Mandana Veiseh

Tumor Paint: A Chlorotoxin:Cy5.5 Bioconjugate for Intraoperative Visualization of Cancer Foci

Toward the goal of developing an optical imaging contrast agent that will enable surgeons to intraoperatively distinguish cancer foci from adjacent normal tissue, we developed a chlorotoxin:Cy5.5 (CTX:Cy5.5) bioconjugate that emits near-IR fluorescent signal. The probe delineates malignant glioma, medulloblastoma, prostate cancer, intestinal cancer, and sarcoma from adjacent non-neoplastic tissue in mouse models. Metastatic cancer foci as small as a few hundred cells were detected in lymph channels. Specific binding to cancer cells is facilitated by matrix metalloproteinase-2 (MMP-2) as evidenced by reduction of CTX:Cy5.5 binding in vitro and in vivo by a pharmacologic blocker of MMP-2 and induction of CTX:Cy5.5 binding in MCF-7 cells following transfection with a plasmid encoding MMP-2. Mouse studies revealed that CTX:Cy5.5 has favorable biodistribution and toxicity profiles. These studies show that CTX:Cy5.5 has the potential to fundamentally improve intraoperative detection and resection of malignancies.

Influence of cell adhesion and spreading on impedance characteristics of cell-based sensors.

Impedance measurements of cell-based sensors are a primary characterization route for detection and analysis of cellular responses to chemical and biological agents in real time. The detection sensitivity and limitation depend on sensor impedance characteristics and thus on cell patterning techniques. This study introduces a cell patterning approach to bind cells on microarrays of gold electrodes and demonstrates that single-cell patterning can substantially improve impedance characteristics of cell-based sensors. Mouse fibroblast cells (NIH3T3) are immobilized on electrodes through a lysine-arginine-glycine-aspartic acid (KRGD) peptide-mediated natural cell adhesion process. Electrodes are made of three sizes and immobilized with either covalently bound or physically adsorbed KRGD (c-electrodes or p-electrodes). Cells attached to c-electrodes increase the measurable electrical signal strength by 48.4%, 24.2%, and 19.0% for three electrode sizes, respectively, as compared to cells attached to p-electrodes, demonstrating that both the electrode size and surface chemistry play a key role in cell adhesion and spreading and thus the impedance characteristics of cell-based sensors. Single cells patterned on c-electrodes with dimensions comparable to cell size exhibit well-spread cell morphology and substantially outperform cells patterned on electrodes of other configurations.

Two-Dimensional Protein Micropatterning for Sensor Applications Through Chemical Selectivity Technique

Two-dimensional protein micropatterning with immobil-ization of IgG and poly (ethylene glycol) (PEG) on patterned Au and Si surfaces was performed through a new technique. The technique for micropatterning is based on a chemical selectivity method by creating chemical bonding between protein, self-assembled monolayers (SAMs) and substrates rather than physical means. The substrates used in this study are pre-fabricated with silicon wafer patterned with arrays of gold squares. The silicon regions of the substrate are modified with polyethylene glycol (PEG) to resist protein adsorption and cell adhesion. The gold regions on the substrate are first immobilized with bifunctional SAM layers that can covalently bound adhesion proteins for individual cell attachment against a PEG background. The surface coatings are characterized by contact angle measurement, ellips-ometry, and atomic force microscopy (AFM). The patterns of fluorescence-labeled proteins are examined using fluorescence microscopy. Our study demonstrated that the PEG modified silicon region showed an effective protein reduction while the gold regions were successfully covalently bonded with proteins. This technique also demonstrated a combined feature of ensuring the activity, selectivity, and stability of the immobilized proteins. A simple lift-off microfabrication process was introduced in this study to pattern metal on silicon substrates without using expensive metal etching.

Temporal changes in Hox gene expression accompany endothelial cell differentiation of embryonic stem cells.

In pluripotent embryonic stem cells (ESCs), expression of the Hox master regulatory transcription factors that play essential roles in organogenesis, angiogenesis, and maintenance of differentiated tissues, is globally suppressed. We investigated whether differentiation of endothelial cells (ECs) from mouse ESCs was accompanied by activation of distinct Hox gene expression profiles. Differentiation was observed within 3 days, as indicated by the appearance of cells expressing specific endothelial marker genes (Flk-1+/VE-Cadherin+). Expression of HoxA3 and HoxD3, which drive adult endothelial cell invasion and angiogenesis, peaked at day 3 and declined thereafter, whereas expression of HoxA5 and HoxD10, which maintain a mature quiescent EC phenotype, was low at day 3, but increased over time. The temporal and reciprocal changes in HoxD3 and HoxA5 expression were accompanied by corresponding changes in expression of established downstream target genes including integrin β3 and Thrombospondin-2. Our results indicate that differentiation and maturation of ECs derived from cultured ESCs mimic changes in Hox gene expression that accompany maturation of immature angiogenic endothelium into differentiated quiescent endothelium in vivo.