Patient
The patients were examined by two surgeons not involved in the treatment. The follow-up period was 12 months, and the method of posttreatment evaluation was standardized. Clinical results were documented by pre- and postoperative digital photos. Results were evaluated at the end of the follow-up period by the operating surgeons, by the patients themselves, and by an independent medical observer.
The patient evaluation was obtained by a questionnaire with a scale of 0 to 5. A subjective evaluation of the skin’s compactness, the volumetric reduction of fat, the patient’s comfort, and the patient’s satisfaction with the outcome of the treatment was requested.
Pinch Test
Body fat was estimated by measuring skinfold thickness according to the guidelines published by the International Society for the Advancement of Kinanthropometry (ISAK). The measurement was performed at the level of the treated areas, and the pinch test was performed immediately before and after treatment and at the end of the follow-up period.
For the pinch test, the tester pinches the skin at the appropriate site to raise a double layer of skin and the underlying adipose tissue but not the muscle. The calipers are then applied 1 cm below and at right angles to the pinch, and a reading in millimeters is taken 2 s later. The mean of two measurements should be taken. If the two measurements differ greatly, a third measurement should be performed, with the median value taken.
Laboratory Evaluations
Hematic levels of cholesterol and triglycerides were constantly verified with specific reference to the low-density lipoprotein (LDL) and high-density lipoprotein (HDL) cholesterol. In particular, samples were obtained 24 h before the beginning of the first session, immediately afterward (within 12 h), after 72 h, and after 7 days. An evaluation of hepatic markers (aspartate aminotransferase [AST]/glutamic-oxaloacetic transaminase [GOT], alanine aminotransferase [ALT]/glutamic-pyruvic transaminase [GPT], gamma-glutamyltranspeptidase [gamma-GT], total bilirubin, and albumin) was carried out before the beginning of the treatment, immediately afterward (within 12 h), after 72 h, after 7 days, and 15 days after the last session.
In Vitro Experiments
Histologic Staining and Immunohistochemistry
Skin biopsies were obtained by lipectomy rather than lip-oaspiration to avoid any mechanical damage. Biopsies were taken from the region treated (right) and control biopsies from the region untreated (left) in the areas of interest: abdomen, ankles, arms, and buttocks. Biopsies were subdi-vided into two parts and either fixed in formalin or stored at -80℃. Tissues fixed in formalin were dehydrated in alco-hol, clarified in xylene, and paraffin-embedded. Sections (5 lm thick) were stained with hematoxylin-eosin and Mallory’s trichrome stain and observed using light micros-copy (Olympus BX41, Tokyo, Japan). Immunohistochemi-cal analyses were performed with a Dako Cytomation kit (En Vision + System-HRP-AEC, Dako Italia, Milan, Italy) according to the manufacturer’s protocol. The antibodies used were anti-laminin and anti-type 4 collagen, all pur-chased from AbCam (Cambridge, UK). The remaining biopsies, kept at -80℃, were sectioned using a cryostat and stained with Oil Red-O, which can identify neutral fats, avoiding histologic artifacts.
Statistical Analysis
Differences were evaluated by the Wilcoxon test for paired continuous variables. The software used for statistical analysis was SPSS (SPSS, Chicago 17.0). A p value less than 0.05 was considered statistically significant.
Result
In Vivo Experiments
Clinical Study
The characteristics of the patients and the measurement data are summarized in Table 1. A total of 50 patients completed the study. The areas treated were the abdomen (14 patients), the thighs (18 patients), the arms (8 patients), the buttocks (6 patients), and the ankles (4 patients). Except for the patients treated in the abdominal area, all the patients had bilateral treatments at each session. All the patients resumed normal activities at completion of the sessions.
The median reduction in fat circumference at the end of the treatment was 6.86 cm for the abdomen, 5.78 cm for the thighs, 2.75 cm for the arms, 5 cm for the buttocks, and 2.25 cm for the ankles (Fig. 2a). The final reduction in fat thickness was significant compared with the measurement
before the treatment (z =-5.384; p<0.0001). The greatest reductions were observed in the thighs and in the abdomen, whereas the ankles showed the least reduction. The final reduction of fat thickness correlated positively with the baseline fat measurement.
Using a pinch test, we confirmed that the fat-thickness reduction at the end of the treatment was 4.50 cm for the abdomen, 3.60 cm for the thighs, 2.10 cm for the arms, 4 cm for the buttock, and 1 cm for the ankles (Fig. 2b). No statistically significant difference in fat-thickness reduction between the men and the women was observed. In the subjects treated for fibrous cellulite, besides the reduction in centimeters, a modification of the cutaneous aspect with an attenuation of the “orange peel” skin effect was observed.
Interestingly, body weight remained constant throughout the treatment for all the patients, strongly suggesting that the fat-thickness reduction was due to the treatment. Improvements in body contour were visibly appreciable in all the patients at the end of the treatment, as supported also by the data from the subjective evaluations, which always showed a clear satisfaction of all the patients treated (score of 4 or 5).
The procedure was well tolerated by all the patients. Figure 3a depicts an example of body contouring, and Fig. 3b shows an example of body contouring after 12 weeks (Fig. 3a and b). Another example of body con-touring is depicted in Fig. 3c–e. A clinically apparent reduction in the fat layer can be noted.