ZnO Nano-Rod Devices for Intradermal Delivery and Immunization.

Intradermal delivery of antigens for vaccination is a very attractive approach since the skin provides a rich network of antigen presenting cells, which aid in stimulating an immune response. Numerous intradermal techniques have been developed to enhance penetration across the skin. However, these methods are invasive and/or affect the skin integrity. Hence, our group has devised zinc oxide (ZnO) nano-rods for non-destructive drug delivery. Chemical vapour deposition was used to fabricate aligned nano-rods on ZnO pre-coated silicon chips. The nano-rods' length and diameter were found to depend on the temperature, time, quality of sputtered silicon chips, etc. Vertically aligned ZnO nano-rods with lengths of 30-35 µm and diameters of 200-300 nm were selected for in vitro human skin permeation studies using Franz cells with Albumin-fluorescein isothiocyanate (FITC) absorbed on the nano-rods. Fluorescence and confocal studies on the skin samples showed FITC penetration through the skin along the channels formed by the nano-rods. Bradford protein assay on the collected fluid samples indicated a significant quantity of Albumin-FITC in the first 12 h. Low antibody titres were observed with immunisation on Balb/c mice with ovalbumin (OVA) antigen coated on the nano-rod chips. Nonetheless, due to the reduced dimensions of the nano-rods, our device offers the additional advantage of excluding the simultaneous entrance of microbial pathogens. Taken together, these results showed that ZnO nano-rods hold the potential for a safe, non-invasive, and painless intradermal drug delivery.

In vivo biodistribution of platinum-based drugs encapsulated into multi-walled carbon nanotubes.

Carbon nanotubes (CNTs) are promising drug delivery systems due to their external functionalizable surface and their hollowed cavity that can encapsulate several bioactive molecules. In this study, the chemotherapeutic drug cisplatin or an inert platinum(IV) complex were entrapped inside functionalized-multi-walled-CNTs and intravenously injected into mice to investigate the influence of CNTs on the biodistribution of Pt-based molecules. The platinum levels in vital organs suggested that functionalized-CNTs did not affect cisplatin distribution, while they significantly enhanced the accumulation of Pt(IV) sample in some tissues (e.g. in the lungs, suggesting their potential application in lung cancer therapy) and reduced both kidney and liver accumulation (thus decreasing eventual nephrotoxicity, a typical side effect of cisplatin). Concurrently, CNTs did not induce any intrinsic abnormal immune response or inflammation, as confirmed by normal cytokine levels and histological evaluations. Therefore, functionalized nanotubes represent an efficient nano-carrier to improve accumulation of Pt species in targeted tissues/organs. From the clinical editor: In this preclinical study functionalized carbon nanotubes are reported to be safe and efficient for targeted delivery of platinum-containing compounds in rodents. Approaches like this may improve the treatment of specific cancers, since platinum based chemotherapies are commonly used, yet limited by toxicity and relatively poor target tissue concentration.

CD137 ligand signaling enhances myelopoiesis during infections.

CD137 and its ligand are expressed in the BM, and conflicting data exist on the regulation of myelopoiesis by the CD137 receptor-ligand system. CD137(-/-) mice have increased numbers of myeloid cells in the BM, indicating an inhibitory influence of CD137 on myelopoiesis. However, CD137 also induces proliferation of hematopoietic progenitor cells and their myeloid differentiation, arguing for an enhancing effect. Here we hypothesized that this latter case represents the situation during infections since expression of CD137 is activation dependent and strongly enhanced during inflammation. Indeed, infections with Influenza, Bordetella pertussis, Mycobacterium bovis, Bacille Calmette-Guérin or Escherichia coli or i.p. injection of LPS led to increased numbers of CD137-expressing cells, especially of CD4(+) T cells in the BM of mice. Coculture experiments confirmed that CD137 expression enables CD4(+) T cells to induce proliferation and myeloid differentiation of BM and hematopoietic progenitor cells. CD137 also enhances myelopoiesis in vivo since the infection-induced increase in myeloid cell proliferation and total myeloid cell numbers in the BM were significantly lower in CD137(-/-) mice. This study reconciles earlier conflicting data by demonstrating that while CD137-CD137L interactions inhibit myelopoiesis during steady-state conditions they increase myelopoiesis during infection.