Human cervicovaginal mucus contains an activity that hinders HIV-1 movement.

Cervical and vaginal epithelia are primary barriers against HIV type I (HIV-1) entry during male-to-female transmission. Cervical mucus (CM) is produced by the endocervix and forms a layer locally as well as in the vaginal compartment in the form of cervicovaginal mucus (CVM). To study the potential barrier function of each mucus type during HIV-1 transmission, we quantified HIV-1 mobility in CM and CVM ex vivo using fluorescent microscopy. Virions and 200-nm PEGylated beads were digitally tracked and mean-squared displacement was calculated. The mobility of beads increased significantly in CVM compared with CM, consistent with the known decreased mucin concentration of CVM. Unexpectedly, HIV-1 diffusion was significantly hindered in the same CVM samples in which bead diffusion was unhindered. Inhibition of virus transport was envelope-independent. Our results reveal a previously unknown activity in CVM that is capable of impeding HIV-1 mobility to enhance mucosal barrier function.

Lipid-coated microgels for the triggered release of doxorubicin.

We have systematically engineered a polymeric, multi-component drug delivery system composed of a lipid-coated hydrogel microparticle (microgel). The design of this delivery system was motivated by the recent elucidation of the mechanism of regulated secretion from the secretory granule and the compositional and structural features that underlie its ability to store and release endogenous drug-like compounds. The present work describes the assembly and response of a prototype construct which displays several important features of the secretory granule, including its high drug loading capacity, and triggered microgel swelling, resulting in the burst release of drug. To achieve this, ionic microgels were synthesized, and loaded with doxorubicin via ion exchange. These microgels were then coated with a lipid bilayer, and the release of doxorubicin was triggered from the gels using either lipid-solubilizing surfactants or electroporation. The use of a microanalytical technique is featured utilizing micropipette manipulation that allows the study of the behavior of individual microparticles. The lipid-coated microgels were electroporated in saline solution; they swelled and disrupted their bilayer coating over a period of several seconds and exchanged doxorubicin with the external plasma saline over a period of several minutes. It is envisioned that this system will ultimately find utility in drug delivery systems that are designed to release chemotherapeutic agents and peptides by the application of a triggering signal.

Residual oil fly ash and charged polymers activate epithelial cells and nociceptive sensory neurons.

Residual oil fly ash (ROFA) is an industrial pollutant that contains metals, acids, and unknown materials complexed to a particulate core. The heterogeneous composition of ROFA hampers finding the mechanism(s) by which it and other particulate pollutants cause airway toxicity. To distinguish culpable factors contributing to the effects of ROFA, synthetic polymer microsphere (SPM) analogs were synthesized that resembled ROFA in particle size (2 and 6 microm in diameter) and zeta potential (-29 mV). BEAS-2B human bronchial epithelial cells and dorsal root ganglion neurons responded to both ROFA and charged SPMs with an increase in intracellular Ca(2+) concentration ([Ca(2+)](i)) and the release of the proinflammatory cytokine interleukin-6, whereas neutral SPMs bound with polyethylene glycol (0-mV zeta potential) were relatively ineffective. In dorsal root ganglion neurons, the SPM-induced increases in [Ca(2+)](i) were correlated with the presence of acid- and/or capsaicin-sensitive pathways. We hypothesized that the acidic microenvironment associated with negatively charged colloids like ROFA and SPMs activate irritant receptors in airway target cells. This causes subsequent cytokine release, which mediates the pathophysiology of neurogenic airway inflammation.

A synthetic mimic of the secretory granule for drug delivery.

Secretory cells contain submicroscopic granules composed of a polyanionic polymer network that is collapsed owing to the presence of hydronium ions and weak base cations. The network is encapsulated within a lipid membrane, and functions as a vehicle for the osmotically inert storage of a variety of granule-bound endogenous mediator species, such as histamine, serotonin and proteases. These species are excreted from the granule and thence from the cell in response to external biochemical signals. Hydrogels that swell and shrink in response to external stimuli might serve as synthetic analogues of secretory granules. Here we describe the systematic engineering of multi-component, environmentally responsive hydrogel microspheres, coated with a lipid bilayer to mimic more closely the natural secretory granule. These microspheres exhibit pH- and ion-dependent volume phase transitions and ion-sensitive exchange of bound cations when the encapsulating lipid membrane is porated. We stimulated poration electrically in individual microgel particles immobilized and manipulated with a micropipette. This system could find use for the triggered release of encapsulated drugs in the body.

Electrochemistry of anticonvulsants: electron transfer as a possible mode of action.

Reduction potentials were determined for various anticonvulsants, including progabide, SL 75.102, CGS 9896, pyridazines, zonisamide, 1,2,3-triazoles, and copper complexes. The values generally were in the range of about -0.1 to -0.6 V for the protonated drugs and the metal complexes. Reduction potentials provide information on the feasibility of electron transfer (ET) in vivo. If the value is relatively positive (greater than about -0.6 V), the agent can act catalytically as an electron acceptor from an appropriate cellular donor. A concomitant favorable influence on abnormal neuronal processes associated with epilepsy could occur. We describe ET as a possible mode of action of anticonvulsants as well as some antiepileptic agents with no electrochemical data based on this hypothetical ET approach.

Electrochemistry of Cu(I) bipyridyl complexes with alkene, alkyne, and nitrile ligands. Implications for plant hormone action of ethylene.

The redox behavior was evaluated for several (BIPY)Cu(I) complexes (BIPY = 2,2'-bipyridyl) with unsaturated ligands by means of cyclic voltammetry in CH2Cl2 at reduced temperatures (-78 degrees, -23 degrees, 0 degree C). The complexes studied are [Cu(I)(BIPY)(C2H4)]PF6, [Cu(I)(BIPY)(3-hexyne)] PF6, [Cu(I)(BIPY)(DEAD)]PF6, ([Cu(I)(BIPY)]2 DEAD)[PF6]2 (DEAD = diethyl acetylene dicarboxylate) and [Cu(I)(BIPY)(CH3CN)]PF6. The oxidations are quasi-reversible at -78 degrees C for scan rates of 20 to 200 mV/sec. The reductions were irreversible on the CV time scale. Evidence is presented in support of a role for an electron transfer mechanism in the case of the plant hormone ethylene. Related literature data are also discussed.

Are reduction potentials of antifungal agents relevant to activity?

Cyclic voltammetry data were obtained for several categories of fungicidal agents including quinones (akrobomycin, podosporin A), iminium ions and precursors (pyridazines, 15-azahomosterol, griseofulvin-4'-oxime), and metal derivatives of chelators (pyridine-2-aldehyde thiosemicarbazones). The reductions usually occurred in the range of -0.7 to +0.3 V. Reduction potentials provide information on the feasibility of electron transfer in vivo. Catalytic production of oxidative stress from redox cycling is a possible mode of action. Alternatively, there may be interference with normal electron transport chains.

Theoretical calculations on calcium channel drugs: is electron transfer involved mechanistically?

Theoretical studies were done on calcium channel drugs in order to gain insight into the mode of action. Empirical force field calculations with nifedipine, a calcium channel antagonist, indicate that the E-conformation at the ring juncture is lower in energy than the Z-conformation. This energy difference is only 0.2 kcal/mol when the esters in the 3- and 5-positions of the dihydropyridine (DHP) ring are both synperiplanar (sp, sp). Molecular orbital calculations on the ground and excited states in the Z-conformation with the esters in the (ap, sp) conformation show a low lying excited state with substantial intramolecular electron transfer (ET) character. This excited state is only 1.8 eV higher in energy than the ground state and corresponds to a transfer of approximately 0.3 electron from the DHP ring to the nitrobenzene moiety. We suggest that ET may play an important role in the mechanism of action, either intramolecular or, as previously proposed, intermolecular, along with lipophilicity and steric effects.