A crosslinked dextran sulfate-chitosan nanoparticle for delivery of therapeutic heparin-binding proteins.

Negatively charged dextran sulfate (DS)-chitosan nanoparticles (DSCS NPs) contain a DS outer shell with binding properties similar to those of heparin and are useful for the incorporation and delivery of therapeutic heparin-binding proteins. These particles, however, are unstable in physiological salt solutions due to their formation through electrostatic interactions. In the present study, a method was developed to covalently crosslink chitosan in the core of the DSCS NP with a short chain dicarboxylic acid (succinate), while leaving the outer shell of the particle untouched. The crosslinked particles, XDSCS NPs, are stable in NaCl solutions up to 3 M. XDSCS NPs were able to incorporate heparin-binding proteins (VEGF and SDF-1α) rapidly and efficiently, and maintain the full biological activity of the proteins. The incorporated proteins were not released from the particles after a 14-day incubation period at 37 °C in PBS, but retained the same activity as those stored at 4 °C. When aerosolized for delivery to the lungs of rats, XDSCS NP-incorporated SDF-1α showed a ∼17-fold greater retention time compared to that of free protein. These properties suggest that XDSCS NPs could be beneficial for the delivery of therapeutic heparin-binding proteins to achieve sustained in vivo effects.

Incorporation of heparin-binding proteins into preformed dextran sulfate-chitosan nanoparticles.

Incorporation of proteins into dextran sulfate (DS)-chitosan (CS) nanoparticles (DSCS NPs) is commonly performed using entrapment procedures, in which protein molecules are mixed with DS and CS until particle formation occurs. As DS is an analog of heparin, the authors examined whether proteins could be directly incorporated into preformed DSCS NPs through a heparin binding domain-mediated interaction. The authors formulated negatively-charged DSCS NPs, and quantified the amount of charged DS in the outer shell of the particles. The authors then mixed the DSCS NPs with heparin-binding proteins (SDF-1α, VEGF, FGF-2, BMP-2, or lysozyme) to achieve incorporation. Data show that for DSCS NPs containing 100 nmol charged glucose sulfate units in DS, up to ~1.5 nmol of monomeric or ~0.75 nmol of dimeric heparin-binding proteins were incorporated without significantly altering the size or zeta potential of the particles. Incorporation efficiencies of these proteins were 95%-100%. In contrast, serum albumin or serum globulin showed minimal incorporation (8% and 4%, respectively) in 50% physiological saline, despite their large adsorption in water (80% and 92%, respectively). The NP-incorporated SDF-1α and VEGF exhibited full activity and sustained thermal stability. An in vivo aerosolization study showed that NP-incorporated SDF-1α persisted in rat lungs for 72 h (~34% remaining), while free SDF-1α was no longer detectable after 16 h. As many growth factors and cytokines contain heparin-binding sites/domains, incorporation into preformed DSCS NPs could facilitate in vivo applications of these proteins.

A Unique Case of Mediastinal Teratoma with Mature Pancreatic Tissue, Nesidioblastosis, and Aberrant Islet Differentiation: a Case Report and Literature Review.

Mediastinal teratomas with elements of mature pancreatic tissue are rare. Only a very few cases of pancreatic tissue with nesidioblastosis in teratoma have been reported. Here, we report a case of a 12-year-old male who presented with pleural effusion and was revealed to have a large anterior mediastinal mass. Biopsy of the mass revealed benign mature teratoma. After biopsy, the teratoma ruptured into the right thoracic cavity. It was then excised and sent to pathology for further evaluation. Preoperatively, there was no evidence of hyperinsulinemia or hypoglycemia. Postoperatively, there was no change in blood glucose levels. Histologically, the mass showed large areas of mature pancreatic tissue flanking a small intestine-like structure. Numerous endocrine cell islets, poorly defined groups of neuroendocrine cells and ductular-insular complexes characteristic of nesidioblastosis were dispersed in the exocrine pancreatic parenchyma. In addition, other parts of the tumor containing keratinizing squamous epithelium with cutaneous adnexal glands, small intestine, and bronchus including cartilage and respiratory epithelium were observed. Some islets contained two or more cell types while others were monophenotypic. Immunohistochemical staining showed pronounced expression of pancreatic polypeptide, moderate expression of somatostatin and insulin and nearly complete absence of glucagon-containing cells. The selective deletion of glucagon might hold clues to an important regulatory mechanism in pancreatic development.

Disproportionate hyperproinsulinemia, beta-cell restricted prohormone convertase 2 deficiency, and cell cycle inhibitors expression by human islets transplanted into athymic nude mice: insights into nonimmune-mediated mechanisms of delayed islet graft failure.

To learn more about nonimmune-mediated islet graft failure, we transplanted different preparations (preps) of isolated human islets under the kidney capsule of streptozotocin (STZ)-diabetic nude mice. One month after the implantation of 1,000 or 2,000 islets, grafts were harvested for morphological, immunohistochemical, and ultrastructural analysis. Only a single islet prep cured the diabetes out of all the recipients, while the remaining preps showed only partial function after the implantation of 2,000 islets. Transplanted mice showed high circulating proinsulin levels but, with the exclusion of those bearing curative grafts, relatively low mature insulin levels. Engrafted beta-cells showed positive carboxypeptidase E (CPE) and prohormone convertase 1 (PC1) staining, while prohormone convertase 2 (PC2) was undetectable. In contrast, PC2 was abundantly expressed by engrafted alpha-cells. Moreover, engrafted beta-cells did not show evidence of replication, and preapoptotic beta-cells, with intra- and extracellular amyloid deposition, were detected with electron microscopy. Cell cycle inhibitors p16(INK4), p21(WAF1), and p27(Kip1) were abundantly expressed in the islet grafts and showed a predominant nuclear localization. In conclusion, diabetic nude mice transplanted with human islets showed disproportionate hyperproinsulinemia and graft evidence of beta-cell restricted PC2 depletion, amyloid deposition and beta-cell death, and lack of beta-cell replication with nuclear translocation of p27(Kip1) and p21(WAF1) that together may contribute to delayed graft failure.