Maggie Chun

Expression of neuropeptides and cytokines in a rabbit model of diabetic neuroischemic wound healing

OBJECTIVE The present study is designed to understand the contribution of peripheral vascular disease and peripheral neuropathy to the wound-healing impairment associated with diabetes. Using a rabbit model of diabetic neuroischemic wound healing, we investigated rate of healing, leukocyte infiltration, and expression of cytokines, interleukin-8 and interleukin-6, and neuropeptides, substance P, and neuropeptide Y. METHODS Diabetes was induced in New Zealand White rabbits by administering alloxan while control rabbits received saline. Ten days later, animals in both groups underwent surgery. One ear served as a sham, and the other was made ischemic (ligation of central+rostral arteries) or neuroischemic (ischemia+ resection of central+rostral nerves). Four 6-mm punch biopsy wounds were created in both ears and wound healing was followed for 10 days using computerized planimetry. RESULTS Nondiabetic sham and ischemic wounds healed significantly more rapidly than diabetic sham and ischemic wounds. Healing was slowest in neuroischemic wounds, irrespective of diabetic status. A high M1/M2 macrophage ratio and a high proinflammatory cytokine expression, both indicators of chronic proinflammatory state, and low neuropeptide expression were seen in preinjury diabetic skin. Postinjury, in diabetic wounds, the M1/M2 ratio remained high, the reactive increase in cytokine expression was low, and neuropeptide expression was further decreased in neuroischemic wounds. CONCLUSIONS This rabbit model illustrates how a combination of a high M1/M2 ratio, a failure to mount postinjury cytokine response as well as a diminished neuropeptide expression, contribute to wound-healing impairment in diabetes. The addition of neuropathy to ischemia leads to equivalently severe impaired wound-healing irrespective of diabetes status, suggesting that in the presence of ischemia, loss of neuropeptide function contributes to the impaired healing associated with diabetes.

High throughput RNAi assay optimization using adherent cell cytometry

BackgroundsiRNA technology is a promising tool for gene therapy of vascular disease. Due to the multitude of reagents and cell types, RNAi experiment optimization can be time-consuming. In this study adherent cell cytometry was used to rapidly optimize siRNA transfection in human aortic vascular smooth muscle cells (AoSMC).MethodsAoSMC were seeded at a density of 3000-8000 cells/well of a 96well plate. 24 hours later AoSMC were transfected with either non-targeting unlabeled siRNA (50 nM), or non-targeting labeled siRNA, siGLO Red (5 or 50 nM) using no transfection reagent, HiPerfect or Lipofectamine RNAiMax. For counting cells, Hoechst nuclei stain or Cell Tracker green were used. For data analysis an adherent cell cytometer, Celigo® was used. Data was normalized to the transfection reagent alone group and expressed as red pixel count/cell.ResultsAfter 24 hours, none of the transfection conditions led to cell loss. Red fluorescence counts were normalized to the AoSMC count. RNAiMax was more potent compared to HiPerfect or no transfection reagent at 5 nM siGLO Red (4.12 +/-1.04 vs. 0.70 +/-0.26 vs. 0.15 +/-0.13 red pixel/cell) and 50 nM siGLO Red (6.49 +/-1.81 vs. 2.52 +/-0.67 vs. 0.34 +/-0.19). Fluorescence expression results supported gene knockdown achieved by using MARCKS targeting siRNA in AoSMCs.ConclusionThis study underscores that RNAi delivery depends heavily on the choice of delivery method. Adherent cell cytometry can be used as a high throughput-screening tool for the optimization of RNAi assays. This technology can accelerate in vitro cell assays and thus save costs.

Gene silencing in human aortic smooth muscle cells induced by PEI-siRNA complexes released from dip-coated electrospun poly(ethylene terephthalate) grafts.

An excessive tissue response to prosthetic arterial graft material leads to intimal hyperplasia (IH), the leading cause of late graft failure. Seroma and abnormal capsule formation may also occur after prosthetic material implantation. The matricellular protein Thrombospondin-2 (TSP-2) has shown to be upregulated in response to biomaterial implantation. This study evaluates the uptake and release of small interfering RNA (siRNA) from unmodified and surface functionalized electrospun PET graft materials. ePET graft materials were synthesized using electrospinning technology. Subsets of the ePET materials were then chemically modified to create surface functional groups. Unmodified and surface-modified ePET grafts were dip-coated in siRNAs alone or siRNAs complexed with transfection reagents polyethyleneimine (PEI) or Lipofectamine RNAiMax. Further, control and TSP-2 siRNA-PEI complex treated ePET samples were placed onto a confluent layer of human aortic smooth muscle cells (AoSMCs). Complexation of all siRNAs with PEI led to a significant increase in adsorption to unmodified ePET. TSP-2 siRNA-PEI released from unmodified-ePET silenced TSP-2 in AoSMC. Regardless of the siRNA-PEI complex evaluated, AoSMC migrated into the ePET. siRNA-PEI complexes delivered to AoSMC from dip-coated ePET can result in gene knockdown. This methodology for siRNA delivery may improve the tissue response to vascular and other prosthetics.

pH-responsive scaffolds generate a pro-healing response

A principal challenge in wound healing is a lack of cell recruitment, cell infiltration, and vascularization, which occurs in the absence of temporal and spatial cues. We hypothesized that a scaffold that expands due to local changes in pH may alter oxygen and nutrient transport and the local cell density, leading to enhanced cell deposition and survival. In this study, we present a pH-responsive scaffold that increases oxygen transport, as confirmed by our finite element model analysis, and cell proliferation relative to a non-responsive scaffold. In vivo, responsive scaffolds induce a pro-healing gene expression profile indicative of enhanced angiogenesis, granulation tissue formation, and tissue remodeling. Scaffolds that stretch in response to their environment may be a hallmark for tissue regeneration.

Development of a composite electrospun polyethylene terephthalate-polyglycolic acid material: potential use as a drug-eluting vascular graft

Intimal hyperplasia (IH), an excessive wound healing response of an injured vessel wall after bypass grafting, typically leads to prosthetic bypass graft failure. In an approach to ameliorate IH, nondegradable poly(ethylene terephthalate) or PET, which has been used in prosthetic vascular grafts for over 60 years, and biodegradable poly(glycolic acid) or PGA were electrospun using different techniques to generate a material that may serve as permanent scaffold and as a drug/biologic delivery device. PET and PGA polymers were electrospun from either a single-blended solution (ePET/ePGA-s) or two separate polymer solutions (ePET/ePGA-d). ePET/ePGA-d material revealed two distinct fibers and was significantly stronger than the single fiber ePET/ePGA-s material. After 21 days of incubation in PBS, ePET-PGA-s showed fiber strand breaks likely due to the degradation of the PGA within the ePET-ePGA-s fiber, while the ePET/ePGA-d material showed intact ePET fibers even after ePGA fiber degradation. The ePET/ePGA- material was able to release red fluorescent dye for at least 14 days. Attachment of human aortic smooth muscle cells (AoSMCs) was similar to both materials. ePET/ePGA-d materials maybe a step towards bypass graft materials that can be custom-designed to promote cellular attachment while serving as a drug delivery platform for IH prevention.

Differential susceptibility of Human Primary Aortic and Coronary Artery Vascular Cells to RNA interference

BACKGROUND RNAi technology is a promising tool for gene therapy of vascular disease. However, the biological heterogeneity between endothelial (EC) and vascular smooth muscle cells (SMC) and within different vascular beds make them differentially susceptible to siRNA. This is further complicated by the task of choosing the right transfection reagent that leads to consistent gene silencing across all cell types with minimal toxicity. The goal of this study was to investigate the intrinsic RNAi susceptibility of primary human aortic and coronary artery endothelial and vascular smooth muscle cells (AoEC, CoEC, AoSMC and CoSMC) using adherent cell cytometry. METHODS Cells were seeded at a density of 5000cells/well of a 96well plate. Twenty four hours later cells were transfected with either non-targeting unlabeled control siRNA (50nM), or non-targeting red fluorescence labeled siRNA (siGLO Red, 5 or 50nM) using no transfection reagent, HiPerFect or Lipofectamine RNAiMAX. Hoechst nuclei stain was used to label cells for counting. For data analysis an adherent cell cytometer, Celigo was used. RESULTS Red fluorescence counts were normalized to the cell count. EC displayed a higher susceptibility towards siRNA delivery than SMC from the corresponding artery. CoSMC were more susceptible than AoSMC. In all cell types RNAiMAX was more potent compared to HiPerFect or no transfection reagent. However, after 24h, RNAiMAX led to a significant cell loss in both AoEC and CoEC. None of the other transfection conditions led to a significant cell loss. CONCLUSION This study confirms our prior observation that EC are more susceptible to siRNA than SMC based on intracellular siRNA delivery. RNAiMax treatment led to significant cell loss in AoEC and CoEC, but not in the SMC populations. Additionally, this study is the first to demonstrate that coronary SMC are more susceptible to siRNA than aortic SMC.