William Mark Saltzman

Small-diameter biodegradable scaffolds for functional vascular tissue engineering in the mouse model.

The development of neotissue in tissue engineered vascular grafts remains poorly understood. Advances in mouse genetic models have been highly informative in the study of vascular biology, but have been inaccessible to vascular tissue engineers due to technical limitations on the use of mouse recipients. To this end, we have developed a method for constructing sub-1mm internal diameter (ID) biodegradable scaffolds utilizing a dual cylinder chamber molding system and a hybrid polyester sealant scaled for use in a mouse model. Scaffolds constructed from either polyglycolic acid or poly-l-lactic acid nonwoven felts demonstrated sufficient porosity, biomechanical profile, and biocompatibility to function as vascular grafts. The scaffolds implanted as either inferior vena cava or aortic interposition grafts in SCID/bg mice demonstrated excellent patency without evidence of thromboembolic complications or aneurysm formation. A foreign body immune response was observed with marked macrophage infiltration and giant cell formation by post-operative week 3. Organized vascular neotissue, consisting of endothelialization, medial generation, and collagen deposition, was evident within the internal lumen of the scaffolds by post-operative week 6. These results present the ability to create sub-1mm ID biodegradable tubular scaffolds that are functional as vascular grafts, and provide an experimental approach for the study of vascular tissue engineering using mouse models.

Multilayer Nanofilms as Substrates for Hepatocellular Applications

Multilayer nanofilms, formed by the layer-by-layer (LbL) adsorption of positively and negatively charged polyelectrolytes, are promising substrates for tissue engineering. We investigate here the attachment and function of hepatic cells on multilayer films in terms of film composition, terminal layer, rigidity, charge, and presence of biofunctional species. Human hepatocellular carcinoma (HepG2) cells, adult rat hepatocytes (ARH), and human fetal hepatoblasts (HFHb) are studied on films composed of the polysaccharides chitosan (CHI) and alginate (ALG), the polypeptides poly(l-lysine) (PLL) and poly(l-glutamic acid) (PGA), and the synthetic polymers poly(allylamine hydrochloride) (PAH) and poly(styrene sulfonate) (PSS). The influence of chemical cross-linking following LbL assembly is also investigated. We find HepG2 to reach confluence after 7 days of culture on only 2 of 18 candidate multilayer systems: (PAH-PSS)(n) (i.e. nPAH-PSS bilayers) and cross-linked (PLL-ALG)(n)-PLL. Cross-linked PLL-ALG and PLL-PGA films support attachment and function of ARH, independently of the terminal layer, provided collagen is adsorbed to the top of the film. (PAH-PSS)(n), cross-linked (PLL-ALG)(n), and cross-linked (PLL-PGA)(n)-PLL films all support attachment, layer confluence, and function of HFHb, with the latter film promoting the greatest level of function at 8 days. Overall, film composition, terminal layer, and rigidity are key variables in promoting attachment and function of hepatic cells, while film charge and biofunctionality are somewhat less important. These studies reveal optimal candidate multilayer biomaterials for human liver tissue engineering applications.

Cellular distribution of injected PLGA-nanoparticles in the liver.

The cellular fate of nanoparticles in the liver is not fully understood. Because the effectiveness and safety of nanoparticles in liver therapy depends on targeting nanoparticles to the right cell populations, this study aimed to determine a relative distribution of PLGA-nanoparticles (sizes 271±1.4 nm) among liver cells in vivo. We found that Kupffer cells were the major cells that took up nanoparticles, followed by liver sinusoidal endothelial cells and hepatic stellate cells. Nanoparticles were found in only 7% of hepatocytes. Depletion of Kupffer cells by clodronate liposomes increased nanoparticle retention in liver sinusoidal endothelial cells and hepatic stellate cells, but not in hepatocytes. It is importantly suggested that studies of drug-loaded nanoparticle delivery to the liver have to demonstrate not only uptake of nanoparticles by the target cell type but also non-uptake by other cell types to assess their effect as well as ensure their safety.

Single-stranded γPNAs for in vivo site-specific genome editing via Watson-Crick recognition.

Triplex-forming peptide nucleic acids (PNAs) facilitate gene editing by stimulating recombination of donor DNAs within genomic DNA via site-specific formation of altered helical structures that further stimulate DNA repair. However, PNAs designed for triplex formation are sequence restricted to homopurine sites. Herein we describe a novel strategy where next generation single-stranded gamma PNAs (γPNAs) containing miniPEG substitutions at the gamma position can target genomic DNA in mouse bone marrow at mixed-sequence sites to induce targeted gene editing. In addition to enhanced binding, γPNAs confer increased solubility and improved formulation into poly(lactic-co-glycolic acid) (PLGA) nanoparticles for efficient intracellular delivery. Single-stranded γPNAs induce targeted gene editing at frequencies of 0.8% in mouse bone marrow cells treated ex vivo and 0.1% in vivo via IV injection, without detectable toxicity. These results suggest that γPNAs may provide a new tool for induced gene editing based on Watson-Crick recognition without sequence restriction.

Peptide Nucleic Acids as a Tool for Site-Specific Gene Editing

Peptide nucleic acids (PNAs) can bind duplex DNA in a sequence-targeted manner, forming a triplex structure capable of inducing DNA repair and producing specific genome modifications. Since the first description of PNA-mediated gene editing in cell free extracts, PNAs have been used to successfully correct human disease-causing mutations in cell culture and in vivo in preclinical mouse models. Gene correction via PNAs has resulted in clinically-relevant functional protein restoration and disease improvement, with low off-target genome effects, indicating a strong therapeutic potential for PNAs in the treatment or cure of genetic disorders. This review discusses the progress that has been made in developing PNAs as an effective, targeted agent for gene editing, with an emphasis on recent in vivo, nanoparticle-based strategies.

4.30 Nanomaterials for Drug Delivery to the Brain

Nanomaterials have emerged as important and versatile platforms for the delivery of therapeutics to the brain. This article describes the complex anatomy and physiology of the brain, which create challenges in treating diseases of the central nervous system, and current strategies using nanomedicines to address these challenges. We discuss various approaches to overcome the blood-brain barrier, examples of successful incorporation of therapeutics with nanomaterials, and strategies to achieve efficient delivery of nanomedicines into specific cells.

Abstract 4937: Fluorescence imaging using Clostridium Perfringens Enterotoxin carboxi-terminal fragment (c-CPE) to target metastatic chemotherapy-resistant human ovarian cancer in xenograft mice

Proceedings: AACR Annual Meeting 2014; April 5-9, 2014; San Diego, CA Epithelial ovarian cancer is the most lethal gynecologic malignancy. It is treated through up front surgery followed by chemotherapy or with neoadjuvant chemotherapy before surgical debulking. Achieving complete or optimal cytoreduction improves both progression free and overall survival. In the operating room, no matter the care taken, there is the potential for areas of macroscopic, microscopic and occult metastases to remain unvisualized. The development of a sensitive and specific intraoperative system for the visualization and removal or destruction of metastatic disease may improve patient outcome. Fresh ovarian cancer samples were recently analyzed by our group with genetic fingerprinting. This analysis revealed high expression of claudin-3 and -4, the epithelial receptors for Clostridium Perfringens Enterotoxin (CPE). Although the administration of the full length CPE in mice is toxic, the injection of the only carboxi-terminal fragment (c-CPE) avoids toxicity while preserving the binding to the receptors. Our previous data showed specific binding of FITC conjugated c-CPE (FITC-c-CPE) to primary ovarian cancer cell lines in vitro as well as preferential accumulation of the labeled peptide into ovarian cancer xenografts in vivo. This study evaluates the in vivo distribution of FITC-c-CPE after intraperitoneal (IP) injection of the peptide as well as the kinetics and tumor binding capacity of c-CPE conjugated to the NearInfraRed Dye CW800 (CW800-c-CPE), focusing on the ability of CW800-c-CPE to identify metastases of chemotherapy-resistant ovarian cancer overexpressing claudin-3 and -4 in vivo. We found that fluorescence uptake by the tumor starts 30 minutes after FITC-c-CPE injection with negligible staining of healthy organs. When the abdominal cavity of FITC-c-CPE injected mice was visualized using a fluorescence microscope, strong signal was detected in near microscopic metastatic nodules and in malignant tumor spheroids isolated from the ascites. Similarly, CW800-c-CPE also accumulated in tumors in vivo following IP or systemic (IV) injection. Ex vivo distribution analysis demonstrated a significantly higher mean fluorescence intensity (MFI) in tumor compared to healthy organs (MFI: mean ± STDV: 156.55 ± 23.73, 95.72 ± 18.19, 30.68 ± 5.88, 23.33 ± 4.05, 34.71 ± 12.71, 28.16 ± 6.1413.46 ± 1.35, 19.78 ± 5.43 in the tumor, kidney, liver, spleen, bowel, lungs and brain, respectively; p<0.01). The accumulation of CW800-c-CPE was also noted in small size tumor implants in the abdomen. These data suggest that c-CPE has tremendous specificity for targeting metastatic chemotherapy-resistant ovarian cancer in vivo. Furthermore, the c-CPE peptide has the potential to be implemented into the operative setting to allow for improved detection of residual tumor during staging and cytoreductive surgery for ovarian cancer patients. Citation Format: Emiliano Cocco, Sara Gasparrini, Erik M. Shapiro, Carlton Schwab, Stefania Bellone, Ileana Bortolomai, Salvatore Lopez, Natalia J. Sumi, Elena Bonazzoli, Roberta Nicoletti, Yang Deng, William M. Saltzman, Caroline J. Zeiss, Dan-Arin Silasi, Thomas J. Rutherford, Peter E. Schwartz, Alessandro D. Santin. Fluorescence imaging using Clostridium Perfringens Enterotoxin carboxi-terminal fragment (c-CPE) to target metastatic chemotherapy-resistant human ovarian cancer in xenograft mice. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 4937. doi:10.1158/1538-7445.AM2014-4937