Targeting tumor cells using magnetic nanoparticles - a feasibility study in animal models.

INTRODUCTION: In non-resectable tumors, chemotherapy is crucial to improve patient survival. However, it is often accompanied by considerable side effects. Targeted delivery of chemotherapy by coupling with iron oxide superparamagnetic nanoparticles (IONP) could potentially increase efficacy while decreasing adverse systemic side effects. We aimed to evaluate the feasibility of targeting nontoxic, biodegradable-IONP into tumors in-vivo by applying an external magnetic field. MATERIAL AND METHODS: Subcutaneous colon carcinoma tumors were induced in 35 mice. IONP was injected systemically, followed by suturing of a magnet on top of the tumors for 2-24 h. Tumors and livers were excised and stained for iron to explore IONP localization. RESULTS: Iron staining was evident in 43% and 20% of tumors exposed to magnets for 4 h or 24 h, respectively. No iron was present following 2 h exposure, nor in the control group; however, iron stain in the livers indicates most of the IONP were cleared by the liver 24 h later. CONCLUSION: We demonstrated the targeting feasibility of IONP to tumor tissue by an external magnetic field. Our data shows successful targeting; however, with low efficacy following systemic injection of the IONP. As such, a paradigm shift is strongly recommended from systemic to locoregional IONP injection to increase targeting efficacy.

Lung Based Engineered Micro-Pancreas Sustains Human Beta Cell Survival and Functionality.

The whole world has been affected by a dramatically increasing prevalence of diabetes. Today, the etiology of both type 1 and type 2 diabetes is thought to revolve around the dysfunction of ß-cells, the insulin producing cells of the body. Within the pharmaceutical industry, the evaluation of new drugs for diabetes treatment is mostly done using cell lines or rodent islets and depends solely on the assessment of static insulin secretion. However, the use of cell lines or rodent islets is limiting lack of similarity of the human islet cells, leading to a constrain of the predictive value regarding the clinical potential of newly developed drugs. To overcome this issue, we developed an Engineered Micro-Pancreas as a unique platform for drug discovery. The Engineered Micro Pancreas is composed of (i) an organ-derived micro-scaffold, specifically a decellularized porcine lung-derived micro-scaffold and (ii) cadaveric islets seeded thereon. The Engineered Micro Pancreas remained viable and maintained insulin secretion in vitro for up to three months. The quantities of insulin were comparable to those secreted by freshly isolated human islets and therefore hold the potential for real-time and metabolic physiology mimicking drug screening.

Characterization of factors that determine lentiviral vector tropism in skin tissue using an ex vivo model.

BACKGROUND: Lentiviral tropism to a solid tissue may be determined by receptor availability, the differentiation state of cells and the three-dimensional architecture of the tissue. METHODS: Using skin organ cultures, lentiviral vector tropism was compared with that of keratinocytes in cell culture. Furthermore, the tropism of lentiviral vector to mouse and human tissues was compared ex vivo, in attempt to validate the mouse skin as an experimental system for human gene therapy of skin diseases. RESULTS: The results obtained indicated that although early progenitor keratinocytes (keratin 15+ and p63+), when grown in culture are permissive to lentiviral vector, they are resistant to transduction in their native 'niche' in the skin tissue. Transiently amplifying keratinocytes (keratin 14+) on the other hand, are permissive to lentiviral vector transduction, in cell culture and in the skin, after separation of the epidermis from the dermis layer. Keratinocytes (keratin 14+) in the hair follicle of human skin are resistant to lentiviral transduction, even after partial digestion of the extracellular matrix collagen. By contrast, collagenase pretreatment of mouse tissue facilitated transduction of keratinocytes within the hair follicle. Because lentivirus pseudotyped by two envelopes (amphotropic murine leukemia virus and vesicular stomatitis virus G glycoprotein) display the same tropism, we suggest that receptor availability is not the critical factor in the pattern of skin tissue transduction. CONCLUSIONS: Taken together, the results obtained in the present study indicate that lentiviral vector tropism in the three-dimensional skin tissue is distinct from the tropism to keratinocytes in culture and is dependent on a complex interplay of extracellular restrictions.

Biopump: Autologous skin-derived micro-organ genetically engineered to provide sustained continuous secretion of therapeutic proteins.

A novel approach for sustained production of therapeutic proteins is described, using genetic modification of intact autologous micro-organ tissue explants from the subject's own skin. The skin-derived micro-organ can be maintained viable ex vivo for extended periods and is transduced with a transgene encoding a desired therapeutic protein, resulting in protein-secreting micro-organ (biopump (BP)). The daily protein production from each BP is quantified, enabling drug dosing by subcutaneous implantation of the requisite number of BPs into the patient to provide continuous production to the circulation of a known amount of the therapeutic protein. Each implanted BP remains localized and is accessible, to enable removal or ablation if needed. Examples from preclinical and clinical studies are presented, including use of associated virus vector 1 and helper-dependent adenoviral vectors producing BPs to provide long-term sustained secretion of recombinant interferon-α and erythropoietin.

Tropism of lentiviral vectors in skin tissue.

The skin is an attractive tissue for gene therapy applications to treat genetic disorders and to express systemically delivered transgenes encoding therapeutic proteins. Understanding the tissue tropism of vectors is a prerequisite for the design of gene therapy trials. Using an ex vivo system of organ culture, we studied factors that determined viral tropism to the epidermal and dermal cells in human and mouse skin. We applied in these studies a lentiviral vector pseudotyped with two glycoproteins that use different cell receptors (vesicular stomatitis virus glycoprotein [VSV-G] and amphotropic murine leukemia virus envelope). The extent of infection with the amphotropic pseudotype was much higher than that of VSV-G, especially at low multiplicities of infection. In contrast, the tropism of these two pseudotypes in skin tissues was similar; at low multiplicities the infection was limited to areas near the basal layer of the epidermis, whereas at high multiplicities the infection extended to the dermal layer. To overcome physical barriers in the skin, the epidermal and dermal layers were separated and infected. Whereas the human epidermis was readily infected, we could not detect infection of stem and early progenitor cells in their niche. In contrast, mouse epidermis was completely resistant to infection. Dermal cells of both species were readily infected with the two pseudotypes. Molecular analysis indicated that infection of mouse epidermal cells was restricted after proviral DNA synthesis and before integration. In conclusion, we show that lentiviral tropism in a solid tissue is dependent on several factors, extra- and intracellular, distinct of the cellular receptors.