Immobilization of DNA aptamers via plasma polymerized allylamine film to construct an endothelial progenitor cell-capture surface.

The endothelial progenitor cells (EPCs) capture stent has drawn increasing attentions and become one of the most promising concepts for the next generation vascular stent. In this regard, it is of great significance to immobilize a molecule with the ability to bind EPC for rapid in vivo endothelialization with high specificity. In this work, a facile two-step method aimed at constructing a coating with specific EPC capturing aptamers is reported. The processes involves as the first-step deposition of plasma polymerized allylamine (PPAam) on a substrate to introduce amine groups, followed by the electrostatic adsorption of a 34 bases single strand DNA sequence to the PPAam surface as a second step (PPAam-DNA). Grazing incidence attenuated total reflection Fourier transform infrared spectroscopy (GATR-FTIR) and X-ray photoelectron spectroscopy (XPS) confirmed the successful immobilization of the aptamers. Quartz crystal microbalance with dissipation (QCM-D) real time monitoring result shows that about 175 ng/cm(2) aptamers were conjugated onto the PPAam surface. The interactions between the modified surfaces and human umbilical vein endothelial cells (ECs), smooth muscle cells (SMCs), and murine induced EPCs derived from mesenchymal stem cells (MSCs) were also investigated. It was demonstrated that PPAam-DNA samples could capture more EPCs, and present a cellular friendly surface for the proliferation of both EPCs and ECs but no effect on the hyperplasia of SMCs. Also, the co-culture results of 3 types of cells confirmed that the aptamer could specifically bond EPCs rather than ECs and SMCs, suggesting the competitive adhesion advantage of EPCs to ECs and SMCs. These data demonstrate that the EPC aptamer has large potential for designing an EPC captured stent and other vascular grafts with targeted in situ endothelialization.

The glucose and lipid effects of colesevelam as monotherapy in drug-naïve type 2 diabetes.

Colesevelam has shown efficacy in adults with type 2 diabetes mellitus (T2DM) in combination with metformin-, sulfonylurea-, or insulin-based therapy, lowering hemoglobin A1c (HbA1c) and low-density lipoprotein cholesterol levels. A study was conducted to evaluate colesevelam as monotherapy in drug-naïve patients with T2DM. In this randomized, double-blind, placebo-controlled, parallel-group study, adults with T2DM who had inadequate glycemic control (HbA1c ≥7.5% and ≤9.5%) with diet and exercise alone were randomized to receive colesevelam 3.75 g/day (n=176) or placebo (n=181) for 24 weeks. The primary efficacy variable was HbA1c at week 24. Colesevelam as compared to placebo showed significant reductions from baseline in HbA1c (-2.92 mmol/mol [0.3%]; p=0.01) and fasting plasma glucose (-10.3 mg/dl; p=0.04) at week 24 with last observation carried forward. Colesevelam also significantly reduced low-density lipoprotein cholesterol (-11.2%; p<0.0001), total cholesterol (-5.1%; p=0.0005), non-high-density lipoprotein cholesterol (-7.4%; p=0.0001), and apolipoprotein B (-6.5%; p=0.0001) and increased apolipoprotein A-I (+ 2.4%; p=0.04), and triglycerides (+ 9.7%; p=0.03). Colesevelam monotherapy resulted in statistically significant improvements in glycemic and most lipid parameters in subjects with type 2 diabetes, with no new or unexpected safety and tolerability issues. Modest reductions in HbA1c and low-density lipoprotein cholesterol levels with colesevelam further support its use in combination with other antidiabetes agents when treatment targets for these parameters are close but are not quite achieved.ClinicalTrials.gov identifier: NCT00789737.

Absorption of colesevelam hydrochloride in healthy volunteers.

OBJECTIVE: To assess whether colesevelam hydrochloride is absorbed in healthy volunteers. METHODS: A single-center, open-label, radiolabeled study was performed with 16 healthy volunteers. Subjects were administered non-radiolabeled colesevelam hydrochloride 1.9 g twice daily for 4 weeks, followed by a single dose of [14C]-colesevelam 2.4 g (480 pCi). These subjects continued to receive non-radioactive colesevelam 1.9 g twice daily for 4 days after administration of the radiolabeled dose. Blood, urine, and feces were collected immediately prior to administration of [14C]-colesevelam and at specified intervals after administration. The whole-blood equivalent concentration of colesevelam was calculated using data collected throughout the 96 hours following radiolabeled drug administration. The proportion of [14C]-colesevelam excreted through urine or feces was calculated based on the amount of radioactivity recovered up to 216 hours after the radiolabeled dose. RESULTS: The mean cumulative total recovery of [14C]-colesevelam in urine and feces was 0.05% and 74%, respectively. Excluding 2 subjects for whom cumulative recovery was <25%, the mean cumulative fecal recovery was 82%. The mean maximum whole-blood equivalent concentration of colesevelam was 0.165+/-0.10 microg equiv/g 72 hours after administration of [14C]-colesevelam, which was estimated to be 0.04% of the administered dose. All blood samples contained <4 times the number of background counts (dpm). CONCLUSIONS: The cumulative recovery data in urine and feces are consistent with the conclusion that colesevelam is not absorbed and is excreted entirely through the gastrointestinal system.

Absorption, distribution and excretion of GT31-104, a novel bile acid sequestrant, in rats and dogs after acute and subchronic administration.

The absorption, distribution, and excretion of GT31-104, a novel bile acid sequestrant, was studied in rats and dogs after both acute and subchronic oral administration. The polyallylamine backbone of GT31-104 was labeled with tritium and one of the alkyl side chains was labeled with 14C. The mean blood and plasma concentration of [3H, 14C]GT31-104 in rats, in both treatment regimens, was negligible at all time points, with the highest amount observed being 0.69 microgram eq/g blood; in dogs the mean blood and plasma concentration of [3H, 14C]GT31-104 was below the limit of quantitation (< 0.001% total dose) at all time points. In both rats and dogs, the mean total urinary excretion of [3H, 14C]GT31-104 was approximately 0.06% of the total dose. The fecal excretion data indicates that both 3H- and 14C-derived radioactivity was excreted entirely in the feces. Mean total radioactivity excreted in the feces ranged from approximately 95 to 105% in the rats and 92 to 102% in the dogs. Across the different treatment regimens, in both species, tissue concentrations were negligible (< 0.01% total dose) and no differences in tissue profile were noted, indicating that there was no effect of pretreatment on [3H, 14C]GT31-104 absorption. GT31-104 was extracted with water, and the water-soluble portion contained radioactivity that would correlate to approximately 0.19% of the 3H dose and 0.41% of the 14C dose; this portion probably accounted for the negligible radioactivity observed systemically. Analysis of gastrointestinal (GI) tract tissues with contents indicated that GT31-104 is rapidly cleared from the GI tract. These data indicate that GT31-104 is not absorbed from the GI tract in rats and dogs.

Analgesic effect and bioavailability of oral ketogan given as tablets or mixture to patients with chronic pain of malignant origin.

Thirteen cancer patients with moderate to severe chronic pain of malignant origin on treatment with Ketogan tablets were included in an open non-randomized cross-over study comparing the analgesic effect, side effects and serum concentrations of Ketogan tablets and mixture. The patients were six days in hospital and were dosed two days with tablets, two days with mixture and finally another two days with tablets. Recordings of pain and side effects and collection of blood samples prior to dosing and hourly thereafter until remedication were performed on the second day of each dosing period in a morning dose interval. The analgesic effect judged by visual analog score (VAS) and pain intensity differences (PID), the areas under the serum concentration time curves, and the average serum concentrations for the three groups were compared. It was not possible do detect any differences among the three groups concerning the analgesic effect, duration of analgesic effect, the serum concentrations and the side effects. The mean plasma half-life of ketobemidone was 2.74 h +/- 0.90 (SD) and the mean relative bioavailability of the mixture was slightly above 100%. Linear regression analysis revealed a significant correlation between ketobemidone serum concentrations and analgesic effect, VAS, for tablet one and for the mixture but not for tablet two, possibly due to the fixed dosing schedule and to the positive effect of hospitalization on the pain.

Analytical methods for the determination of naftifine and its metabolites in human plasma and urine.

Analytical procedures have been worked out for the determination both of naftifine, the antifungal constituent of Exoderil, and its demethyl derivative in plasma, and of the metabolites p-hydroxyphenyl-, 3,4-dihydrodiol- and 7,8-dihydrodiol-naftifine and naphthoic acid in urine. For plasma a HPLC-method with UV-detection after extraction of the samples with hexane is used. In urine samples the metabolites are deconjugated, extracted with chloroform, silylated and measured by GC with flame ionization detection. The standard calibration curves for the parent compound and metabolites are linear. The detection limit for naftifine and its demethyl derivative is ca. 5 ng/ml, for naphthoic acid 1 microgram/ml and for the other metabolites 2 micrograms/ml.

The role of the lymphatic transport in the enteral absorption of naftifine by the rat.

After intestinal absorption of 3H-naftifine by the rat, an appreciable amount of radioactivity is drained via the lymphatics, mainly as parent compound associated almost exclusively with chylomicrons. In contrast, metabolites are mainly transported in the portal blood. Drug transported via the portal route undergoes high extraction and extensive degradation by the liver and is released to the systemic circulation in small quantities only. As is shown from a comparison of animals with intact and with drained lymph flow, the systemic blood level of naftifine is determined to a large extent by drug transported via the lymphatic route.