Long-term outcome of adipose-derived regenerative cell-enriched autologous fat transplantation for reconstruction after breast-conserving surgery for Japanese women with breast cancer.

PURPOSE: More effective methods are needed for breast reconstruction after breast-conserving surgery for breast cancer. The aim of this clinical study was to assess the perioperative and long-term outcomes of adipose-derived regenerative cell (ADRC)-enriched autologous fat grafting. METHODS: Ten female patients who had undergone breast-conserving surgery and adjuvant radiotherapy for breast cancer were enrolled. An ADRC-enriched fat graft prepared from the patient's adipose tissue was implanted at the time of adipose tissue harvest. The perioperative and long-term outcomes of the grafts, which included safety, efficacy, and questionnaire-based patient satisfaction, were investigated. RESULTS: The mean operation time was 188 ± 30 min, and the mean duration of postoperative hospitalization was 1.2 ± 0.4 days. No serious postoperative complications were associated with the procedure. Neither recurrence nor metastatic disease was observed during the follow-up period (7.8 ± 1.5 years) after transplantation. Of 9 available patients, "more than or equal to average" satisfaction with breast appearance and overall satisfaction were reported by 6 (66.7%) and 5 (55.6%) patients, respectively. CONCLUSIONS: ADRC-enriched autologous fat transplantation is thus considered to be safe perioperatively, with no long-term recurrence, for patients with breast cancer treated by breast-conserving surgery, and it may be an option for breast reconstruction, even after adjuvant radiotherapy.

Oncologic risks of autologous fat grafting to the breast.

As the frequency of fat grafting to the breast has increased, some investigators have raised the possibility that this procedure may potentially increase the risks associated with breast cancer. Their concerns included not only interference with cancer detection, but also promotion of tumor formation or recurrence mediated by mechanisms such as aromatase expression, angiogenesis, and tumor stromal cells. However, published clinical studies describing outcomes of fat grafting to the breast in more than 2000 patients have not reported any increase in new or recurrent cancers. The reason for this apparent disconnect may lie in the small sample sizes and relatively short follow-up, but it may also reside in the considerable gap between laboratory studies or theoretical considerations suggesting potential risks and the actual clinical practice. This review discusses potential risks of current and novel approaches to autologous fat grafting to the breast within the context of both the underlying science and clinical practice.

Automated isolation and processing of adipose-derived stem and regenerative cells.

The popularity of nonhematopoietic, adult tissue-derived stem and progenitor cells for use as a cellular research tool, and ultimately as a clinical therapeutic, has increased exponentially over the past decade. Almost all adult-derived stem/progenitor cells (autologous and allogeneic), with one exception, require at least some ex vivo expansion or further manipulation prior to use to satisfy efficacy and safety requirements for preclinical or clinical use. The principal reason is the relatively low frequency of these therapeutically valuable cells within any given adult tissue, except for adipose tissue, which has been shown to have at least two log greater concentrations of these progenitor cells. Therefore, use of autologous adipose-derived cells as both a research tool and cell therapeutic is feasible and has been shown to be both safe and efficacious in preclinical and clinical models of injury and disease. The development and utilization of automated processes and instrumentation such as Cytori Therapeutics' Celution® System to reduce variability and increase quality of the recovered cells is requisite for clinical use and preferred by basic researchers. Here, use of an automated, closed processing platform for isolation and concentration of adipose-derived stem and regenerative cells is described, including a profile of the isolated cells immediately prior to use, and commonly used methods to quantify and qualitatively assess the recovered cells.

Supplementation of fat grafts with adipose-derived regenerative cells improves long-term graft retention.

Current practice of autologous fat transfer for soft tissue augmentation is limited by poor long-term graft retention. Adipose-derived regenerative cells (ADRCs) contain several types of stem and regenerative cells, which may help improve graft retention through multiple mechanisms. Using a murine fat transplantation model, ADRCs were added to transplanted fat to test whether ADRCs could improve the long-term retention of the grafts. This study showed, at both 6 and 9 months after transplantation, ADRCs not only increased graft retention by 2-fold but also improved the quality of the grafts. ADRC-supplemented grafts had a higher capillary density, indicating ADRCs could promote neovascularization. Further cell tracking and gene expression studies suggest ADRCs may promote angiogenesis and adipocyte differentiation and prevent apoptosis through the expression of various growth factors, including VEGFA and IGF-1. Taken together, these results suggest a potential clinical utility of ADRCs in facilitating autologous fat transfer for soft tissue augmentation.

Adipose tissue-derived cells improve cardiac function following myocardial infarction.

BACKGROUND: Adipose tissue consists of mature adipocytes and a mononuclear cell fraction termed adipose tissue-derived cells (ADCs). Within these heterogeneous ADCs exists a mesenchymal stem cell-like cell population, termed adipose tissue-derived stem cells. An important clinical advantage of adipose tissue-derived stem cells over other mesenchymal stem cell populations is the fact that they can be isolated in real time in sufficient quantity, such that ex vivo expansion is not necessary to obtain clinically relevant numbers for various therapeutic applications. MATERIALS AND METHODS: The aim of this investigation was to evaluate the therapeutic potential of freshly isolated ADCs in treating rats acutely following myocardial infarction. Rats underwent 45 min of left anterior descending artery occlusion followed by reperfusion. Fifteen minutes post-myocardial infarction, saline or 5 x 10(6) ADCs from green fluorescent protein-expressing transgenic rats were injected into the chamber of the left ventricle. Left ventricular function and morphometry was followed with 2-D echocardiography for 12 wk, at which point hearts were harvested for histological analysis. RESULTS: Twelve weeks following cell therapy, left ventricular end-diastolic dimension was less dilated while the ejection fraction and cardiac output of ADC-treated rats were significantly improved compared to control rats (P < 0.01). Despite this benefit, absolute engraftment rates were low. This paradox may be partially explained by ADC-induced increases in both capillary and arteriole densities. CONCLUSIONS: These data confirm the therapeutic benefit of freshly isolated ADCs delivered post-MI and suggest a novel beneficial mechanism for ADCs through a potent proangiogenic effect.

Stem cells from human fat as cellular delivery vehicles in an athymic rat posterolateral spine fusion model.

BACKGROUND: Mesenchymal stem cells derived from human liposuction aspirates, termed processed lipoaspirate cells, have been utilized as cellular delivery vehicles for the induction of bone formation in tissue engineering and gene therapy strategies. In this study, we sought to evaluate the efficacy of bone morphogenetic protein (BMP)-2-producing adipose-derived stem cells in inducing a posterolateral spine fusion in an athymic rat model. METHODS: Single-level (L4-L5) intertransverse spinal arthrodesis was attempted with use of a type-I collagen matrix in five groups of athymic rats, with eight animals in each group. Group I was treated with 5 x 10(6) adipose-derived stem cells transduced with an adenoviral vector containing the BMP-2 gene; group II, with 5 x 10(6) adipose-derived stem cells treated with osteogenic media and 1 microg/mL of recombinant BMP-2 (rhBMP-2); group III, with 10 microg of rhBMP-2; group IV, with 1 microg of rhBMP-2; and group V, with 5 x 10(6) adipose-derived stem cells alone. The animals that showed radiographic evidence of healing were killed four weeks after cell implantation and were examined with plain radiographs, manual palpation, microcomputed tomography scanning, and histological analysis. RESULTS: All eight animals in group I demonstrated successful spinal fusion, with a large fusion mass, four weeks postoperatively. Furthermore, group-I specimens consistently revealed spinal fusion at the cephalad level (L3 and L4), where no fusion bed had been prepared surgically. In contrast, despite substantial BMP-2 production measured in vitro, group-II animals demonstrated minimal bone formation even eight weeks after implantation. Of the groups treated with the application of rhBMP-2 alone, the one that received a relatively high dose (group III) had a higher rate of fusion (seen in all eight specimens) than the one that received the low dose (group IV, in which fusion was seen in four of the eight specimens). None of the group-V animals (treated with adipose-derived stem cells alone) demonstrated successful spine fusion eight weeks after the surgery. CONCLUSIONS: Adipose-derived stem cells show promise as gene transduction targets for inducing bone formation to enhance spinal fusion in biologically stringent environments.

Downregulation of extracellular matrix-related gene clusters during osteogenic differentiation of human bone marrow- and adipose tissue-derived stromal cells.

Bone marrow- and adipose tissue-derived stromal cells (BMSCs and ASCs, respectively) exhibit a similar capacity for osteogenic differentiation in vitro, but it is unclear whether they share a common differentiation process, because they originate from different tissues. The aim of this study was to explore BMSC and ASC osteogenic differentiation by focusing on the expression of extracellular matrix-related genes (ECMGs), which play a crucial role in osteogenesis and bone tissue regeneration in vivo. We characterized the gene expression profiles of BMSCs and ASCs using a custom complementary deoxyribonucleic acid microarray containing 55 ECMGs. Undifferentiated BMSCs and ASCs actively expressed a wide range of ECMGs. Once BMSCs and ASCs were placed in an osteogenic differentiation medium, 24 and 17 ECMGs, respectively, underwent considerable downregulation over the course of the culture period. The remaining genes were maintained at a similar expression level to corresponding uninduced cell cultures. Although the suppression phenomenon was consistent irrespective of stromal cell origin, collagen (COL)2A1, COL6A1, COL9A1, parathyroid hormone receptor, integrin (INT)-beta3, and TenascinX genes were only downregulated in osteogenic BMSCs, whereas COL1A2, COL3A1, COL4A1, COL5A2, COL15A1, osteopontin, osteonectin, and INT-beta1 genes were only downregulated in osteogenic ASCs. During this time period, cell viability was sustained, suggesting that the observed downregulation did not occur by selection and elimination of unfit cells from the whole cell population. These data suggest that osteogenically differentiating BMSCs and ASCs transition away from a diverse gene expression pattern, reflecting their multipotency toward a configuration specifically meeting the requirements of the target lineage. This change may serve to normalize gene expression in mixed populations of stem cells derived from different tissues.

Adipose-derived stem and progenitor cells as fillers in plastic and reconstructive surgery.

Plastic surgeons are keenly aware of the principle "replace like with like." This principle underlies much of the rationale behind the clinical use of autologous fat transplantation, despite the procedure's drawbacks. Autologous fat transplantation is frequently used for a variety of cosmetic and reconstructive indications not limited to posttraumatic defects of the face and body, involutional disorders such as hemifacial atrophy, sequelae of radiation therapy, and many aesthetic uses such as lip and facial augmentation and wrinkle therapy. However, the limitations of fat transplantation are well known, particularly the long-term unpredictability of volume maintenance. Regenerative cell-based strategies such as those encompassing the use of stem cells hold tremendous promise for augmentation of the soft-tissue space. Preclinical studies and early clinical series show that adipose-derived stem cells offer the possibility of finally fulfilling the key principle of replacing like with like as an aesthetic filler, without the drawbacks of current technology.

Plasticity of human adipose stem cells toward endothelial cells and cardiomyocytes.

Recent preclinical and clinical studies have suggested that adult stem cells have the ability to promote the retention or restoration of cardiac function in acute and chronic ischemia. Published clinical studies have used autologous donor cells, including skeletal muscle myoblasts, cultured peripheral blood cells, or bone marrow cells. However, our research and that of others indicates that human adipose tissue is an alternative source of cells with potential for cardiac cell therapy. These findings include the presence of cells within adipose tissue that can differentiate into cells expressing a cardiomyocytic or endothelial phenotype, as well as angiogenic and antiapoptotic growth factors. This potential is supported by preclinical studies in large animals.

Fat tissue: an underappreciated source of stem cells for biotechnology.

Adipose tissue can be harvested in large amounts with minimal morbidity. It contains numerous cells types, including adipocytes, preadipocytes, vascular endothelial cells and vascular smooth muscle cells; it also contains cells that have the ability to differentiate into several lineages, such as fat, bone, cartilage, skeletal, smooth, and cardiac muscle, endothelium, hematopoietic cells, hepatocytes and neuronal cells. Cloning studies have shown that some adipose-derived stem cells (ADSCs) have multilineage differentiation potential. ADSCs are also capable of expressing multiple growth factors, including vascular endothelial growth factor and hepatocyte growth factor. Early, uncontrolled, non-randomized clinical research, applying fresh adipose-derived cells into a cranial defect or undifferentiated ADSCs into fistulas in Crohn's disease, has shown healing and an absence of side effects. The combination of these properties, and the large quantity of cells that can be obtained from fat, suggests that this tissue will be a useful tool in biotechnology.

Multipotential differentiation of adipose tissue-derived stem cells.

Tissue engineering offers considerable promise in the repair or replacement of diseased and/or damaged tissues. The cellular component of this regenerative approach will play a key role in bringing these tissue engineered constructs from the laboratory bench to the clinical bedside. However, the ideal source of cells still remains unclear and may differ depending upon the application. Current research for many applications is focused on the use of adult stem cells. The properties of adult stem cells that make them well-suited for regenerative medicine are (1) ease of harvest for autologous transplantation, (2) high proliferation rates for ex vivo expansion and (3) multilineage differentiation capacity. This review will highlight the use of adipose tissue as a reservoir of adult stem cells and draw conclusions based upon comparisons with bone marrow stromal cells.

Tissue-engineered bone from BMP-2-transduced stem cells derived from human fat.

BACKGROUND: Progenitor cells capable of induction into multiple mesenchymal lineages have been isolated from human liposuction aspirates. These cells, named processed lipoaspirate cells, have previously shown in vitro osteogenic capacity. The purpose of this study was to examine the in vivo bone induction capacity of bone morphogenetic protein-2 (BMP-2)-transduced processed lipoaspirate cells using adipose tissue from multiple harvest sites. METHODS: Processed lipoaspirate cells extracted from human abdominal and buttock liposuction aspirates (n = 5) and from infrapatellar fat pads (n = 5) were placed in osteogenic media containing Dulbecco's Modified Eagle Medium with 10% fetal bovine serum supplemented with 50 muM ascorbic acid-2-phosphate and 10 mM beta-glycerol phosphate. Half of these cells were transfected with an adenovirus carrying the cDNA for bone morphogenetic protein-2 (adBMP-2). These transfected cells were then seeded onto collagen I matrices at a concentration of 2 x 10 cells/matrix and were placed into the hind limbs of severe combined immunodeficient mice (n = 10). Nontransfected processed lipoaspirate cells were placed in the contralateral limb as a control. After 6 weeks, specimens were analyzed by radiographs, densitometry, and hematoxylin and eosin and von Kossa staining. RESULTS: The average number of cells extracted from the abdominal/buttock lipoaspirates was 3.4 x 10 cells/100 ml fat aspirate and 5.5 x 10 cells per infrapatellar fat pad (average volume, 20.6 cc). All 10 BMP-2 transfected processed lipoaspirate constructs produced abundant radiographic and histologic bone. The bone was adequately mineralized and was beginning to establish a marrow cavity. There was no quantitative difference in bone production between harvest sites [mean, 2.0 +/- 0.1 aluminum units (knee) versus 2.1 +/- 0.1 aluminum units (abdomen/buttock); p = 0.14]. No bone was produced in the negative controls. CONCLUSIONS: Multipotential processed lipoaspirate cells can be extracted from adipose tissue harvested from liposuction aspirates or from the infrapatellar fat pad of the knee. Processed lipoaspirate cells can be transduced with the BMP-2 gene to produce abundant in vivo bone. These cells appear to be clinically useful for bone tissue engineering applications either as osteoprogenitor cells or as delivery vehicles for BMP-2.

The growing importance of fat in regenerative medicine.

A recent publication by Michael Longaker and colleagues represents a landmark for the use of adipose tissue as a source of cells for tissue regeneration. The authors investigated the ability of adipose tissue-derived cells (ADCs) to regenerate critical size calvarial (superior portion of the skull) defects in mice by using a novel osteoconducive apatite-coated Poly-lactic-co-glycolic acid (PLGA) scaffold for cell delivery. Direct comparison of this osteogenic ability was performed with bone marrow stromal cells and juvenile calvarial-derived osteoblasts.

Autologous stem cells (adipose) and fibrin glue used to treat widespread traumatic calvarial defects: case report.

This is a report of a 7-year-old girl suffering from widespread calvarial defects after severe head injury with multifragment calvarial fractures, decompressive craniectomy for refractory intracranial hypertension and replantation of cryopreserved skull fragments. Chronic infection resulted in an unstable skull with marked bony defects. Two years after the initial injury the calvarial defects were repaired. Due to the limited amount of autologous cancellous bone available from the iliac crest, autologous adipose derived stem cells were processed simultaneously and applied to the calvarial defects in a single operative procedure. The stem cells were kept in place using autologous fibrin glue. Mechanical fixation was achieved by two large, resorbable macroporous sheets acting as a soft tissue barrier at the same time. The postoperative course was uneventful and CT-scans showed new bone formation and near complete calvarial continuity three months after the reconstruction.

Noninvasive in situ evaluation of osteogenic differentiation by time-resolved laser-induced fluorescence spectroscopy.

The clinical implantation of bioengineered tissues requires an in situ nondestructive evaluation of the quality of tissue constructs developed in vitro before transplantation. Time-resolved laser-induced fluorescence spectroscopy (TR-LIFS) is demonstrated here to noninvasively monitor the formation of osteogenic extracellular matrix (ECM) produced by putative stem cells (PLA cells) derived from human adipose tissue. We show that this optical spectroscopy technique can assess the relative expression of collagens (types I, III, IV, and V) within newly forming osteogenic ECM. The results are consistent with those obtained by conventional histochemical techniques (immunofluorescence and Western blot) and demonstrate that TR-LIFS is a potential tool for monitoring the expression of distinct collagen types and the formation of collagen cross-links in intact tissue constructs.

The use of tissue expanders in the closure of a giant omphalocele.

Giant omphalocele is associated with a high degree of visceroabdominal disproportion, which prohibits safe primary closure. Conventional treatment options include (1) topical therapy with epithelialization followed by secondary ventral hernia repair and (2) staged reduction using a SILASTIC(R) (Dow Corning, Midland, MI) chimney. The authors report a case in which staged reduction of a giant omphalocele was facilitated by the use of crescent-shaped tissue expanders positioned in the potential space between the internal oblique and transversus abdominis layers of the abdominal wall.

Adult stem cell therapy for the heart.

The purpose of this review is to summarize current data leading to and arising from recent clinical application of cellular therapy for acute myocardial infarct (heart attack) and congestive heart failure. We specifically focus on use of adult stem cells and compare and contrast bone marrow and adipose tissue; two different sources from which stem cells can be harvested in substantial numbers with limited morbidity. Cellular therapy is the latest in a series of strategies applied in an effort to prevent or mitigate the progressive and otherwise irreversible loss of cardiac function that frequently follows a heart attack. Unlike surgical, pharmacologic, and gene transfer approaches, cellular therapy has the potential to restore cardiac function by providing cells capable of regenerating damaged myocardium and/or myocardial function. Skeletal muscle myoblast expansion and transfer allows delivery of cells with contractile function, albeit without any evidence of cardiomyogenesis or electrical coupling to remaining healthy myocardium. Delivery of endothelial progenitor cells (EPCs) which drive reperfusion of infarct zone tissues is also promising, although this mechanism is directed at halting ongoing degeneration rather than initiating a regenerative process. By contrast, demonstration of the ability of adult stem cells to undergo cardiomyocyte differentiation both in vitro and in vivo suggests a potential for regenerative medicine. This potential is being examined in early clinical studies.

Chondrogenic potential of multipotential cells from human adipose tissue.

The use of stem cells for cell-based tissue-engineering strategies represents a promising alternative for the repair of cartilaginous defects. The multilineage potential of a population of putative mesodermal stem cells obtained from human lipoaspirates, termed processed lipoaspirate cells, was previously characterized. The chondrogenic potential of those cells was confirmed with a combination of histological and molecular approaches. Processed lipoaspirate cells under high-density micromass culture conditions, supplemented with transforming growth factor-beta1, insulin, transferrin, and ascorbic acid, formed well-defined nodules within 48 hours of induction and expressed the cartilaginous markers collagen type II, chondroitin-4-sulfate, and keratan sulfate. Reverse transcription polymerase chain reaction analysis confirmed the expression of collagen type II and the cartilage-specific proteoglycan aggrecan. In summary, human adipose tissue may represent a novel plentiful source of multipotential stem cells capable of undergoing chondrogenesis in vitro.

The use of adult stem cells in regenerative medicine.

The cellular component of the tissue engineering paradigm is arguably the most important piece of the complex task of regenerating or repairing damaged or diseased tissue. Critical to the development of clinical strategies is the need for reliable sources of multipotent cells that can be obtained with limited morbidity. The adult stem cell population may be well suited for this task. The next several years will bring many phase I and II studies using adult stem cells as the cellular foundation for engineered tissue constructs. Future research should be directed toward better characterization of this cell population, including identifying unique markers and mapping out lineage development. For now, the ideal source of adult stem cells remains uncertain, but as questions are answered, adult stem cell biology will likely transition from bench top to clinical reality.