Sydney R. Coleman

Long-Term survival of fat transplants: Controlled demonstrations

To document the amount and rate of re-absorption of fatty tissue transplanted using the authors technique, the author initiated controlled studies in 1987. A selected crease was infiltrated with autologous fatty tissue using a nearby crease as control. At specific time intervals the infiltrated crease was compared to the nearby control crease to evaluate percentage of recurrence. Photographs were taken in the first week, then at least yearly over six years. All views, all positions of the mouth, and all lighting situations demonstrated the continued absence of any crease in the area of infiltration. In contrast, the nearby control crease remained unchanged or deepened from its preoperative condition, giving every indication of a permanent correction. This experiment demonstrates the potential lasting nature of corrections performed with the transplantation of fatty tissue and is supported by over 400 infiltrations into the nasolabial folds in the authors practice.

Fat grafting to the breast revisited : Safety and efficacy

Background: A 1987 American Society of Plastic and Reconstructive Surgeons position paper predicted that fat grafting would compromise breast cancer detection and should therefore be prohibited. However, there is no evidence that fat grafting to breasts is less safe than any other form of breast surgery. As discussions of fat grafting to the breast are surfacing all over the world, it is time to reexamine the opinions of the 1987 American Society of Plastic and Reconstructive Surgeons position paper. Methods: This is a retrospective examination of 17 breast procedures performed using fat grafting from 1995 to 2000. Indications included micromastia, postaugmentation deformity, tuberous breast deformity, Polands syndrome, and postmastectomy reconstruction deformities. The technique used was the Coleman method of fat grafting, which attempts to minimize trauma and place grafted fat in small aliquots at many levels. Results: All women had a significant improvement in their breast size and/or shape postoperatively and all had breasts that were soft and natural in appearance and feel. Postoperative mammograms identified changes one would expect after any breast procedure. Conclusions: Given these results and reports of other plastic surgeons, free fat grafting should be considered as an alternative or adjunct to breast augmentation and reconstruction procedures. It is time to end the discrimination created by the 1987 position paper and judge fat grafting to the breast with the same caution and enthusiasm as any other useful breast procedure.

The Anatomy of the Aging Face: Volume Loss and Changes in 3-Dimensional Topography

Facial aging reflects the dynamic, cumulative effects of time on the skin, soft tissues, and deep structural components of the face, and is a complex synergy of skin textural changes and loss of facial volume. Many of the facial manifestations of aging reflect the combined effects of gravity, progressive bone resorption, decreased tissue elasticity, and redistribution of subcutaneous fullness. A convenient method for assessing the morphological effects of aging is to divide the face into the upper third (forehead and brows), middle third (midface and nose), and lower third (chin, jawline, and neck). The midface is an important factor in facial aesthetics because perceptions of facial attractiveness are largely founded on the synergy of the eyes, nose, lips, and cheek bones (central facial triangle). For aesthetic purposes, this area should be considered from a 3-dimensional rather than a 2-dimensional perspective, and restoration of a youthful 3-dimensional facial topography should be regarded as the primary goal in facial rejuvenation. Recent years have seen a significant increase in the number of nonsurgical procedures performed for facial rejuvenation. Patients seeking alternatives to surgical procedures include those who require restoration of lost facial volume, those who wish to enhance normal facial features, and those who want to correct facial asymmetry. Important factors in selecting a nonsurgical treatment option include the advantages of an immediate cosmetic result and a short recovery time.

Autologous fat grafts harvested and refined by the Coleman technique: a comparative study.

Background: The viability of fat grafts obtained by even a well-established technique remains poorly studied and unknown. This study was designed to determine the viability of fat grafts harvested and refined by the Coleman technique. Methods: Sixteen adult white women were enrolled in this study. In group 1 (n = 8), fat grafts were harvested and processed with the Coleman technique by a single surgeon from the abdomen of each patient according to his standardized method. In group 2 (n = 8), fat grafts were harvested with the conventional liposuction by another surgeon. After centrifugation, the resulting middle layer of tissue was collected. All fat graft samples were analyzed for the following studies: trypan blue vital staining for viable adipocyte counts, glycerol-3-phophatase dehydrogenase assay, and routine histologic examination. Results: The higher viable adipocyte counts were found in group 1 compared with group 2 (4.11 ± 1.11 versus 2.57 ± 0.56 × 106 cells/ml; p < 0.004). The level of glycerol-3-phophatase dehydrogenase activity was significantly higher in group 1 compared with group 2 (0.66 ± 0.09 versus 0.34 ± 0.13 U/ml; p < 0.0001). Histologic examination showed normal structure of fragmented fatty tissues in both groups. Conclusions: Although fat grafts obtained by both methods maintain normal histologic structure, the Coleman technique yields a greater number of viable adipocytes and sustains a more optimal level of cellular function within fat grafts and should be considered superior to conventional liposuction as a preferred method of choice for fat graft harvesting.

Structural fat grafting.

The site selected to harvest the fat does not seem to affect the outcome; therefore I let the patients choose, or I use whatever site is most convenient. A 2-mm diameter (15 or 23 cm length) blunt cobra cannula is used so the fat is harvested in small parcels, as globules—with the idea that it will fit through the aperture of a 10-mL Luer-Lok® syringe (Becton/Dickerson [B-D®], Franklin, NJ). Fat harvested with a large cannula (eg, 9 mm) may not survive the mechanical trauma of being forced through the lumen of a small cannula during placement. Some surgeons use a syringe that results in a very high harvest pressure. I just pull back the 1-mL marker on the 10-mL syringe and maintain gentle suction as fat accumulates. I almost always use epidural or local anesthesia for harvesting. The local area is infiltrated with Ringers lactate, 1:400,000 epinephrine. When using local anesthetic alone, I use 0.5% lidocaine with 1:200,000 epinephrine, infiltrated at a ratio of 1 to 1 for the planned harvest. …

Avoidance of arterial occlusion from injection of soft tissue fillers

In recent years, several cases of blindness, stroke, and skin necrosis have occurred after injection of soft tissue fillers. To avoid such complications, the author recommends using larger, blunt cannulas and epinephrine at the injection site, while avoiding the injection of large boluses of soft tissue filler in the face. (Aesthetic Surg J 2002;22:555-557.).

Fat grafting accelerates revascularisation and decreases fibrosis following thermal injury

BACKGROUND Fat grafting has been shown clinically to improve the quality of burn scars. To date, no study has explored the mechanism of this effect. We aimed to do so by combining our murine model of fat grafting with a previously described murine model of thermal injury. METHODS Wild-type FVB mice (n=20) were anaesthetised, shaved and depilitated. Brass rods were heated to 100°C in a hot water bath before being applied to the dorsum of the mice for 10s, yielding a full-thickness injury. Following a 2-week recovery period, the mice underwent Doppler scanning before being fat/sham grafted with 1.5cc of human fat/saline. Half were sacrificed 4 weeks following grafting, and half were sacrificed 8 weeks following grafting. Both groups underwent repeat Doppler scanning immediately prior to sacrifice. Burn scar samples were taken following sacrifice at both time points for protein quantification, CD31 staining and Picrosirius red staining. RESULTS Doppler scanning demonstrated significantly greater flux in fat-grafted animals than saline-grafted animals at 4 weeks (fat=305±15.77mV, saline=242±15.83mV; p=0.026). Enzyme-linked immunosorbent assay (ELISA) analysis in fat-grafted animals demonstrated significant increase in vasculogenic proteins at 4 weeks (vascular endothelial growth factor (VEGF): fat=74.3±4.39ngml(-1), saline=34.3±5.23ngml(-1); p=0.004) (stromal cell-derived factor-1 (SDF-1): fat=51.8±1.23ngml(-1), saline grafted=10.2±3.22ngml(-1); p<0.001) and significant decreases in fibrotic markers at 8 weeks (transforming growth factor-ß1(TGF-ß): saline=9.30±0.93, fat=4.63±0.38ngml(-1); p=0.002) (matrix metallopeptidase 9 (MMP9): saline=13.05±1.21ngml(-1), fat=6.83±1.39ngml(-1); p=0.010). CD31 staining demonstrated significantly up-regulated vascularity at 4 weeks in fat-grafted animals (fat=30.8±3.39 vessels per high power field (hpf), saline=20.0±0.91 vessels per high power field (hpf); p=0.029). Sirius red staining demonstrated significantly reduced scar index in fat-grafted animals at 8 weeks (fat=0.69±0.10, saline=2.03±0.53; p=0.046). CONCLUSIONS Fat grafting resulted in more rapid revascularisation at the burn site as measured by laser Doppler flow, CD31 staining and chemical markers of angiogenesis. In turn, this resulted in decreased fibrosis as measured by Sirius red staining and chemical markers.

The Current State of Fat Grafting: A Review of Harvesting, Processing, and Injection Techniques.

Background: Interest in and acceptance of autologous fat grafting for use in contour abnormalities, breast reconstruction, and cosmetic procedures have increased. However, there are many procedural variations that alter the effectiveness of the procedure and may account for the unpredictable resorption rates observed. Methods: The authors highlighted studies investigating the effects of harvesting procedures, processing techniques, and reinjection methods on the survival of fat grafts. This review focused on the impact different techniques have on outcomes observed in the following: in vitro analyses, in vivo animal experiments, and human studies. Results: This systemic review revealed the current state of the literature. There was no significant difference in the outcomes of grafted fat obtained from different donor sites, different donor-site preparations, harvest technique, fat harvesting cannula size, or centrifugation speed, when tumescent solution was used. Gauze rolling was found to enhance the volume of grafted fat, and no significant difference in retention was observed following centrifugation, filtration, or sedimentation in animal experiments. In contrast, clinical studies in patients found more favorable outcomes with fat processed by centrifugation compared with sedimentation. In addition, higher retention was observed with slower reinjection speed and when introduced into less mobile areas. Conclusions: There has been a substantial increase in research interest to identify methodologies for optimizing fat graft survival. Despite some differences in harvest and implantation technique in the laboratory, these findings have not translated into a universal protocol for fat grafting. Therefore, additional human studies are necessary to aid in the development of a universal protocol for clinical practice.

Human fat grafting alleviates radiation skin damage in a murine model.

Background: Autogenous fat grafting has been observed to alleviate the sequelae of chronic radiodermatitis. To date, no study has replicated this finding in an animal model. Methods: The dorsa of adult wild-type FVB mice were shaved and depilated. The dorsal skin was then distracted away from the body and irradiated (45 Gy). Four weeks after irradiation, 1.5-cc fat or sham grafts were placed in the dorsal subcutaneous space. Gross results were analyzed photometrically. The animals were euthanized at 4 and 8 weeks after fat or sham grafting and their dorsal skin was processed for histologic analysis. Results: Hyperpigmentation and ulceration were grossly improved in fat-grafted mice compared with sham-grafted controls. This improvement manifested histologically in a number of ways. For example, epidermal thickness measurements demonstrated decreased thickness in fat-grafted animals at both time points (20.6 ± 1.5 &mgr;m versus 55.2 ± 5.6 &mgr;m, p = 0.004; 17.6 ± 1.1 &mgr;m versus 36.3 ± 6.1 &mgr;m, p = 0.039). Picrosirius red staining demonstrated a diminished scar index in fat-treated animals at both time points as well (0.54 ± 0.05 versus 0.74 ± 0.07, p = 0.034; and 0.55 ± 0.06 versus 0.93 ± 0.07, p = 0.001). Conclusion: Fat grafting attenuates inflammation in acute radiodermatitis and slows the progression of fibrosis in chronic radiodermatitis.

Fat Grafting for Facial Filling and Regeneration

Plastic surgeons have come to realize that fat grafting can rejuvenate an aging face by restoring or creating fullness. However, fat grafting does much more than simply add volume. Grafted fat can transform or repair the tissues into which it is placed. Historically, surgeons have hesitated to embrace the rejuvenating potential of fat grafting because of poor graft take, fat necrosis, and inconsistent outcomes. This article describes fat grafting techniques and practices to assist readers in successful harvesting, processing, and placement of fat for optimal graft retention and facial esthetic outcomes.