The role of external defects in chemical sensing of graphene field-effect transistors.

A fundamental understanding of chemical sensing mechanisms in graphene-based chemical field-effect transistors (chemFETs) is essential for the development of next generation chemical sensors. Here we explore the hidden sensing modalities responsible for tailoring the gas detection ability of pristine graphene sensors by exposing graphene chemFETs to electron donor and acceptor trace gas vapors. We uncover that the sensitivity (in terms of modulation in electrical conductivity) of pristine graphene chemFETs is not necessarily intrinsic to graphene, but rather it is facilitated by external defects in the insulating substrate, which can modulate the electronic properties of graphene. We disclose a mixing effect caused by partial overlap of the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) of adsorbed gas molecules to explain graphene's ability to detect adsorbed molecules. Our results open a new design space, suggesting that control of external defects in supporting substrates can lead to tunable graphene chemical sensors, which could be developed without compromising the intrinsic electrical and structural properties of graphene.

Long hydrocarbon chain diols and diacids with central ether or ketone moieties that favorably alter lipid disorders.

Long hydrocarbon chain derivatives with bis-terminal hydroxyl or carboxyl groups and various central moieties (ketone, ether, ester, amide, carbamate, etc.) have been synthesized and evaluated for their effects on the de novo incorporation of radiolabeled acetate into lipids in primary cultures of rat hepatocytes as well as for their effects on lipid, glycemic and body weight variables in female obese Zucker fatty rats following one and two weeks of oral administration. The most active compounds were found to be symmetrical with four to five methylene groups separating the ether or ketone central functionality from the gem dimethyl, cycloalkyl or methyl/aryl substituents. Cycloalkyl substitution alpha to the carboxyl group in keto-acids lowered the in vitro activity to micromolar values. Furthermore, in vivo biological activity was found to be greatest for cyclopropyl-substituted ketone derivatives, particularly the ketodiacid with five methylene groups on each side of the central ketone functionality, which was identified as an HDL elevator and was also found to reduce insulin and glucose.

A permanently charged tamoxifen derivative displays anticancer activity and improved tissue selectivity in rodents.

A quaternized form of tamoxifen (TAM), tamoxifen methiodide (TMI), was shown to demonstrate very low brain uptake compared to TAM and, unexpectedly, was considerably less estrogenic than TAM in the uterus. The agonist activity of TMI in the bone was similar to that of TAM. TMI manifested significant dose-dependent tumoricidal activity with a rapid onset of action against MCF-7 human breast cancer implants in nude mice and a mean reduction in tumor size of 60% over six weeks.

Cannabinoids, endogenous ligands and synthetic analogs.

The investigation of natural and synthetic cannabinoid ligands, including (-)-Delta(9)-tetrahydrocannabinol, cannabinol, cannabidiol, HU-210, HU-211, CT3, CP 55, 940, WIN 55, 212-2, SR 14, 1716A, anandamide, 2-arachidonoylglycerol, and numerous novel analogs, has led to important findings that have contributed to a better understanding of the role of these compounds in physiological processes. Their potential use for medicinal purposes is also better understood as a result.

Nonpsychotropic synthetic cannabinoids.

Unlike natural cannabinoids which belong to the 6aR - trans series, the synthetic dexanabinol (HU-211), a 6aS-trans enantiomer, does not have affinity toward cannabinoid receptors and is devoid of cannabimimetic activity. On the other hand, dexanabinol demonstrated significant neuroprotective properties which prompted its development as a therapeutic agent. We now present the extension of a series of 6aS-trans cannabinoids with novel derivatives, including water soluble derivatives and congeners of dexanabinol.

Chemical delivery systems for some penicillinase-resistant semisynthetic penicillins.

Chemical delivery systems (CDS's) based on a dihydropyridine----quaternary pyridinium ion redox system analogous to the naturally occurring NADH----NAD+ system were synthesized for a group of staphylococcal penicillinase resistant penicillins, including methicillin, oxacillin, cloxacillin, and dicloxacillin, in order to improve their penetration of the central nervous system (CNS). The CDS's are penicillin monoesters of gem-diols in which the other hydroxyl group is esterified by the dihydrotrigonelline carrier. The CDS's were found to be much more lipopholic than the parent drugs by comparing their log k' values used as lipophilicity indexes. A study of the chemical oxidation of the CDS's performed by a UV spectrophotometric method showed relatively slow reaction. Stability studies were performed in buffers and different animal tissues for both the CDS's and the quaternary salt type derivatives. These studies showed that the CDS's were oxidized to the quaternary salt forms at neutral and basic pH and added water at lower pH. The quaternary salts released the parent drugs both in buffers and in vitro. A preliminary in vivo distribution study in the rat and rabbit demonstrated blood-brain barrier (BBB) penetration by the CDS, whereas no drug was detected by administering the drug itself.

Brain-specific chemical delivery systems for beta-lactam antibiotics. In vitro and in vivo studies of some dihydropyridine and dihydroisoquinoline derivatives of benzylpenicillin in rats.

Four chemical delivery systems (CDS's) based on a dihydropyridine----quaternary pyridinium salt redox system were used for the brain delivery of benzylpenicillin (BP). CDS's 5 and 9 are diesters of C1 and C2 diols in which one hydroxyl group is esterified by the benzylpenicillin-3-carboxylic group and the other by dihydrotrigonelline. CDS's 13a and 17 are benzylpenicillin esters of amino alcohols in which the amine group is acylated by dihydro-trigonelline (13a) or by 1,2-dihydro-2-methyl-4-isoquinolinecarboxylic acid (17). In vitro relative stability studies showed that both CDS's and quaternary pyridinium salts were quite unstable in rat and rabbit blood or brain but much more stable in dog or human blood. Kinetic studies performed in rat brain homogenate demonstrated the facile enzymatic oxidation of the CDS's to the corresponding quaternary salts. Hydrolysis of the CDS's and the quaternary salts resulted in the release of benzylpenicillin. In biological media CDS 13a also yielded a water addition product, the 6-hydroxy-1,4,5,6-tetrahydropyridine derivative. In vivo distribution studies were carried out in rats. After iv administration of equimolar doses of BP and CDS's, brain benzylpenicillin levels were found to be substantially higher and more prolonged in case of 5 and 9 than of BP itself. However, administration of 13a and 17 resulted in lower brain benzylpenicillin levels due to the water addition reaction and a nonspecific brain delivery, respectively. The remarkable increase of BP levels as well as the prolonged effect after the administration of 5 and 9 is a result of an improved penetration through the blood-brain barrier of the lipophilic CDS's and a "lock-in" effect of the corresponding quaternary salts generated in situ.

Brain-specific chemical delivery systems for beta-lactam antibiotics. Synthesis and properties of some dihydropyridine and dihydroiosquinoline derivatives of benzylpenicillin.

Six chemical delivery systems (CDS) were synthesized for benzylpenicillin in order to improve its transport across the blood-brain barrier. The CDS's were based on a dihydropyridine----quaternary pyridinium ion redox system, analogous to the naturally occurring NADH----NAD+ system. Two different types of CDS's were prepared: benzylpenicillin esters of diols in which the other hydroxyl group is esterified by dihydrotrigonelline and benzylpenicillin esters of amino alcohols in which the amine group is acylated by dihydrotrigonelline, or by 1,2-dihydro-2-methyl-4-isoquinolinecarboxylic acid. Lipophilicities of the CDS's were proved to be much higher than those of benzylpenicillin by using Rm values as lipophilicity indexes. Upon oxidation, all of the CDS's gave the quaternary ion forms. Kinetic studies in buffer (pH profiles) indicated that the quaternary salts released benzylpenicillin in pH range of 5-9 via hydrolysis. The CDS's in acidic media yielded as the major reaction product 6-hydroxy-1,4,5,6-tetrahydropyridines as a result of water addition, while in basic conditions benzylpenicillin was released. The water addition reaction was dependent on the CDS's structure, being more prevalent in the case of the "amide-esters". The dihydroisoquinoline CDS was rather stable in the pH range 5-8.

Antihypertensive activity of redox derivatives of tryptophan.

The essential amino acid, tryptophan, has been shown to lower blood pressure in rats when administered orally or intravenously. In order to potentially enhance this action, a brain-targeting chemical delivery system (CDS) approach was applied to this compound. The CDS is based on a dihydropyridine----pyridinium ion redox system, chemically analogous to the naturally occurring NADH----NAD+ system. The dihydropyridine moiety containing carrier is chemically attached to the amino group by an amide-type bonding while the carboxylic acid functionality is esterified to various alcohols. Physicochemical studies of the new derivatives were performed. The determined chromatographic Rm values indicate an increased lipophilicity for the CDSs compared to the parent compound. Oxidation stability studies performed on selected compounds using a ferricyanide-mediated method showed that the CDSs are oxidized to the respective quaternary salt forms. Activity studies performed in deoxycorticosterone acetate induced hypertensive rats, demonstrated that the delivery system for tryptophan reduced blood pressure more efficiently for a longer time than did the parent compound.

Effect of molecular manipulation on the estrogenic activity of a brain-targeting estradiol chemical delivery system.

The structural parameters important for biological efficacy of an estradiol chemical delivery system (CDS), a brain-targeting approach based on redox trapping, were examined by molecular manipulation of a prototype derivative, estradiol 17-(1-methyl-1, 4-dihydronicotinate) (E2-CDS). Seven E2-CDS analogs in which the N-methyl substituent was altered were prepared including N-substituted short and medium straight chain alkyl, short branched chain alkyl, and aralkyl derivatives. Chemical and in vitro testing indicated that the most stable derivative was the N-benzyl E2-CDS. The analogs were tested in an intact male rat model to assess various central estrogenic manifestations including the rate of body weight gain, serum E2 and testosterone concentrations, and seminal vesicle, prostate and pituitary weight changes. Results indicated that all prepared CDS derivatives exerted some degree of central estrogenization with the most potent compounds being the parent E2-CDS and its ethyl homologue. Importantly, while the ethyl E2-CDS was equipotent to E2-CDS in various biological assays, it did not significantly elevate serum E2 compared to vehicle control at day 14.

Dexanabinol Pharmos.

Dexanabinol is a non-psychotropic cannabinoid NMDA receptor antagonist under development by Pharmos Corp for the potential treatment of cerebral ischemia, glaucoma, Alzheimer's disease, cardiac failure, head injury and multiple sclerosis (MS) [311522]; it is in phase III trials for traumatic brain injury (TBI) [388709]. Dexanabinol was licensed to Pharmos for development from its originator, the Hebrew University of Jerusalem [180441]. Pharmos is seeking to enter into a strategic agreement with another company to develop and commercialize dexanabinol [317369]. Unlike its enantiomer, HU-210 (Yissum Research Development Co), dexanabinol does not interact with cannabinoid receptors [223330]. It has also exhibited more effective antioxidant and anti-inflammatory properties than MK-801 (dizocilpine; Merck & Co Inc) [167980], [168212]. In addition, dexanabinol is generally well tolerated and appears toxicologically safe [170116]. Pharmos has been awarded a Small Business Innovation Research grant from the National Institutes of Health (NIH) National Institute of Neurological Disorders and Stroke, Division of Stroke and Trauma. The grant covers the development of new prodrugs and novel formulations of dexanabinol and will support additional study of dexanabinol compounds for various indications. The prodrugs being studied are part of the group of compounds that include dexanabinol [247958]. A Notice of Allowance was received in March 1999 on a patent covering the use of the drug in the treatment of MS [324163]. The use of dexanabinol and its derivatives to treat MS is described in US-05932610 [358503]. An oral formulation of dexanabinol is claimed in US-05891468. Dexanabinol analogs with special utility in acute and chronic pain are claimed in US-04876276, while dexanabinol analogs for neuroprotection are claimed in US-06096740. Pharmos estimates that the worldwide market for dexanabinol in the treatment of severe head trauma may reach $1 billion per year [319244].

Chemical systems for delivery of antiepileptic drugs to the central nervous system.

The chemical delivery system (CDS) approach, a recently developed procedure conceived to enhance the specific central nervous system (CNS) uptake of drugs, has been applied to several antiepileptic agents. CDSs based on dihydropyridine<-->pyridinium salt type redox targetors, reversibly linked to the drug, were designed, synthesized and tested for some traditional (phenytoin, valproate) and potential (stiripentol) antiepileptic drugs, as well as some compounds (GABA, adenosine) with important roles in epileptogenesis. Physicochemical, in vitro stability, in vivo tissue distribution, activity and toxicity studies were performed for the new derivatives. The results of these investigations indicated that selected CDSs possessed properties required for delivering the drugs to the CNS. In vivo experiments indicated improved brain uptake and enhanced pharmacologic activity in some of the examined cases. On the other hand, no toxic side effects were registered during the studies. Properly developed CDSs could enhance the therapeutic indexes of the anticonvulsant drugs.

Structural studies of loteprednol etabonate and other analogs of prednisolone using NMR techniques.

Several structural analogs of prednisolone, prepared by esterification of the carboxylic and/or the C(17)-hydroxy group of 11 beta, 17 alpha-dihydroxy-3-oxo-androsta-1,4-diene-17 beta-carboxylic acid, were investigated by NMR. Step-by-step analysis of the 1H and 13C NMR spectra of these steroids, including proton-proton selective decoupling, nuclear Overhauser effect difference spectra, attached proton test, proton-carbon correlation (HETCOR), proton-proton correlation (COSY), and long-range proton-carbon decoupling (INAPT) techniques, led to unequivocal assignments of all their proton and carbon resonances. The stereochemical structure of loteprednol etabonate (chloromethyl 17 alpha-ethoxycarbonyloxy-11 beta-hydroxy-3-oxoandrosta-1,4-diene-17 beta-carboxylate, 1), a soft corticosteroid antiinflammatory drug, was proved to be analogous to prednisolone.

Chemistry of loteprednol etabonate and related steroids. II. Reactions at ring C and NMR structural studies of the resulting compounds.

Several derivatives of lotoprednol etabonate (1), a soft corticosteroid antiinflammatory drug, are formed during the synthesis and sterilization process. Some of these contaminants of 1 result from side reactions taking place on the steroid ring C including oxidation, dehydration, chlorination and chlorohydroxylation. The products have been identified, synthesized, and fully characterized by 1H and 13C NMR spectroscopy.

Effect of sustained estradiol release in the intact male rat: correlation of estradiol serum levels with actions on body weight, serum testosterone, and peripheral androgen-dependent tissues.

The differential effect of increasing serum estradiol on various parameters in the intact male rat was assessed through the use of subcutaneously implanted, hormone-laden pellets. The delivery systems were designed to release drug through bioerosion at a zero-order rate over a 12-day time-course. Male Sprague-Dawley rats (190 to 220 g) were given estrogen pellets at increasing labeled strenghts (0, 0.001, 0.01, 0.1, 1.0, 10, 50, and 100 mg). Animals were weighed at various intervals before and after implantation. At Day 6, 12, and 26 after drug administration, rats were examined for 4 additional parameters, including serum estradiol and testoterone concentrations and accessory organ weights (i.e., ventral prostate and seminal vesicles). Serum estradiol levels were consistent with pellet potency and lifetime. Increases in body weight were suppressed 50% by circulating estradiol levels of approximately 200 pg/mL at Day 6,250 pg/mL at Day 12, and 285 pg/mL at Day 26. On the other hand, suppression of serum testosterone was more sensitive and was decreased 50% by peripheral estrogen levels of 36, 43, and 51 pg/mL at Days 6, 12, and 26, respectively. Accessory organ weights essentially reflected serum testosterone levels as indicated by their similar ED50 values: 50.5, 50.5, and 44.3 pg/mL for the ventral prostate at Day 6, 12, and 26, respectively, and 48, 56, and 51.5 pg/mL for the seminal vesicle regression at Day 6, 12, and 26, respectively. The data indicate the pellet used provided sustained plasma levels of hormone and these constant peripheral levels exerted potent pharmacological action. Initial body weight changes seemed to be less sensitive to the action of estradiol than serum testosterone or derivative properties, such as accessory organ weight.

Predicting vegetative bud break in two arctic deciduous shrub species, Salix pulchra and Betula nana.

The factors controlling bud break in two arctic deciduous shrub species, Salix pulchra and Betula nana, were investigated using field observations and growth-chamber studies. A bud-break model was calibrated using a subset of the experimental observations and was used to predict bud break under current and potential future climate regimes. The two species responded similarly in terms of bud break timing and response to air temperature in both field and controlled environments. In the field, the timing of bud break was strongly influenced by air temperatures once snowmelt had occurred. Growth chamber studies showed that a period of chilling is required before buds break in response to warming. Model simulations indicate that under current conditions, the chilling requirement is easily met during winter and that even with substantial winter warming, chilling will be sufficient. In contrast, warm spring temperatures determine the timing of bud break. This limitation by spring temperatures means that in a warmer climate bud break will occur earlier than under current temperature regimes. Such changes in bud break timing of the deciduous shrubs will likely have important consequences for the relative abundance of shrubs in future communities and consequently ecosystem processes.

Improved anticonvulsant activity of phenytoin by a redox brain delivery system. II: Stability in buffers and biological materials.

The stability of nine chemical delivery systems (CDSs) for phenytoin (DPH) was studied in aqueous buffers and in biological materials. The systems were based on a dihydropyridine in equilibrium quaternary pyridinium salt redox pair attached to 3-(hydroxymethyl)phenytoin via an ester linkage. The pyridinium derivatives released DPH in aqueous buffers and their hydrolytic reactivity was consistent with their chemical structure. Although in rat blood and plasma all pyridinium esters hydrolyzed rapidly, there was a wide range in the hydrolysis rates in rat brain homogenate. The sterically hindered 1-alkylcarboxynicotinamide was the least reactive ester (t1/2 = 98.2 min), while the trigonellylglycolate ester was the fastest to hydrolyze enzymatically (t1/2 = 2 min) in rat brain homogenate. In acidic media, the major products of all dihydropyridine esters were the corresponding water adducts, the 6-hydroxy- 1,4,5,6-tetrahydropyridines. These adducts were of no significance in biological materials. After comparison of the relative stability of the corresponding pairs of dihydropyridine and pyridinium ion in brain homogenate and the absolute stability of the various dihydropyridines, two CDSs were chosen for further in vivo evaluations. The CDSs chosen were the dihydrotrigonellinate ester and its 6-methyl derivative.

Improved anticonvulsant activity of phenytoin by a redox brain delivery system. III: Brain uptake and pharmacological effects.

Phenytoin (DPH) was delivered to the brain by a dihydropyridine in equilibrium pyridinium salt redox system, which was evaluated for anticonvulsant activity. Following iv injection of the lipophilic delivery system of DPH (2) to rats, concentrations of DPH were lower but sustained and, after 30 min, essentially the same as the levels after equimolar administration of DPH. While 2 delivered the same levels of DPH to the brain as DPH did, it was twice as potent as DPH in rats (ED50 was 7.5 mumol/kg for 2 and 14.2 mumol/kg for DPH) and mice (2: 10.5; DPH: 23.9) against maximal electroshock seizures (MES), and seven times more potent in mice (2: 10.0, DPH: 70.6) against maximal pentylenetetrazole seizures (MPS). Moreover, 2 was active against pentylenetetrazole threshold seizures (PTS) in mice and rats (ED50 = 44.1 and 40.5 mumol/kg, respectively), while DPH was ineffective (up to a dose of 79.2 mumol/kg). After evaluation of acute neurological toxicity in rats, 2 was found to possess 1.5 times higher a protective index (for MES) than DPH. It appeared also that while DPH was 2.9 times less sensitive to MPS than to MES, 2 was equally potent to both types of convulsions. Thus, the data indicate that 2 delivered DPH more efficiently to the brain. The better anticonvulsant activity (quantitatively as well as qualitatively) of 2 can be explained on the basis of an improved distribution in the brain due to its higher lipophilicity, and by favorable regional differences in the rates of conversion of 2 to DPH at the convulsing foci.

Improved anticonvulsant activity of phenytoin by a redox brain delivery system I: Synthesis and some properties of the dihydropyridine derivatives.

Nine chemical delivery systems (CDSs) were synthesized for the efficient transport of phenytoin (DPH) across the blood-brain barrier. The CDSs were based on a dihydropyridine in equilibrium quaternary pyridinium ion redox system which relies on chemistry similar to the NADH in equilibrium NAD interconversion for activity. The chemical carriers, derivatives of trigonelline, 1-alkylcarboxynicotinamide, 3-pyridylacetic acid, and N-methylpicolinic acid, were esterified with 3-(hydroxymethyl)phenytoin. The CDSs proved to be more lipophilic (5-23 times) than DPH. The 1-alkylcarboxydihydronicotinamide CDSs, excluding the sterically hindered one (11e), were quite unstable in rat tissue homogenates and hydrolyzed to release DPH. In human blood, however, they were found to be much more stable (75 times) toward hydrolysis. All other CDSs were oxidized quantitatively to the corresponding pyridinium ion in rat brain homogenates. These compounds were found to possess the required physicochemical characteristics for delivering DPH into rat brain.

Redox derivatives of tranylcypromine: syntheses, properties, and monoamine oxidase inhibitor activity of some chemical delivery systems.

Several brain-targeting chemical delivery systems (CDS) based on a dihydropyridine----pyridinium salt type redox system were synthesized for the monoamine oxidase (MAO) inhibitor tranylcypromine (TCP). The dihydronicotinate moiety was chemically attached to the amino group of TCP by either an amide or substituted carbamate linkages. Physicochemical studies of the new derivatives, including chromatographic Rm determinations, were performed. Only the substituted carbamate-type derivatives manifested an increased lipophilicity relative to the parent compound. In vitro oxidation stability studies were also performed on selected derivatives using a ferricyanide-mediated method. Results of this assay showed that the dihydropyridine-type derivatives oxidized to the respective quaternary salt forms with stabilities which empirically correlated with other effective CDSs. Preliminary in vivo studies performed in rats indicated that some of the new derivatives exerted significant biological activity.