Mimicking of Phase I Metabolism Reactions of Molindone by HLM and Photocatalytic Methods with the Use of UHPLC-MS/MS.

Establishing the metabolism pathway of the drug undergoing the hepatic biotransformation pathway is one of the most important aspects in the preclinical discovery process since the presence of toxic or reactive metabolites may result in drug withdrawal from the market. In this study, we present the structural elucidation of six, not described yet, metabolites of an antipsychotic molecule: molindone. The elucidation of metabolites was supported with a novel photocatalytical approach with the use of WO3 and WS2 assisted photochemical reactions. An UHPLC-ESI-Q-TOF combined system was used for the registration of all obtained metabolite profiles as well as to record the high resolution fragmentation spectra of the observed transformation products. As a reference in the in vitro metabolism simulation method, the incubation with human liver microsomes was used. Chemometric comparison of the obtained profiles pointed out the use of the WO3 approach as being more convenient in the field of drug metabolism studies. Moreover, the photocatalysis was used in the direction of the main drug metabolite synthesis in order to further isolation and characterization.

Reactive Oxygen Species-mediated Degradation of Antidiabetic Compounds: Cytotoxic Implications of Their Photodegradation Products.

Reactive oxygen species (ROS) have been described in their double physiological function, helping in the maintenance of health as well as contributing to oxidative stress. Diabetes mellitus is a chronical disease nearly related to oxidative stress, whose treatment (in type II variant) consists in the administration of antidiabetic compounds (Andb) such as Gliclazide (Gli) and Glipizide (Glip). In this context, as Andb may be exposed to high ROS concentrations in diabetic patients, we have studied the potential ROS-mediated degradation of Gli and Glip through photosensitized processes, in the presence of Riboflavin (Rf) vitamin. We found that singlet oxygen (O2 (1 ∆g )) participated in the Rf-sensitized photodegradation of both Andb, and also superoxide radical anion in the case of Gli. Two principal products derived from O2 (1 ∆g )-mediated degradation of Gli were identified and their chemical structures characterized, through HPLC mass spectrometry. O2 (1 ∆g )-mediated degradation products and their toxicity was assayed on Vero cell line. These studies demonstrated that neither Gli nor its photoproducts caused cytotoxic effect under the experimental conditions assayed. Our results show strong evidences of ROS-mediated Andb degradation, which may involve the reduction or loss of their therapeutic action, as well as potential cytotoxicity derived from their oxidation products.

Sunlight photolysis of benzotriazoles - Identification of transformation products and pathways.

Benzotriazoles (BTs) are widely used corrosion inhibitors, incompletely removed in municipal wastewater treatment. The photochemical fate of the three BTs 1H-benzotriazole (1H-BT), 4-methyl-1H-benzotriazole (4Me-BT) and 5-methyl-1H-benzotriazole (5Me-BT) and of three microbial metabolites, was studied under simulated sunlight (290-800 nm) at neutral pH in aqueous solution for 24 h. The half-life, the quantum yield and the reaction rate were determined and a total of 36 photolysis products were detected and identified using liquid chromatography-high resolution-mass spectrometry. The half-lives of all six BTs were in the range of 6-24 h under the experimental conditions. Though the quantum yields were comparatively low (0.0007-0.0021), the environmental half-lives ranged from 2.4 to 8 d, suggesting that sunlight photolysis is still a relevant degradation process of BTs in surface waters. The photolysis pathway of 1H-BT under simulated sunlight differed from that suggested for UV-radiation, in that aminophenol is formed directly rather than via aniline. Similar pathways were found for the other BTs, except for 4-hydroxy-1H-benzotriazole (4OH-BT). Most identified transformation products of the BTs showed a high reactivity and appear not to persist in the environment. Upon co-photolysis of BTs with dissolved organic matter (DOM), however, series of reaction products were determined by Fourier transform - ion cyclotron resonance - mass spectrometry (FTICR-MS) which are formed by reaction of photolysis intermediates of the BTs with DOM.

Circumvention of cisplatin resistance in ovarian cancer by combination of cyclosporin A and low-intensity ultrasound.

Cisplatin resistance is a challenge in the treatment of ovarian cancer. The aim of this study was to explore if ultrasound can overcome chemoresistance and enhance chemosensitization due to cyclosporin A. Ultrasound and/or cyclosporin A were employed to overcome cisplatin resistance in human ovarian cancer cell line COC1/DDP. Mechanisms were explored from the perspective of: DNA damage, intracellular platinum level, detoxification, and genes related to drug efflux and DNA repair. In vivo therapeutic efficacy was validated in a short-term model (subrenal cell-clot transplantation) in mice and the survival benefit was investigated in an orthotopic cancer model in mice using HO-8910PM cells. The findings were: (i) ultrasound enhanced the effect of cisplatin leading to a lower cell-survival rate (IC50 decreased from 3.19 to 0.35 µg/ml); (ii) ultrasound enhanced cisplatin via direct (increasing the intercellular level of active platinum) and indirect (decreasing the glutathione level, and expression of LRP and ERCC1 genes) mechanisms that intensified cisplatin-induced DNA damage, thus enhancing cell apoptosis and necrosis; (iii) cisplatin followed by ultrasound led to small tumor sizes in the short-term model without exacerbation of the systemic toxicity, and prolonged the survival times in the orthotopic model; and (iv) ultrasound synergized the sensitization due to cyclosporin A in vitro and in vivo. These data demonstrated that ultrasound combined with cyclosporin A overcame cisplatin resistance in ovarian cancer.

Enhancement effect of ethanol on lipid and fatty acid accumulation and composition of Scenedesmus sp.

The effects of ethanol concentration gradients along with varied cultivation times on lipid and fatty acid accumulation and composition of Scenedesmus sp. were studied. The maximum increment of algal density, lipid productivity, lipid content and fatty acid content were 6.61, 11.75, 1.34 and 3.14 times higher than the control group under 12h photoperiod. Algal light deprivation inhibited ethanol positive effects on algal growth and lipid biomass. The cumulative quantity of C16:0 and C18:0 decreased correspondingly with the increase of ethanol concentrations and cultivation times. Besides, unsaturated fatty acids appeared early in algal cells and increased 57.02% in maximum. However, only 2.27% (14)C was transferred from ethanol to fatty acids. The results indicated that adding proper amount of ethanol in algal culture medium was beneficial to biodiesel feedstock production and biodiesel properties.

Study of the photocatalytic transformation of synephrine: a biogenic amine relevant in anti-doping analysis.

The occurrence of some cases of positive results in anti-doping analysis of octopamine requires clarification as to whether its methylated derivative synephrine could be a metabolic precursor of octopamine itself. Synephrine is a natural phenylethylamine derivative present in some food supplements containing Citrus aurantium, permitted in sport regulations. A simulative laboratory study had been done using a photocatalytic process, to identify all possible main and secondary transformation products, in a clean matrix; these were then sought in biological samples obtained from three human volunteers and four rats treated with synephrine; the parent compound and its new potential metabolic products were investigated in human urine and rat plasma samples. The transformation of synephrine and octopamine and the formation of intermediate products were evaluated, adopting titanium dioxide as photocatalyst. Several products were formed and characterized using the HPLC-HRMS(n) technique. The main intermediates identified in these experimental conditions were compared with the major synephrine metabolites found in in vivo studies on rats and humans. Some more oxidized species, already formed in the photocatalytic process, were also found in urine and plasma samples of treated animals. These new findings could be of interest in further metabolism studies. The main photocatalytic pathway involving synephrine appears to be N-demethylation to give octopamine. On the contrary, we demonstrate the inconsistency of this reaction in both rat and human in vivo determinations, resulting in forensic importance.

Enhanced biodegradation of carbamazepine after UV/H2O2 advanced oxidation.

Carbamazepine is one of the most persistent pharmaceutical compounds in wastewater effluents due to its resistance to biodegradation-based conventional treatment. Advanced oxidation can efficiently degrade carbamazepine, but the toxicity and persistence of the oxidation products may be more relevant than the parent. This study sets out to determine whether the products of advanced oxidation of carbamazepine can be biotransformed and ultimately mineralized by developing a novel methodology to assess these sequential treatment processes. The methodology traces the transformation products of the (14)C-labeled carbamazepine during UV/hydrogen peroxide advanced oxidation and subsequent biotransformation by mixed, undefined cultures using liquid scintillation counting and liquid chromatography with radioactivity, mass spectrometry, and UV detectors. The results show that the oxidation byproducts of carbamazepine containing a hydroxyl or carbonyl group can be fully mineralized by a mixed bacterial inoculum. A tertiary treatment approach that includes oxidation and biotransformation has the potential to synergistically mineralize persistent pharmaceutical compounds in wastewater treatment plant effluents. The methodology developed for this study can be applied to assess the mineralization potential of other persistent organic contaminants.

Biotransformación de carbón de bajo rango por bacterias aisladas de microhábitats influenciados por residuos de carbón / Biotransformation of low rank coal by bacteria isolated from environments influenced by coal residue

Se describió la capacidad de cinco cepas bacterianas para transformar un carbón de bajo rango (CBR), para ello se evaluaron cepas aisladas de microhábitats con presencia de partículas procedentes de los procesos de almacenamiento y lavado de carbón en la mina El Cerrejón (Colombia). Se realizaron ensayos de solubilización de CBR en medio de cultivo sólido y líquido, además de la decoloración de sustancias húmicas (SH) extraídas del CBR. Todas las bacterias evaluadas presentaron capacidad para biotransformar CBR en medio sólido, esta actividad es mayor cuando el CBR ha sido pretratado con ácido nítrico; en medio líquido se alcanzó una pérdida de peso de CBR hasta del 37% por acción de una cepa de Acinetobacter baumannii, acompañada de la aparición de hasta 8,06 mg/ml-1 de sustancias solubles con absorbancia a 465 nm; los cambios en el pH del medio sugieren que la actividad biotransformadora de CBR está asociada a la liberación de sustancias alcalinas; finalmente, se encontró evidencia para sugerir que las SH presentes en el CBR son transformadas por cometabolismo, posiblemente mediante reacciones de depolimerización, decoloración y repolimerización.

in this study were evaluated five bacterial strains isolated from microhabitats with high content of coal particles generated from storage and washing processes, in "The Cerrejón” open coal mine (Colombia), their ability to biotransform a low rank coal (LRC) was described by testing solubilization on solid and liquid culture medium, as well as bleaching of humic substances (HS) extracted from LRC. All tested bacteria showed ability to biotransform LRC on solid medium, this activity is greater when the LRC has been pretreated with nitric acid; in liquid medium LRC reached 37% of weight loss by Acinetobacter baumannii strain, accompanied by the appearance of up to 6.8 mg/ml-1 of soluble substances with absorbance at 465 nm, changes in culture medium pH suggest that LRC biotransformations activity is associated with alkaline substances release, finally found evidence to suggest that HS contained within LRC are transformed by cometabolism, possibly by depolymerization reactions, bleaching and repolimerization.

Effects of light regime and oxygen profile on transformation of oxolinic acid in pond sediment.

This study investigated the effects of light (visible light - 5800 lux, 24h) or dark regime and aerobic or anaerobic condition on the decay of added oxolinic acid (OA) at 5, 10 and 20 mg L(-1) in eel pond sediment. An asymptotic decaying exponential model C(t)=C(min)+C(o) × exp (-k × t) was used to facilitate quantitative approach to OA transformation, where C(t) is the concentration of OA after t days, C(min) the estimated level-off concentration of OA residue, C(o) the concentration of added OA and k the decaying coefficient. OA decayed faster under light (C(min)=4.6 mg L(-1)) than under dark (C(min)=7.8 mg L(-1)) and also decayed faster under aerobic (C(min)=4.0 mg L(-1)) than under anaerobic condition (C(min)=8.5 mg L(-1)). C(min) increased with C(o). Sundrying and tilling eel pond bottom should be able to reduce OA residue significantly.

Biocatálisis aplicada a la Química Farmacéutica / Enzymes and microorganisms as catalysts in the synthesis of products of pharmaceutical interest

La Industria Farmacéutica se enfrenta en la actualidad, forzada por la normativade la UE a reducir la producción de residuos (200 Kg) por kilogramo deproducto. Ello implica el desarrollo de procesos de síntesis más eficaces y selectivos,utilizando mejores catalizadores. Por ello la Biocatálisis y las Biotransformaciones,como aplicación de la misma a la Síntesis Orgánica, están adquiriendo unpapel importante en el diseño de las nuevas síntesis de fármacos. En la presenterevisión se comentan algunas de las metodologías desarrolladas por el Grupo deBiotransformaciones de la UCM en este campo. Se abordan las metodologías desarrolladaspara la mejora de los biocatalizadores: nuevas técnicas de inmovilización o de modificación química, control de la actividad de agua etc. Se describenalgunos procesos de interés desarrollados en el grupo como la resolución de racémicosy su aplicación a la obtención de ácidos S-2-arilpropiónicos o de β-bloqueantesadrenérgicos; la reducción estereoselectiva de cetonas proquirales, la síntesisen un paso de nucleósidos con actividad farmacológica etc. En todos los casos secomentan las ventajas de las nuevas metodologías de síntesis en sintonía con lanueva normativa de obligado cumplimiento de la UE sobre eliminación de disolventescontaminantes (CH2Cl2, TCE), inflamables (hexano, isooctano), compuestosorgánicos volátiles (COV) etc, y de reactivos contaminantes v.g.: catalizadoresórgano metálicos

Pharmaceutical industries are nowadays facing the challenge of lowering theratio (kg of residues/kg of product) to levels below 200, as required by the Europeanlegislation. This fact is demanding the implementation of more selective andefficient synthetic procedures, so that new and better catalysts are needed. For thispurpose, Applied Biocatalysis, and more specifically Biotransformation (the use ofthe former in Organic Synthesis), are becoming more prominent in the design ofnew strategies for drugs synthesis. In this review, some of the methodologiesapplied inside the Biotransformations Group of the Complutense University arepresented; thus, the employ of different methodologies (such as immobilizationand/or modification of biocatalysts, or the control of water activity of the reactionmedia) for improving the biocatalyst performance are described. The biocatalyzedresolution of racemates for obtaining enantiopure S-2-aryl propionic acids (profens)or cardiotonic β-blockers, the estereoselective carbonyl reduction of prochiralketones, or the one-step semi-synthesis of therapeutically significant nucleosideswill be discussed. In all cases, a special emphasis is set on the environmentaladvantages of the biocatalyzed processes, as demanded by EU legislation on substitutionof contaminant solvents (CH2Cl2, TCE) or reagents (organo metallic catalysts),as well as highly flammable compounds (n-hexane, isooctane), or promotingVOCs release

Radiolytic decomposition of multi-class surfactants and their biotransformation products in sewage treatment plant effluents.

Electron beam irradiation (EBI), as one of the most efficient advanced oxidation processes, was applied to the treatment of sewage treatment plant (STP) effluent, with the objective of evaluating the effectiveness of radiolytic decomposition of multi-class surfactants. Target compounds, included several high-volume surfactant groups, such as alkylphenol ethoxylates (APEOs) and their biotransformation products, linear alkylbenzene sulfonates (LAS), alkyl sulfates (AS), alkylether sulfates (AES), coconut diethanol amides (CDEA), alcohol ethoxylates (AEO) and polyethylene glycols (PEGs). EBI treatment of STP effluent (total concentration of APEO-derived compounds 265mugl(-1), being APE(2)C the most abundant by-degradation products) resulted in efficient decomposition of all alkylphenolic compounds; elimination of 94% longer ethoxy chain nonylphenol ethoxylates (NPEO, n(EO)=3-15) was obtained when 3kGy were applied. Slightly less efficient decomposition of short ethoxy chain oligomers (NPEO(1) and NPEO(2)) was observed, resulting in disappearance of about 80% of the initially present compounds. LC-MS analysis of treated wastewater suggested that the mechanism of EBI degradation of APEOs is a combination of two parallel pathways: a progressive shortening and oxidation of the ethoxy chain, which resulted in a formation of short ethoxy chain oligomers and APECs and central fission that resulted in formation of PEGs. Decomposition of APECs at 1kGy initially yielded APs, which were subsequently eliminated applying higher radiation doses. With a radiation dose of 2kGy about 95% of NPE(1)C and 97% of NPE(2)C were decomposed. Similar elimination rates were obtained for octylphenolic compounds. Radiolytic treatment applied was also very effective in removing PEGs formed as by-products from APEO degradation, as well as in decomposing other surfactants, such as linear LAS, AS and AES.

Photostability studies on nicardipine-cyclodextrin complexes by capillary electrophoresis.

Nicardipine (NC)-cyclodextrin solid systems were prepared in equimolar ratios and their photostability in aqueous solution under exposure to UV(A)-UV(B) radiations was evaluated. The photodegradation process was monitored by a capillary electrophoresis (CE) method able to provide the enantioresolution of the rac-nicardipine. Enantioresolution was achieved using the mixture 3.0% sulfate-beta-cyclodextrin (SbetaCD) and 2.0% heptakis(2,3,6-tri-O-methyl)-beta-cyclodextrin (TMbetaCD) as chiral selector in 20mM triethanolammonium phosphate solution (pH 3.0). The photostability studies were carried out on inclusion complexes of rac-nicardipine with alpha-cyclodextrin (alphaCD), beta-cyclodextrin (betaCD), gamma-cyclodextrin (gammaCD), hydroxypropyl-alpha-cyclodextrin (HPalphaCD), hydroxypropyl-beta-cyclodextrin (HPbetaCD), hydroxypropyl-gamma-cyclodextrin (HPgammaCD), (2-hydroxyethyl)-beta-cyclodextrin (HEbetaCD) and methyl-beta-cyclodextrin (MbetaCD). A photoprotective effect was observed by betaCD, HPalphaCD, HEbetaCD, whereas gammaCD, MbetaCD, HPbetaCD and HPgammaCD did not affect the nicardipine photostability. Conversely, alphaCD was found to favour the drug photodegradation. Evidences for CDs-mediated stereoselective photodegradation of rac-nicardipine were observed only for the beta-CD complex. In this case, two distinct photodegradation profiles, with two different kinetic constants (k), were observed for the nicardipine enantiomers.

Light-dependent activation of 7,12-dimethylbenz[a]anthracene to a potent genotoxicant.

7,12-Dimethylbenz[a]anthracene (DMBA), which is widely used in mutagenesis and experimental carcinogenesis, is activated to a mutagen by white fluorescent light. A 40 min exposure to white fluorescent light of Salmonella typhimurium TA98 plates treated with DMBA, in the absence of exogenous metabolism, resulted in an approximately 30-fold increase in the number of histidine revertants. This phenomenon also occurs, with lesser intensity, with other promutagens, such as benzo[a]pyrene or 2-acetylaminofluorene, and in other Salmonella tester strains. Moreover, white fluorescent light is able to activate DMBA to a toxicant for Chinese hamster V79 cells in culture, resulting in very low cell survival. Under these conditions, white fluorescent light-activated DMBA was shown to cause chromosomal aberrations, but not gene mutations, as determined by resistance to thioguanine. This white fluorescent light-dependent activation of DMBA seems to be related to the formation of reactive species, as the addition of vitamin E results in a reduction in the number of histidine revertants induced by white fluorescent light in S. typhimurium TA98.

[Changes in drug pharmacokinetics and pharmacodynamics under the influence of microwaves of different ranges]. / Izmeneniia farmakokinetiki i farmakodinamiki lekarstv pod vliianiem mikrovoln raznogo diapazona.

Human and animal experiments were conducted to compare the effect of microwaves different by their range on drug pharmacodynamics and pharmacokinetics. The response to the microwaves depended on the dose and site of the exposure, on the frequency of the electromagnetic modes. The results suggest that it is possible to use microwaves for potentiating and prolongation of some drugs action.

Photoactivation of 2-nitrofluorene in vitro and in the rat in vivo. UVA-induced formation of reactive intermediates that bind covalently to RNA and protein.

2-Nitrofluorene (2-NF), an environmental pollutant, can be activated by UV light to reactive intermediates that bind covalently to RNA and protein in vitro: high levels of covalent binding were obtained. This covalent binding was not dependent on the presence of oxygen in the solution and could be decreased by glutathione. Hydrolysis of the in vitro modified RNA and subsequent analysis of the liberated bases by HPLC revealed that approximately 15% of the covalent binding of 2-NF to RNA could be attributed to the formation of a guanosine adduct of nitroreduced 2-NF, N-(deoxyguanosin-8-yl)-2-aminofluorene. Many other adducts are formed of which the structure and mechanism of formation are as yet unknown. The possibility of photoactivation of 2-NF in the rat in vivo was also investigated. Photoactivation increased covalent binding of 2-NF in the skin but not in other organs. The mechanism of the photoactivation of 2-NF is discussed.

DNA repair induction by UV irradiation and various mutagens requiring metabolic activation in rat hepatocytes maintained in culture for several days.

Freshly isolated rat hepatocytes cultivated in Williams Medium E (WME) quickly lose their cytochrome P-450-dependent metabolic activities. A significantly better maintenance of cytochrome P-450 was achieved by supplementing WME with hormones and nutrients and 2% DMSO and 10% fetal calf serum. After 72-h cultivation in this medium the cytochrome P-450 content was still 72% of the amount measured in freshly isolated cells. Over the same period of time the activity of 7-ethoxycoumarin-O-deethylase dropped to approximately 55% of its initial value. DNA repair induction by UV irradiation, hydrogen peroxide, benzo[a]pyrene and 2-acetylaminofluorene was measured. A clear dose-dependent increase of the incorporation of [3H]thymidine was found with all agents tested, regardless of whether the treatment of the hepatocytes began 4 or 52 h after cell isolation. In the case of UV light and hydrogen peroxide the maximum effects were slightly lower after prolonged cultivation, whereas little change or even a slight increase was found with benzo[a]pyrene and 2-acetylaminofluorene. These results indicated that cell cultivation led to a slight loss of DNA repair activity but did not, despite the loss of cytochrome P-450, cause a decrease in DNA-damaging intermediates produced from the two indirect mutagens. The absolute amounts of [3H]thymidine incorporated by the solvent control cells of the 52-h groups was consistently found to be twice the level measured in the corresponding 4-h control groups. The incorporation of deoxy[3H]cytidine was not changed when tested in parallel. The increase in [3H]thymidine incorporation can therefore be explained by the assumption of a diminution of the thymidine pool during cell cultivation.

Metabolism of mutagenic polycyclic aromatic hydrocarbons by photosynthetic algal species.

Polycyclic aromatic hydrocarbons (PAH) known to produce carcinogenic and mutagenic effects have been shown to contaminate waters, sediments and soils. While it is accepted that metabolites of these compounds are responsible for most of their biological effects in mammals, their metabolism, and to a large extent their bioactivity, in aquatic plants have not been explored. Cultures of photosynthetic algal species were assayed for their ability to metabolize benzo[a]pyrene (BaP), a carcinogenic PAH under conditions which either permitted (white light) or disallowed (gold light) photooxidation of the compound. Growth of Selenastrum capricornutum, a fresh-water green alga, was completely inhibited when incubated in white light with 160 micrograms BaP/l medium. By contrast concentrations at the upper limit of BaP solubility in aqueous medium had no effect on algal growth when gold light was used. BaP quinones and phenol derivatives were found to inhibit growth of Selenastrum under white light incubation. BaP phototoxicity and metabolism were observed to be species-specific. All 3 tested species of the order Chlorococcales were growth-inhibited by BaP in white light whereas neither the green alga Chlamydomonas reinhardtii nor a blue-green, a yellow-green or an euglenoid alga responded in this fashion. Assays of radiolabeled BaP metabolism in Selenastrum showed that the majority of radioactivity associated with BaP was found in media as opposed to algal cell pellets, that the extent of metabolism was BaP concentration dependent, and that the proportion of various metabolites detected was a function of the light source. After gold light incubation, BaP diols predominated while after white light treatment at equal BaP concentrations, the 3,6-quinone was found in the highest concentration. Extracted material from algal cell pellets and from media was tested for mutagenicity in a forward mutation suspension assay in Salmonella typhimurium using resistance to 8-azaguanine for selection. Direct-acting mutagens were detected in extracted media from incubation of Selenastrum with 400 micrograms BaP/l for 1 day in gold light. Extracts of media from algae incubated in gold light from 1 to 4 days with 1200 micrograms BaP/l were found to have direct-acting mutagens as well as those requiring further metabolism. Media extracts from white light incubations of BaP were mutagenic upon addition of rat liver homogenates. Activity of these materials from white light treatment are largely attributable to unmetabolized BaP.

Irreversible binding with biological macromolecules and effects in bacterial mutagenicity tests of the radical cation of promethazine and photoactivated promethazine. Comparison with chlorpromazine.

The irreversible binding of the radical cation of promethazine (PMZ+.) to DNA and protein in vitro and bacterial macromolecules in situ has been studied. Binding experiments were performed with synthesized [35S] promethazine. The results are compared to those with the chlorpromazine radical cation (CPZ+.). Secondary reaction products which result from fission of the alkylamino side chain are involved in the macromolecular binding of PMZ+. Compared to CPZ+. the covalent DNA binding of PMZ+. is significantly less. A larger amount of PMZ+. binds to single-stranded DNA than to double-stranded DNA. The extent of binding to proteins and RNA is of the same order as that of CPZ+. Bacterial mutagenicity tests show that the low genotoxicity of PMZ+. is related to the low DNA binding. The bacterial cytotoxicity is possibly related to the covalent protein binding. Similar results have been obtained with photoactivated promethazine (PMZ) and chlorpromazine (CPZ). The role of radical cations in the photosensitization and metabolic activation of phenothiazine drugs is discussed.

The effect of chlorpromazine on pharmacokinetics and pharmacodynamics of phenobarbital in X-irradiated rats.

Male Wistar rats were irradiated with a single 600R dose of X-rays on the whole body. Chlorpromazine was given 30 min before phenobarbital. Phenobarbital sleeping time was prolonged by chlorpromazine both in irradiated and non-irradiated rats. On the 3rd day after irradiation the prolongation of the phenobarbital sleep by chlorpromazine was more marked than on the 6th day. No correlation between the pharmacodynamic action of phenobarbital and its cerebral level was noted.