Mathematical modelling of drug delivery from pH-responsive nanocontainers.

Targeted drug delivery systems represent a promising strategy to treat localised disease with minimum impact on the surrounding tissue. In particular, polymeric nanocontainers have attracted major interest because of their structural and morphological advantages and the variety of polymers that can be used, allowing the synthesis of materials capable of responding to the biochemical alterations of the environment. While experimental methodologies can provide much insight, the generation of experimental data across a wide parameter space is usually prohibitively time consuming and/or expensive. To better understand the influence of varying design parameters on the release profile and drug kinetics involved, appropriately-designed mathematical models are of great benefit. Here, we developed a continuum-scale mathematical model to describe drug transport within, and release from, a hollow nanocontainer consisting of a core and a pH-responsive polymeric shell. Our two-layer mathematical model accounts for drug dissolution and diffusion and includes a mechanism to account for trapping of drug molecules within the shell. We conduct a sensitivity analysis to assess the effect of varying the model parameters on the overall behaviour of the system. To demonstrate the usefulness of our model, we focus on the particular case of cancer treatment and calibrate the model against release profile data for two anti-cancer therapeutical agents. We show that the model is capable of capturing the experimentally observed pH-dependent release.

Fatty acid-related modulations of membrane fluidity in cells: detection and implications.

Metabolic homeostasis of fatty acids is complex and well-regulated in all organisms. The biosynthesis of saturated fatty acids (SFA) in mammals provides substrates for ß-oxidation and ATP production. Monounsaturated fatty acids (MUFA) are products of desaturases that introduce a methylene group in cis geometry in SFA. Polyunsaturated fatty acids (n-6 and n-3 PUFA) are products of elongation and desaturation of the essential linoleic acid and α-linolenic acid, respectively. The liver processes dietary fatty acids and exports them in lipoproteins for distribution and storage in peripheral tissues. The three types of fatty acids are integrated in membrane phospholipids and determine their biophysical properties and functions. This study was aimed at investigating effects of fatty acids on membrane biophysical properties under varying nutritional and pathological conditions, by integrating lipidomic analysis of membrane phospholipids with functional two-photon microscopy (fTPM) of cellular membranes. This approach was applied to two case studies: first, pancreatic beta-cells, to investigate hormetic and detrimental effects of lipids. Second, red blood cells extracted from a genetic mouse model defective in lipoproteins, to understand the role of lipids in hepatic diseases and metabolic syndrome and their effect on circulating cells.

Effects of bleomycin and antioxidants on the fatty acid profile of testicular cancer cell membranes.

Bleomycin is used in chemotherapy regimens for the treatment of patients having testicular germ-cell tumor (TGCT). There is no study in the literature investigating the effects of bleomycin on membrane lipid profile in testicular cancer cells. We investigated membrane fatty acid (FA) profiles isolated, derivatized and analyzed by gas chromatography of NTera-2 testicular cancer cells incubated with bleomycin (Bleo) for 24 h in the absence and presence of N-Acetyl-L-Cysteine (NAC) and curcumin (Cur) as commonly used antioxidant adjuvants. At the same time the MAPK pathway and EGFR levels were followed up. Bleomycin treatment increased significantly saturated fatty acids (SFA) of phospholipids at the expense of monounsaturated (MUFA) and polyunsaturated fatty acids (PUFA). Bleomycin also led to a significant increase in the trans lipid isomers of oleic and arachidonic acids due to its free radical producing effect. Incubation with bleomycin increased the p38 MAPK and JNK levels and downregulated EGFR pathway. Coincubation of bleomycin with NAC reversed effects caused by bleomycin. Our results highlight the important role of membrane fatty acid remodeling occurring during the use of bleomycin and its concurrent use with antioxidants which can adjuvate the cytotoxic effects of the chemotherapeutic agents.

trans Arachidonic acid isomers inhibit NADPH-oxidase activity by direct interaction with enzyme components.

NADPH-oxidase is an enzyme that represents, when activated, the major source of non-mitochondrial reactive oxygen species. In phagocytes, this production is an indispensable event for the destruction of engulfed pathogens. The functional NADPH-oxidase complex consists of a catalytic membrane flavocytochrome b (Cytb(558)) and four cytosolic proteins p47(phox), p67(phox), Rac and p40(phox). The NADPH-oxidase activity is finely regulated spatially and temporally by cellular signaling events that trigger the translocation of the cytosolic subunits to its membrane partner involving post-translational modifications and activation by second messengers such as arachidonic acid (AA). Arachidonic acid in its natural cis-poly unsaturated form (C20:4) has been described to be an efficient activator of the enzyme in vivo and in vitro. In this work, we examined in a cell-free system whether a change of the natural cis geometry to the trans configuration, which could occur either by diet or be produced by the action of free radicals, may have consequences on the functioning of NADPH-oxidase. We showed the inability of mono-trans AA isomers to activate the NADPH-oxidase complex and demonstrated the inhibitory effect on the cis-AA-induced NADPH oxidase activation. The inhibition is mediated by a direct effect of the mono-trans AA which targets both the membrane fraction containing the cytb(558) and the cytosolic p67(phox). Our results suggest that the loss of the natural geometric feature (cis-AA) induces substantial structural modifications of p67(phox) that prevent its translocation to the complex.

Combined Raman and IR spectroscopic study on the radical-based modifications of methionine.

Among damages reported to occur on proteins, radical-based changes of methionine (Met) residues are one of the most important convalent post-translational modifications. The combined application of Raman and infrared (IR) spectroscopies for the characterisation of the radical-induced modifications of Met is described here. Gamma-irradiation was used to simulate the endogenous formation of reactive species such as hydrogen atoms (•H), hydroxyl radicals (•OH) and hydrogen peroxide (H(2)O(2)). These spectroscopic techniques coupled to mass experiments are suitable tools in detecting almost all the main radical-induced degradation products of Met that depend on the nature of the reactive species. In particular, Raman spectroscopy is useful in revealing the radical-induced modifications in the sulphur-containing moiety, whereas the IR spectra allow decarboxylation and deamination processes to be detected, as well as the formation of other degradation products. Thus, some band patterns useful for building a library of spectra-structure correlation for radical-based degradation of Met were identified. In particular, the bands due to the formation of methionine sulfoxide, the main oxidation product of Met, have been identified. All together, these results combine to produce a set of spectroscopic markers of the main processes occurring as a consequence of radical stress exposure, which can be used in a spectroscopic protocol for providing a first assessment of Met modifications in more complex systems such as peptides and proteins, and monitoring their impact on protein structure.

Investigation of radical-based damage of RNase A in aqueous solution and lipid vesicles.

The gamma-irradiation of bovine pancreatic ribonuclease A (RNase A) in aqueous solution were investigated at different doses by vibrational spectroscopy as well as enzymatic assay, electrophoresis, and HPLC analysis. Both functional and structural changes of the protein were caused by attack of H(*) atoms and (*)OH radicals. In particular, Raman spectroscopy was shown to be a useful tool in identifying conformational changes of the protein structure and amino acidic residues that are preferential sites of the radical attack (i.e., tyrosine and methionine). After partial structural changes by the initial radical attack, the internal sulfur-containing amino acid residues were rendered susceptible to transformation. By using the biomimetic model of dioleoyl phosphatidyl choline vesicle suspensions containing RNase A, the damage to methione residues could be connected to a parallel alteration of membrane unsaturated lipids. In fact, thiyl radical species formed from protein degradation can diffuse into the lipid bilayer and cause isomerization of the naturally occurring cis double bonds. As a consequence, trans unsaturated fatty acids are formed in vesicles and can be considered to be markers of this protein damage.

Reactivity of tris(trimethylsilyl)silane toward diarylaminyl radicals.

Absolute rate constants for the reaction of tri-tert-butylphenoxyl radical (ArO*) with (TMS)(3)SiH were measured spectrophotometrically in the temperature range 321-383 K. Rate constants for the hydrogen abstraction from (TMS)(3)SiH by diarylaminyl radicals of type (4-X-C(6)H(4))(2)N* were determined by using a method in which the corresponding amines catalyze the reaction of ArO* with (TMS)(3)SiH. At 364.2 K, rate constants are in the range of 2-50 M(-)(1) s(-)(1) for X = H, CH(3), CH(3)O, and Br, whereas the corresponding value for ArO* is 3 orders of magnitude lower. A common feature of these reactions is the low preexponential factor [log(A/M(-1)s(-1)) of 4.4 and 5.2 for ArO* and Ph(2)N*, respectively], which reflects high steric demand in the transition state. A semiempirical approach based on intersecting parabolas suggests that the observed reactivity is mainly related to the enthalpy of the reaction and allowed to estimate activation energies for the reaction of (4-X-C(6)H(4))(2)N* and ArO* radicals with a variety of silicon hydrides.

Free radicals associated with DNA damage.

This short review focuses on the chemical events related to DNA damage induced by free radicals. Diffusible hydroxyl radicals (HO) are able to react with either the sugar units by hydrogen abstraction or with the base moieties by addition. Selectively generated carbon-centred radicals at C1', C4' and C5' in model nucleosides or oligonucleotides and their subsequent fate under aerobic or anoxic condition are discussed by rationalisation of the available kinetic data. Reaction paths for the formation of nucleobase modifications such as 8-oxoG and FapyG, amplification of base damage, and tandem lesions are also discussed. Some types of DNA damage may be poorly repaired leading to deleterious genetic changes with time.

Cis-trans isomerization of polyunsaturated fatty acid residues in phospholipids catalyzed by thiyl radicals.

Phospholipids containing trans-unsaturated fatty acid residues are the major products of the thiyl radical attack on L-alpha-phosphatidylcholine from soybean lecithin in homogeneous solution or in liposomes (LUVET). Thiyl radicals act as the catalyst for the cis-trans isomerization, and the number of catalytic cycles depends on the reaction conditions. The presence of approximately 0.2 mM oxygen does not influence the reaction outcome but accelerates the efficiency of cis-trans isomerization in homogeneous solution. Under these conditions, the PUFA peroxidation is found to be unimportant. A detailed study of the isomerization of methyl linoleate including product studies indicates the formation of a small amount of conjugated dienes that act as inhibitors. Indeed, all-trans-retinol substantially retarded the isomerization process.