In Vivo Degradation of Crosslinked Hyaluronic Acid Fillers by Exogenous Hyaluronidases.

BACKGROUND: An advantage of hyaluronic acid (HA)-based fillers is reversibility. OBJECTIVE: To evaluate the ability of 2 hyaluronidases to degrade 3 HA-based fillers using a novel in vivo model. MATERIALS AND METHODS: Rats were injected with 3 HA fillers (HYC-24L+, VYC-20L, and RES-L) to create a projecting bolus. After 4 days, recombinant human hyaluronidase (HX) or ovine hyaluronidase (VIT) was administered at (1) varying doses (5 U, 10 U, or 30 U per 0.1 mL filler) or (2) different dilutions (10 U diluted 3-fold). The impact of tissue integration was assessed by administering 10 U/0.1 mL filler 4 weeks after filler injection. Three-dimensional images quantified projection loss over 72 hours. RESULTS: Complete loss of projection was achieved for all fillers with the highest HX and VIT doses; lower doses achieved less degradation. No difference in degradation was observed between HYC-24L+ and VYC-20L using HX or VIT. RES-L was slightly more degraded with 10 U VIT but not with 10 U HX. Enzyme dilution resulted in less degradation. Tissue integration did not impact the degree of degradation. CONCLUSION: This model incorporates the biological system while controlling variables including filler depth and volume and location of hyaluronidase delivery. Hyaluronic acid filler degradation by exogenous hyaluronidase was not hindered by differences among fillers.

Vitronectin-Based, Biomimetic Encapsulating Hydrogel Scaffolds Support Adipogenesis of Adipose Stem Cells.

Soft tissue defects are relatively common, yet currently used reconstructive treatments have varying success rates, and serious potential complications such as unpredictable volume loss and reabsorption. Human adipose-derived stem cells (ASCs), isolated from liposuction aspirate have great potential for use in soft tissue regeneration, especially when combined with a supportive scaffold. To design scaffolds that promote differentiation of these cells down an adipogenic lineage, we characterized changes in the surrounding extracellular environment during adipogenic differentiation. We found expression changes in both extracellular matrix proteins, including increases in expression of collagen-IV and vitronectin, as well as changes in the integrin expression profile, with an increase in expression of integrins such as αVß5 and α1ß1. These integrins are known to specifically interact with vitronectin and collagen-IV, respectively, through binding to an Arg-Gly-Asp (RGD) sequence. When three different short RGD-containing peptides were incorporated into three-dimensional (3D) hydrogel cultures, it was found that an RGD-containing peptide derived from vitronectin provided strong initial attachment, maintained the desired morphology, and created optimal conditions for in vitro 3D adipogenic differentiation of ASCs. These results describe a simple, nontoxic encapsulating scaffold, capable of supporting the survival and desired differentiation of ASCs for the treatment of soft tissue defects.

Rheological Properties and In Vivo Performance Characteristics of Soft Tissue Fillers.

BACKGROUND: Physicochemical properties and performance in nonclinical animal models can provide insights into soft tissue filler performance. OBJECTIVE: To evaluate the in vivo performance of fillers with different compositions and physicochemical properties. MATERIALS AND METHODS: Physicochemical properties were measured in vitro. Rat models were developed and used to compare lift capacity, resistance to deformation, and tissue integration. Four homogeneous hyaluronic acid (HA) fillers, 2 nonanimal stabilized HA (NASHA) fillers, and 1 calcium hydroxylapatite/carboxymethyl cellulose (CaHA/CMC) filler were evaluated. RESULTS: Filler lift capacity correlated better with filler composition/type (homogeneous > NASHA > CaHA/CMC) than with specific rheological properties. The CaHA/CMC filler had high initial resistance to deformation relative to other groups; all HA fillers exhibited lower initial resistance to deformation, which increased over time. Homogeneous HA fillers were integrated with surrounding tissue, whereas integration within particle-based fillers (NASHA and CaHA/CMC) was variable, with some areas void of tissue. CONCLUSION: The animal models provide a platform to make comparative evaluations among fillers. The results indicated that biological interaction plays an important role in how the filler performs. Rheology alone was not sufficient to understand filler performance but was most useful when comparing within fillers of similar composition.

Skin extracellular matrix stimulation following injection of a hyaluronic acid-based dermal filler in a rat model.

BACKGROUND: Hyaluronic acid-based dermal fillers have gained rapid acceptance for treating facial wrinkles and deep tissue folds. Although their space-filling properties are well understood, this study evaluates the cellular and molecular changes in skin, as a secondary effect, following injection of a commercially available, 24-mg/ml, cross-linked hyaluronic acid-based filler (HYC-24L+) in a rodent model. METHODS: Sprague-Dawley rats, aged 2 to 4 months, were injected intradermally with 20 µl of HYC-24L+ using a linear threading technique and followed to 12 weeks after injection. Untreated skin and saline injection were used as study controls. Enzyme-linked immunosorbent assay and reverse-transcriptase polymerase chain reaction methods were used to investigate changes in the expression of several extracellular matrix proteins and genes over time. RESULTS: HYC-24L+ significantly increased the protein expression levels of collagen types I and III in rat dermal tissue for up to 12 weeks. The ratio of collagen type III to type I protein, however, remained unchanged, suggesting maintenance of collagen homeostasis. A significant increase in dermal elastin after HYC-24L+ injection was also observed. Gene expression analysis confirmed that several genes associated with extracellular matrix production and assembly were also transiently up-regulated, and that these changes temporally preceded those observed at the protein level. CONCLUSION: In addition to its well-understood space-filling function, as a secondary effect, the authors demonstrate that HYC-24L+ stimulates the production of several extracellular matrix components, including dermal collagen and elastin.

Approaches to avoid immune responses induced by repeated subcutaneous injections of allogeneic umbilical cord tissue-derived cells.

BACKGROUND: Cellular treatments for repairing diseased tissues represent a promising clinical strategy. Umbilical cord tissue-derived cells (UTC) are a unique source of cells with a low immunogenic profile and potential for tissue repair. By using UTC from miniature swine, we previously demonstrated that despite their low immunogenic phenotype, UTC could induce an immune response under certain inflammatory conditions and after multiple subcutaneous (SC) injections. Given that repeat dosing of cells may be necessary to achieve a lasting therapeutic benefit, in this study, we examined approaches to avoid an immune response to multiple SC injections of UTC. METHODS: By using in vitro and in vivo measures of sensitization to SC cellular injections, we assessed the effects of varying the location of administration site, prolongation of timing between injections, and use of immunosuppressive treatments on repeated cellular injections in Massachusetts General Hospital major histocompatibility complex-defined miniature swine. RESULTS: Although under normal conditions, a single SC injection of major histocompatibility complex-mismatched UTC did not induce a detectable immune response, multiple SC injections of UTC demonstrated rapid humoral and cell-mediated immune responses. Avoidance of an immune response to repeat SC injection was achieved by concurrent immunosuppression with each dose of UTC. CONCLUSIONS: UTC and other similar cell types believed to be nonimmunogenic have the potential to induce immune responses under certain conditions. These studies provide important considerations and guidelines for preclinical studies investigating allogeneic cellular therapies.

Immunogenicity of umbilical cord tissue derived cells.

Umbilical cord tissue provides a unique source of cells with potential for tissue repair. Umbilical cord tissue-derived cells (UTCs) are MHC class I (MHCI) dull and negative for MHC class II (MHCII), but can be activated to increase MHCI and to express MHCII with IFN-gamma stimulation. Mesenchymal stem cells with similar characteristics have been inferred to be nonimmunogenic; however, in most cases, immunogenicity was not directly assessed. Using UTC from Massachusetts General Hospital MHC-defined miniature swine, we assessed immunogenicity across a full MHC barrier. Immunogenicity was assessed by in vitro assays including mixed lymphocyte reaction (MLR) and flow cytometry to detect serum alloantibody. A single injection of MHC-mismatched unactivated UTCs did not induce a detectable immune response. When injected in an inflamed region, injected repeatedly in the same region or stimulated with IFN-gamma prior to injection, UTCs were immunogenic. As clinical cellular repair strategies may involve injection of allogeneic cells into inflamed regions of damaged tissue or repeated doses of cells to achieve the desired benefit, our results on the immunogenicity of these cells in these circumstances may have important implications for optimal success and functional improvement for this cellular treatment strategy for diseased tissues.

Cells isolated from umbilical cord tissue rescue photoreceptors and visual functions in a rodent model of retinal disease.

Progressive photoreceptor degeneration resulting from genetic and other factors is a leading and largely untreatable cause of blindness worldwide. The object of this study was to find a cell type that is effective in slowing the progress of such degeneration in an animal model of human retinal disease, is safe, and could be generated in sufficient numbers for clinical application. We have compared efficacy of four human-derived cell types in preserving photoreceptor integrity and visual functions after injection into the subretinal space of the Royal College of Surgeons rat early in the progress of degeneration. Umbilical tissue-derived cells, placenta-derived cells, and mesenchymal stem cells were studied; dermal fibroblasts served as cell controls. At various ages up to 100 days, electroretinogram responses, spatial acuity, and luminance threshold were measured. Both umbilical-derived and mesenchymal cells significantly reduced the degree of functional deterioration in each test. The effect of placental cells was not much better than controls. Umbilical tissue-derived cells gave large areas of photoreceptor rescue; mesenchymal stem cells gave only localized rescue. Fibroblasts gave sham levels of rescue. Donor cells were confined to the subretinal space. There was no evidence of cell differentiation into neurons, of tumor formation or other untoward pathology. Since the umbilical tissue-derived cells demonstrated the best photoreceptor rescue and, unlike mesenchymal stem cells, were capable of sustained population doublings without karyotypic changes, it is proposed that they may provide utility as a cell source for the treatment of retinal degenerative diseases such as retinitis pigmentosa.

A cell encapsulation device for studying soluble factor release from cells transplanted in the rat brain.

The transplantation of a variety of naturally occurring and genetically modified cell types has been shown to be an effective experimental method to achieve sustained delivery of therapeutic molecules to specific target areas in the brain. To acquire a better understanding of dosing, implant mechanism of action, and how certain cell types affect remodeling of central nervous system (CNS) tissue, a refillable cell encapsulation device was developed for introducing cells into the brain while keeping them physically isolated from contact with brain tissue with a semipermeable membrane. The stereotactically placed device consists of a hollow fiber membrane (HFM), a polyurethane grommet with watertight cap that snaps into a precisely drilled hole in the rat skull, and a removable cell-containing insert. The cell-containing insert can be introduced or removed in a time-dependent manner to study the influence of soluble factors released from transplanted cells. The study describes the device design and validates its utility using a well-established cell transplantation model of Parkinson's disease.

Comparison of pure and mixed populations of human fetal-derived neural progenitors transplanted into intact adult rat brain.

We examined the influence of initial graft composition on the number, type, and distribution of human progenitor cells after transplantation into the anterior subventricular zone (SVZa) of normal adult rats. The grafted populations were derived from 19-week-old human cortical tissue grown under adherent conditions in the presence of fibroblast growth factor (FGF) and from a subpopulation of nestin-expressing cells, isolated using negative immunoselection methods, which exhibited properties of neural progenitors. Identical numbers of each were transplanted and the number and location of engrafted cells were compared 4 weeks later. We found a significantly greater number of presumptive neurons and astrocytes in animals that received mixed grafts compared to those enriched for progenitors. In addition, the number of human cells undergoing division was significantly greater in animals that received mixed grafts. The spatial distribution of grafted cells was not significantly different, suggesting that the patterns of cell migration were unaffected by transplant composition, whereas, a greater proportion of neurons was observed in the neurogenic areas of animals that received progenitor-enriched grafts. From a clinical perspective, our results suggest that the cellular composition of human fetal-derived transplants may be an important parameter that influences the number and pattern of differentiation of engrafted cells following transplantation in the mature CNS.