Folate-linked lipoplexes for short hairpin RNA targeting claudin-3 delivery in ovarian cancer xenografts

Ovarian cancers highly overexpress folate receptor α (FRα) and claudin3 (CLDN3), both of which are associated with tumor progression and poor prognosis of patients. Downregulation of FRα and CLDN3 in ovarian cancer may suppress tumor growth and promote benign differentiation of tumor. In this study, F-P-LP/CLDN3, a FRα targeted liposome loading with short hairpin RNA (shRNA) targeting CLDN3 was prepared and the pharmaceutical properties were characterized. Then, the antitumor effect of F-P-LP/CLDN3 was studied in an in vivo model of advanced ovarian cancer. Compared with Control, F-P-LP/CLDN3 promoted benign differentiation of tumor and achieved about 90% tumor growth inhibition. In the meantime, malignant ascites production was completely inhibited, and tumor nodule number and tumor weight were significantly reduced (p < 0.001). FRα and CLDN3 were downregulated together in tumor tissues treated by F-P-LP/CLDN3. The antitumor mechanisms were achieved by promoting tumor cell apoptosis, inhibiting tumor cell proliferation and reducing microvessel density. Finally, safety evaluation indicated that F-P-LP/CLDN3 was a safe formulation in intraperitoneally administered cancer therapy. We come to a conclusion that F-P-LP/CLDN3 is a potential targeting formulation for ovarian cancer gene therapy.     

Device-directed therapeutic drug delivery systems.

To increase the therapeutic effectiveness of device-directed drug delivery systems for diseased cardiovascular tissues and cancerous tissues, new devices and new functional biomaterials were devised to meet the requirements as listed below: drug-infusible balloon catheter, drug-releasable and covered stents, and in situ hydrogelation on and in cancerous tissues. New therapeutic strategies based on these devices were discussed.     

Improvement of QOL by drug delivery systems

The objectives of the medical advancements made in recent years are i) the cure of diseases and relief of their symptoms, ii) expansion of life expectancy, iii) improvement of QOL (quality of life), and iv) prevention of diseases. Most importantly, the therapy should maintain the dignity of patients. DDS is defined as a highly-functional dosage form for improving the medical usefulness of drugs by potentiating their efficacy, reducing their toxicity, and making them a 'patient-friendly medicine'. DDS is strongly expected for achieving 1) the controlled release, 2) new alternative mucosal absorption, and 3) targeting to the action site of drugs. The improvements of QOL by devising novel DDS such as Lupron Depot, Imigran Nasal Spray, Durotep Patch and Pegasys were reviewed.     

Sensitizing hormone-refractory prostate cancer cells to drug treatment by targeting 14-3-3sigma

Advanced and hormone-refractory prostate cancer has long been considered as a chemoresistant disease. Recently, it was found that 14-3-3sigma expression increases as prostate tumor progresses, and that 14-3-3sigma contributes significantly to drug resistance in breast cancers. We, thus, hypothesized that advanced and hormone-refractory prostate cancers may have an increased level of 14-3-3sigma, which in turn may contribute to drug resistance in advanced and hormone-refractory prostate cancers. In this study, we tested this hypothesis and found that, indeed, the expression level of 14-3-3sigma in androgen-independent prostate cancer cell lines DU145, PC3, and CWR22RV are much higher than that in the androgen-dependent cell line LNCaP, and that the androgen-independent cells are more resistant to mitoxantrone and Adriamycin than the androgen-dependent cells. Depleting 14-3-3sigma expression in DU145 and CWR22RV by RNA interference significantly sensitized these cells to mitoxantrone and Adriamycin by abrogating G2-M checkpoint and increasing apoptosis, whereas restoring 14-3-3sigma expression in LNCaP cells enhanced drug resistance. We also showed that 14-3-3sigma deficiency caused nuclear localization of Cdc2 and dephosphorylation of the Tyr15 residue upon DNA damage. Based on these studies, we propose that therapeutic intervention targeting 14-3-3sigma may be useful for sensitizing hormone-refractory prostate cancers to chemotherapy by both G2-M checkpoint abrogation and apoptosis enhancement.     

Floating drug delivery systems: an approach to oral controlled drug delivery via gastric retention.

In recent years scientific and technological advancements have been made in the research and development of rate-controlled oral drug delivery systems by overcoming physiological adversities, such as short gastric residence times (GRT) and unpredictable gastric emptying times (GET). Several approaches are currently utilized in the prolongation of the GRT, including floating drug delivery systems (FDDS), also known as hydrodynamically balanced systems (HBS), swelling and expanding systems, polymeric bioadhesive systems, modified-shape systems, high-density systems, and other delayed gastric emptying devices. In this review, the current technological developments of FDDS including patented delivery systems and marketed products, and their advantages and future potential for oral controlled drug delivery are discussed.     

Neonatal drug monitoring and drug delivery systems

The problems associated with drug delivery and achievement of therapeutic blood levels in neonates are reviewed, using chloramphenicol as an example. Administration of small volumes, concentrated solutions and intravenous line filter chambers greatly affect the final dose delivered to the infant. Once delivered, variability in drug elimination caused by changing hepatic and renal function and protein binding necessitate careful drug monitoring and pharmacokinetic analysis especially with drugs like chloramphenicol that have a narrow therapeutic range. If one uses a team approach involving nurses, clinical chemists and clinical pharmacologists, optimal doses of chloramphenicol in the newborn are achieved more consistently.     

Evaluation of cell penetrating peptides fused to elastin-like polypeptide for drug delivery.

Translocation through the plasma membrane is a major limiting step for the cellular delivery of macromolecules. Several cell penetrating peptides (CPP) have been demonstrated to efficiently internalize various molecular cargo to targets inside eukaryotic cells. In this study, the efficiency and mechanism of cellular uptake of the CPPs penetratin, Tat, and MTS fused to elastin-like polypeptides (CPP-ELP) were evaluated. Elastin-like polypeptides are biopolymers with features that make them useful as polymeric carriers for the delivery of therapeutics. Therefore, improving efficiency of cellular uptake by fusing ELPs to CPPs and understanding the mechanism of their cellular internalization could contribute to development of new therapeutic approaches. Flow cytometry and confocal fluorescence microscopy were used to elucidate the mechanism of CPP-ELP uptake. The internalization of all CPP-ELPs was impaired dramatically at 4 degrees C, under ATP depletion conditions, and with hyperosmolar sucrose, implicating involvement of an endocytic pathway for CPP-ELP internalization. Penetratin was identified as the most effective CPP for delivering ELP. Finally, in order to demonstrate the potential of CPP-ELP for drug delivery, a fusion polypeptide was made containing penetratin, ELP, and a peptide derived from the cyclin-dependent kinase inhibitor p21. This polypeptide was shown to inhibit proliferation of SKOV-3 and HeLa cells by slowing their growth rate.     

Humanized docking system for assembly of targeting drug delivery complexes.

Targeted drug delivery requires 'loading' drugs onto targeting proteins. Traditional technologies for loading drugs rely on chemical conjugation of drugs or drug carriers to targeting proteins. An alternative approach might rely on assembly of targeting complexes using a docking system that includes two components: a 'docking' tag fused to a targeting protein, and a 'payload' module containing an adapter protein for non-covalent binding to the docking tag. We describe here a fully humanized adapter/docking tag system based on non-covalent interaction between two fragments of human pancreatic RNase I. A 15 amino acid long N-terminal fragment of RNase I designed to serve as a docking tag, was fused to the N-terminus of human vascular endothelial growth factor that served as a targeting protein. An 18-125 and an 18-127 amino acid long fragments of RNase I were engineered, expressed and refolded into active conformations to serve as adapter proteins. Interactions between the targeting and adapter proteins were characterized using enzymatic analysis and surface plasmon resonance. Targeting DNA delivery complexes were assembled, characterized by dynamic light scattering, and found to be very effective in receptor-mediated DNA delivery.     

Structure and design of polymeric surfactant-based drug delivery systems.

The review concentrates on the use of polymeric micelles as pharmaceutical carriers. Micellization of biologically active substances is a general phenomenon that increases the bioavailability of lipophilic drugs and nutrients. Currently used low-molecular-weight pharmaceutical surfactants have low toxicity and high solubilization power towards poorly soluble pharmaceuticals. However, micelles made of such surfactants usually have relatively high critical micelle concentration (CMC) and are unstable upon strong dilution (for example, with the blood volume upon intravenous administration). On the other hand, amphiphilic block co-polymers are also known to form spherical micelles in solution. These micelles have very high solubilization capacity and rather low CMC value that makes them very stable in vivo. Amphiphilic block co-polymers suitable for micelle preparation are described and various types of polymeric micelles are considered as well as mechanisms of their formation, factors influencing their stability and disintegration, their loading capacity towards various poorly soluble pharmaceuticals, and their therapeutic potential. The basic mechanisms underlying micelle longevity and steric protection in vivo are considered with a special emphasis on long circulating drug delivery systems. Advantages and disadvantages of micelles when compared with other drug delivery systems are considered. New polymer-lipid amphiphilic compounds such as diacyillipid-polyethylene glycol, are described and discussed. These compounds are very attractive from a practical point of view, since they easily micellize yielding extremely stable micelles with very high loading capacity. Micelle passive accumulation in the areas with leaky vasculature (tumors, infarct zones) is discussed as an important physiology-based mechanism of drug delivery into certain target zones. Targeted polymeric micelles prepared by using thermo- or pH-sensitive components or by attaching specific targeted moieties (such as antibodies) to their outer surface are described as well as their preparation and some in vivo properties. The fast growing field of diagnostic micelles is analyzed. Polymeric micelles are considered loaded with various agents for gamma, magnetic resonance, and computed tomography imaging. Their in vitro and in vivo properties are discussed and the results of the initial animal experiments are presented.     

Molecular engineering of proteins and polymers for targeting and intracellular delivery of therapeutics.

There are many protein and DNA based therapeutics under development in the biotechnology and pharmaceutical industries. Key delivery challenges remain before many of these biomolecular therapeutics reach the clinic. Two important barriers are the effective targeting of drugs to specific tissues and cells and the subsequent intracellular delivery to appropriate cellular compartments. In this review, we summarize protein engineering work aimed at improving the stability and refolding efficiency of antibody fragments used in targeting, and at constructing new streptavidin variants which may offer improved performance in pre-targeting delivery strategies. In addition, we review recent work with pH-responsive polymers that mimic the membrane disruptive properties of viruses and toxins. These polymers could serve as alternatives to fusogenic peptides in gene therapy formulations and to enhance the intracellular delivery of protein therapeutics that function in the cytoplasm.     

Intracellular drug delivery by sulfatide-mediated liposomes to gliomas.

We described here a liposomal carrier system in which the targeting ligand was sulfatide, a glycosphingolipid known to bind several extracellular matrix (ECM) glycoproteins whose expression was highly up-regulated in many tumors. In vitro experiments with human glioma cell lines demonstrated that robust intracellular uptake of the liposomes depended specifically on the presence of sulfatide as the key liposomal component. Significant amount of the liposomes remained largely intact in the cytoplasm for hours following their internalization. When anticancer drug doxorubicin (DOX) was encapsulated in such liposomes, most of the drug was preferably delivered into the cell nuclei to exert its cytotoxicity. Use of this drug delivery system to deliver DOX for treatment of tumor-bearing nude mice displayed much improved therapeutic effects over the free drug or the drug carried by polyethylene glycol (PEG)-grafted liposomes. Our results demonstrate a close link between effective intracellular uptake of the drug delivery system and its therapeutic outcome. Moreover, the sulfatide-containing liposomes (SCL) may represent an interesting ligand-targeted drug carrier for a wide spectrum of cancers in which sulfatide-binding ECM glycoproteins are expressed.     

New biodegradable polymers for injectable drug delivery systems.

Many biodegradable polymers were used for drug delivery and some are successful for human application. There remains fabrication problems, such as difficult processability and limited organic solvent and irreproducible drug release kinetics. New star-shaped block copolymers, of which the typical molecular architecture is presented, results from their distinct solution properties, thermal properties and morphology. Their unique physical properties are due to the three-dimensional, hyperbranched molecular architecture and influence microsphere fabrication, drug release and degradation profiles. We recently synthesized thermosensitive biodegradable hydrogel consisting of polyethylene oxide and poly(L-lactic acid). Aqueous solution of these copolymers with proper combination of molecular weights exhibit temperature-dependent reversible sol-gel transition. Desired molecular arrangements provide unique behavior that sol (at low temperature) form gel (at body temperature). The use of these two biodegradable polymers have great advantages for sustained injectable drug delivery systems. The formulation is simple, which is totally free of organic solvent. In sol or aqueous solution state of this polymer solubilized hydrophobic drugs prior to form gel matrix.