Aesthetic Plastic Surgery© The Author(s) 200810.1007/s00266-008-9262-3
Lipolysis Using a 980-nm Diode Laser: A Retrospective Analysis of 534 Procedures
Cemaform-Spherligne, c/o Clinique Saint-Michel, Avenue d’Orient, 83100 Toulon, France
Osyris, Osyris SA, Hellemmes, France
INSERM U 703, Pavillon Vancostenobel, Lille University Hospital, 59037 Lille Cedex, France
Received: 11 July 2008Accepted: 10 October 2008Published online: 30 October 2008
The safety and efficacy of the 980-nm diode laser for laser lipolysis were evaluated in different body areas.
From June 2005 to June 2007, 334 subjects underwent laser lipolysis. The treatment was performed using a 980-nm diode laser (OSYRIS, Hellemmes, France). After tumescent anesthesia, a 1-mm-diameter microcannula housing a 600-μm optical fiber was inserted into the subcutaneous fat. The cannula was moved back and forth in a predetermined manner to get a homogeneous distribution of energy at the treated area. Laser settings (power and cumulative energy) were selected in relation to individual body areas: 6 W (chin, arm, knee), 10 W (abdomen, back), and 15 W (thigh, hips, buttock). Patient satisfaction was evaluated and side effects were recorded. The laser energy counter incrementally counted the energy used; then the cumulative energy used for each treatment was recorded. Ultrasound imaging was used to control tumescent anesthesia infiltration, cannula position prior to laser emission,and postoperative fat liquefaction.
Five hundred thirty-four (534) laser lipolysis procedures were performed on 334 patients. Different areas were treated: hips (197), inner thighs (86), abdomen (86), knees (61), flanks (57), buttocks (28), chin (22), arms (18), back (4). Mean cumulative energy was area–dependent, ranging from a minimum of 2200 J (knee) to a maximum of 51,000 J (abdomen). Contour correction and skin retraction were observed almost immediately in most patients. There was no scarring, infection, burns, hypopigmentation, bruising, swelling, or edema. Ecchymoses were observed in almost all patients but resolved in under 1 week for 322 patients. Patient satisfaction was very high. Because laser lipolysis is an outpatient procedure, patients were able to resume normal daily activities after 24 h. Ultrasound imaging confirmed that the thermal effect generated by the laser results in melting and rupture of the collagenous and subdermal bands.
This clinical study demonstrates that the removal of small volumes of fat with concurrent subdermal tissue contraction can be performed safely and effectively using a 980-nm diode laser. Additional benefits include excellent patient tolerance and quick recovery time. This study also confirms that enough accumulated energy must be delivered to achieve sufficient lipolysis throughout different fat layers.
KeywordsLaser lipolysis Diode laser, 980 nm Adipocyte Fat
Liposuction has become increasingly popular over the last decade and now stands among the most popular body-sculpting procedures. This increasing popularity is associated with the evolution of techniques and equipment for fat removal and body reshaping. Besides traditional suction-assisted lipoplasty, other options include ultrasound-assisted and external ultrasound-assisted liposuction, power-assisted liposuction, and laser lipolysis. Efforts in the search for alternatives and new tools primarily seek to reduce downtime, decrease operator fatigue, reduce bleeding, and promote skin contraction.
Widely used in Europe and Latin America, laser lipolysis (also called laser lipoplasty) was introduced in North America in 1994 [1, 2]. Laser lipolysis with a pulsed 1064-nm Nd:YAG laser has proven to be safe and effective. After adequate infiltration of an anesthetic solution, a flexible optical fiber is inserted via a small-caliber cannula into the fat tissue. Transillumination from a red aiming beam makes the 1-mm cannula easy to see. Laser energy is transmitted to and absorbed by the adipocytes, leading to volume expansion and rupture . Histologic analyses of the effects of pulsed Nd:YAG lasers on human fat tissue have shown areas of reversible cellular damage (tumefaction), irreversible tissue damage (lysis), and a reduction in bleeding when compared to conventional liposuction.
The mechanisms leading to laser lipolysis are temperature-dependent. First, at low energy and consequently low temperature, only tumefaction of adipocytes is observed . As carried out by Goldman  on tissues removed immediately after the procedure, at higher energy levels histologic assessment showed adipocytic membrane rupture as well as coagulation of small vessels in the fatty tissue .
More importantly, the incidence of tumefaction and lysis varies proportionally to the intensity of energy accumulated in the target. Badin et al.  showed that conventional liposuction produces less reversible damage (tumefaction) than laser lipolysis with 1000 J of energy. At energy levels ranging from 1000 J up to 12,000 J, Kim and Geronemus observed a direct correlation between energy levels and volume reduction. Typically, 3000 J leads to a 5-cm3 reduction in fat volume and a 20-cm3 volume reduction is obtained with 12,000 J. These clinical observations have been confirmed through mathematical modeling of laser lipolysis .
This study aimed to present a retrospective analysis on 334 patients (534 treated areas) treated by laser lipolysis.
Materials and Methods
A 980-nm diode laser (Pharaon, OSYRIS, Hellemmes, France) is used in continuous emission mode. Power settings are chosen as a function of the treated area: 6 W (chin, arms, knees), 10 W (abdomen, back), and 15 W (thighs, hips, buttocks). Transcutaneous illumination by the aiming beam ensures precise visualization of the region where the energy is delivered.The laser light is conveyed into the fat layer using a 1-mm microcannula (OSYRIS) which incorporates a 600-μm optical fiber. The microcannula has been specifically designed so that its distal end is level with the fiber tip (Fig. 1). Also, the distal end is rounded to minimize potential tissue trauma resulting from the back-and-forth motion used.
OSYRIS cannula developed for laser lipolysis. The round tip avoids any damage during the back-and-forth motion
Ultrasound imaging is used to determine the volume to be treated and the thickness of the fat layer (Fig. 2). It is also used to control tumescent anesthesia infiltration, cannula position prior to laser emission, and postoperative fat liquefaction.
Ultrasound imaging probe used to determine the volume to be treated and the thickness of the fat layer
All procedures were performed in an outpatient clinic setting. After marking the treatment site with a surgical marker, patients are prepped and draped in sterile fashion. First, local anesthesia (adrenaline 1:500,000) is administered using the wet infiltration technique (Fig. 3). After infiltration of the tumescent fluid, a small incision of 1–2 mm is made with an 18-gauge needle. The 1-mm microcannula is then inserted through the incision into the subcutaneous fat (Fig. 4). During the laser lipolysis procedure, The patient and the staff wear protective eyewear.
Ultrasound image recorded during the tumescent anesthesia infiltration. The arrow shows the presence of the fluid
Position of the cannula inside the fat layer is controlled with ultrasound imaging (red arrow)
To achieve optimal lipolysis, enough energy must be cumulatively delivered throughout the different fat layers (superficial, medium, and deep) and into the subdermal plane so as to reach the collagenous layer. Furthermore, a homogeneous distribution of light energy is required to get an optimal elevation of tissue temperature into the fat layer. This can be achieved only through optimal positioning and movement of the cannula during the procedure (Fig. 5).
Position of the cannula during the laser lipolysis procedure
The protocol is as follows:
The cannula is inserted in the hypodermis.
The cannula is moved back and forth in the fat layer at a velocity of approximately 100 mm/s in a vertical plane parallel to the surface. This back-and-forth motion is repeated 10–15 times while maintaining the same horizontal plane.
After 10–15 back-and-forth motions have been completed, the cannula is moved to the adjacent area (by about 1° or so) which is treated with 10–15 back-and-forth motions. This is repeated until the entire area has been treated (Fig. 5).
To provide a homogeneous treatment of the fat layer, the cannula is inserted 120 mm from the previous insertion point so that the trajectories cross. Steps 2 and 3 are repeated.
During laser lipolysis, one hand is used to move the cannula. The other hand maintains contact with the treated area. When the cannula is forced through the adipose layer, the tip can meet resistance at the septae. The hand is then used to immobilize tissues during the back-and-forth movement of the cannula. The hand is also used to control the temperature elevation of the skin. Optimal dosage is reached when the skin feels warm to the touch. This superficial skin heating is clearly felt when the temperature reaches 40°C.
After lipolysis, liquified fat can be either aspirated with a 3-mm cannula or massaged out. Aspiration was performed in large treated volumes and in locations that were easily accessible. Massage was performed in small volumes and in areas that were not easily accessible (e.g., knees or arms). It is at this point that clinical results can be gauged by analyzing the immediate body or facial contour improvement. MicroporeTM or TensoplastTM adhesives are affixed to the skin to better compress and remodel certain areas such as the banana fold, the external thigh, and the inferolateral part of the buttocks. The tape remains in place for 1 week and compression garments should be used for 1 month. There are no restrictions to activity; sun exposure should be avoided for 1 month. Finally, the total energy delivered during the laser lipolysis procedure was recorded.
Before the procedure, patients received pain medication and an anxiolytic. After the operation, an antibiotic (Augmentin 1000, GlaxoSmithKline; 1 tablet by mouth 2 times per day morning and evening) was prescribed for 3 days.
The patients were asked to wait for a minimum of 8 days before resuming normal activities, in particular sporting activities where mechanical shocks could be experienced. Physiotherapy sessions were sometimes prescribed (mainly when no aspiration was performed) to get better elimination of fat. They were proposed a few days after the procedure.
For each patient, age and sex were recorded. Contraindications to enrollment were as follows: pregnancy, bleeding disorders; immune deficits; heart, liver, and kidney insufficiency; allergies to local anesthetics; pacemaker and serious heart rhythm disorders; psychiatric disorders; unstable motivations; large fat volumes; and obesity.
All patients were informed about the purpose of the study and signed consent for the described procedure to be performed. Patients were seen at baseline, 1 week, 1 month, and 3 months postprocedure. At each visit, they were weighed, photographed, and clinically assessed. Patient satisfaction was recorded using a scale of 1 to 4 (1 = not satisfied, 2 = less satisfied, 3 = satisfied, 4 = very satisfied). Side effects, discomfort, any observed change, or adverse events were recorded.
Since June 1, 2005, 334 patients [296 females aged 18–71 years (average = 43.6 years) and 7 males aged 18–49 (average = 36.9 years)] underwent laser lipolysis. None of the patients had undergone any previous treatments for fat reduction. Five hundred thirty-four laser lipolysis procedures were performed on these 334 patients. Different locations were treated: hips (197): inner thighs (86), abdomen (86), knees (61), flanks (57), buttocks (28), chin (22), arms (18), and back (4). Aspiration was performed after 399 procedures (75%). A massage was systematically performed on the remaining 25% at the end of the procedure. Fluid emulsion (mixture of lysed fat and tumescent anesthesia) leaks were sometimes observed from the cannula hole during the massage. Table 1 summarizes the mean energy used for each location and the mean tumescent fluid infiltration.
Mean energy and mean tumescent fluid infiltration used for each location
No. procedures (534)
No. patients (334)
Total energy (J)
Tumescent infiltration (ml)
Both contour correction and skin retraction were observed almost immediately in most patients. There was no scarring, infection, burns, hypopigmentation, bruising, swelling, or edema. Ecchymoses were observed in almost all patients but were resolved in under 1 week in 322 patients. Only ten patients reported ecchymoses lasting 2 weeks and two patients reported ecchymoses lasting 3 weeks.
Because laser lipolysis was performed as an outpatient procedure, patients were able to return to normal daily activities after the first postoperative day. Pain and discomfort were evaluated at 1 week, 1 month, and 3 months. At 1 week, 83% reported no pain/discomfort and 17% reported mild pain/discomfort. At 1 month, mild pain/discomfort was reported by 5%. At 3 months, only three patients reported discomfort due to paresthesia. For these three patients, the paresthesia seem to be induced by microecchymoses due to sporting activities resumed too quickly. One necrosis was observed in one patient next to the navel in an area where several laparoscopic procedures had been previously performed. The tissue would be more fragile at the point of entry of these examinations.
Fifty-eight percent of patients were very satisfied with the results of the laser lipolysis procedure, 22% were satisfied, and 18% were less satisfied. Only 2% were not satisfied at all (Fig. 6). Figures 7 and 8 show clinical results obtained after laser lipolysis.
Patient satisfaction rate after one laser lipolysis procedure
Patient before and at 6-month follow-up. For the 980-nm diode laser, power = 6 W; cumulative energy = 7600 J
Patient before and at 6-month follow-up. For the 980-nm diode laser, power = 15 W; cumulative energy = 24,750 J (right side) and 25,500 J (left side)
There was no difference in postoperative problems between aspiration and massage patients. Results in terms of volume reduction were observed sooner (1–2 months) after aspiration. When there was no aspiration, results were usually observed later (4–8 months).
Data recorded during the 534 procedures allowed for a calculation of the mean cumulative energy applied for each location: 8,100 J for the knee, 14,600 J for the hip, 10,400 J for the inner thigh, 11,700 J for the chin, 12,800 J for the arm, 13,100 J for the buttock line, 14,600 J for the hip, 21,900 J for the back, and 24,600 J for the abdomen (Fig. 9).
Cumulative energy used for each location
Because of the laser’s interaction with collagenous and subdermal bands, ultrasound imaging has confirmed that a thermal effect is obtained that results in melting and rupturing of the bands (Fig. 10a, b). This contributes to liberating previously retracted skin and remodeling collagenous tissue, with clinically evident skin retraction. This can be clearly seen on ultrasound images when comparing before and after images.
a Before laser lipolysis: collagenous and subdermal bands are clearly seen. b After laser lipolysis: melting of collagenous and subdermal bands is observed
Laser lipolysis is a new technique still under development. The main objectives of this technique are quicker recovery, reduced operator fatigue, and concurrent skin contraction . The use of the Nd:YAG laser as an auxiliary tool has refined the traditional lipoplasty technique. Badin et al.  reported its utility in lipolysis of the upper abdomen and periumbilical region. The Nd:YAG laser was first proposed because of the deep penetration of its 1064-nm wavelength. However, diode lasers, which can typically emit at 810, 940, and 980 nm, may offer an alternative. While in the same spectral region, their wavelengths offer the inherent benefits of diode technology, namely, better efficiency (usually 30%) and high power outputs (25 W or more).
Laser-tissue interaction is achieved through absorption of laser energy by receptive chromophores, producing sufficient heat to cause the desired thermal damage. The heat acts on the fatty cells and on the extracellular matrix to produce both reversible and irreversible cellular damage. In our study, at low-energy settings and for both 980- and 1064-nm wavelengths, reversible damage was confirmed by the tumefaction of adipocytes. An increase in their diameter of up to 100 μm was observed. The heat generated by the laser would alter the balance of sodium and potassium of the cellular membrane, allowing the free transport of extracellular liquid to the intracellular atmosphere. This observation is in agreement with that of Badin et al.  who used an Nd:YAG laser. They observed that the average diameter of adipocytes was 95.69 μm after lipolysis compared with an average diameter of 73.48 μm for adipocytes in their normal state and a diameter of 85.54 μm for adipocytes after conventional liposuction. Several articles have confirmed that the Nd:YAG laser developed by the company Deka (Manchester, NH) and sold in the U.S. by Cynosure (Westford, MA) does not act mechanically. A recent article by Khoury et al.  compared the mechanisms of action of three different wavelengths (1.06, 1.32, and 2.1 μm) operating at similar modes of emission (100–300 μs, 100–666 mJ/pulse, 12–40 Hz). Those pulse widths clearly suggest that the 1064-nm lasers used for lipolysis are not Q-switched. Furthermore, the hypothesis that the mechanism of laser lipolysis is photomechanical was not confirmed by the histologic results. Conversely, Khoury et al. showed that the mechanism of action was purely thermal. This interesting study confirmed the results of previously published articles which were further evidenced by the findings of a mathematical model backed by clinical work [5, 6, 10].
For higher-energy settings, rupture of adipocytes, coagulation of collagen fiber, and small vessels were observed. This was demonstrated in a recent article by Mordon et al. . These observations are in accordance with the histologic study carried out by Goldman  on tissues removed immediately following the procedure and on biopsies taken approximately 40 days following the procedures. These biopsies showed the coagulation of small vessels in the fatty tissue, the rupture of adipocytes, the appearance of small channels produced by laser action, reorganization of the reticular dermis, and coagulation of collagen in the fat tissue. Due to the rupture of the membrane, lipases liberated by the adipocyte are responsible for the liquefaction of the tissue, which further facilitates the subsequent aspiration. Through the liquefactive effect of the laser, the fat is loosened without the abrupt and repetitive back-and-forth motion of the cannula as performed in the conventional liposuction technique. The fact that heat also induces coagulation of small vessels in fat tissues is very important as this phenomenon will facilitate liposuction with reduced trauma and bleeding. Liposuction removes significant amounts of fat, serum, and blood. In cases in which large amounts of fatty tissue are to be removed, a physiologically significant loss of blood can provoke metabolic alterations. Laser-assisted liposuction offers the advantage of removing larger volumes of fat without hemodynamic repercussions .
It remains difficult to compare the parameters used in this clinical study to those usually reported in the literature, because in most of the other studies the cumulative energy used to treat a given volume is usually not reported. Prado et al.  used a Nd:YAG laser and applied 400 J in the submental zone. Key  performed submental laser lipolysis with a 1320-nm laser using a cumulative energy of 560–1040 J. However, for these two clinical studies, the reduction of the fat volume was not reported. Using magnetic resonance imaging before laser lipolysis and at 3 months follow-up, Kim and Geronemus  determined the fat volume reduction of the submentum. In the submental zone, approximately 3000 J was applied to get a mean volume reduction of 5.2 ± 2.8 cm3. Similarly, in a recent article, Mordon et al.  also quantified the fat volume reduction in the submental zone using 3D photography. They found a similar reduction of 10 ± 1 cm3 for a total energy application of 6600 J. Total energy reported in our clinical study depends on the location of the treated area. It varied from 8100 J for the knee to a maximum of 24,600 J for the abdomen. The highest cumulative energy reported in this clinical study was 51,000 J for the abdomen. When compared to previous published studies, the cumulative energy reported in this study is much higher. However, as suspected by Kim and Geronemus , it is evident that the subjects treated in the early studies were actually undertreated, with insufficient total cumulative energy delivered at the treatment site. This is likely attributable to the initial learning curve of this novel procedure.
The highest cumulative energy in our study of 51,000 J corresponds to a 72-cm3 volume reduction, confirming that laser lipolysis should be used only to reduce volumes by less than 100 cm3 as previously stated .
Laser lipolysis with the 980-nm diode laser was demonstrated to be less traumatic than conventional liposuction methods. The primary reasons for this are the small-diameter (1 mm) cannula and the effects of the laser interacting with tissue. There are other hypotheses made to explain reduced pain, the absence of bruising and edema, and the faster recovery associated with laser lipoplasty. One could be that the laser seals lymphatic and arteriovenous vessels . The absence of bleeding is a very important issue. In a clinical report on submental Nd:YAG laser lipolysis on 82 patients, Goldman  histologycally observed the coagulation of small blood vessels in the fatty tissue and the rupture of adipocytes.
The interaction between the laser and the biological tissue produces a fat volume reduction and a remodeling of the collagenous tissue, with clinically evident skin contraction as can be observed immediately after the procedure. In our study, ultrasound imaging clearly showed that a thermal effect is obtained after laser lipolysis which results in the melting and rupturing of collagenous and subdermal bands. The wound repair that follows the laser treatment leads to the creation of new collagen and elastin fibers and subsequent tissue contraction. This phenomenon is confirmed by Badin et al.  who observed after histologic analysis that the collagen denaturation performed in the deep reticular dermis and the conjunctive septum of the subcutaneous tissue constituted a proinflammatory stimulant followed by vascular proliferation and collagen neosynthesis. Finally, the resulting skin contraction observed on patients confirms these claims and is in accordance to previous clinical studies [8, 13].
This clinical study demonstrates that the removal of small volumes of fat with concurrent subdermal tissue contraction can be safely and effectively performed using a 980-nm diode laser. Additional benefits include excellent patient tolerance and quick recovery time. This study also confirms that enough accumulated energy must be delivered in order to achieve sufficient lipolysis throughout different fat layers.
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