Quantitative dose-response curves from subcellular lipid multilayer microarrays.

The dose-dependent bioactivity of small molecules on cells is a crucial factor in drug discovery and personalized medicine. Although small-molecule microarrays are a promising platform for miniaturized screening, it has been a challenge to use them to obtain quantitative dose-response curves in vitro, especially for lipophilic compounds. Here we establish a small-molecule microarray assay capable of controlling the dosage of small lipophilic molecules delivered to cells by varying the sub-cellular volumes of surface supported lipid micro- and nanostructure arrays fabricated with nanointaglio. Features with sub-cellular lateral dimensions were found necessary to obtain normal cell adhesion with HeLa cells. The volumes of the lipophilic drug-containing nanostructures were determined using a fluorescence microscope calibrated by atomic-force microscopy. We used the surface supported lipid volume information to obtain EC-50 values for the response of HeLa cells to three FDA-approved lipophilic anticancer drugs, docetaxel, imiquimod and triethylenemelamine, which were found to be significantly different from neat lipid controls. No significant toxicity was observed on the control cells surrounding the drug/lipid patterns, indicating lack of interference or leakage from the arrays. Comparison of the microarray data to dose-response curves for the same drugs delivered liposomally from solution revealed quantitative differences in the efficacy values, which we explain in terms of cell-adhesion playing a more important role in the surface-based assay. The assay should be scalable to a density of at least 10,000 dose response curves on the area of a standard microtiter plate.

Capture of carbon dioxide by amine-impregnated as-synthesized MCM-41.

The novel carbon dioxide (CO2) adsorbents with a high capture efficiency were prepared through impregnating the as-synthesized MCM-41 with three kinds of amines, namely diethylenetriamine (DETA), triethylenetetramine (TETA) and 2-amino-2-methyl-1-propanol (AMP). The resultant samples were characterized by small angle X-ray diffraction and low temperature N2 adsorption. The synthesis way not only saves the energy or extractor to remove the template but also is environmentally friendly due to the absence of the potential pollutants such as toluene. CO2 capture was investigated in a dynamic packed column. The sample impregnated by TETA showed the highest adsorption capacity, approximately 2.22 mmol/g at 60 degrees C due to its highest amino-groups content among the three amines. The CO2 adsorption behavior was also investigated with the deactivation model, which showed an excellent prediction for the breakthrough curves.

Comparison of the mutagenicity and mutagen specificity of ethylenimine with triethylenemelamine in the ad-3 region of heterokaryon 12 of Neurospora crassa.

Studies have been performed to compare the mutagenicity and mutagenic specificity of the trifunctional alkylating agent, triethylenemelamine (TEM), and a closely related monofunctional agent, ethylenimine (EI), in the adenine-3 (ad-3) region of a 2-component heterokaryon (H-12) of Neurospora crassa. The primary objective of our studies was to characterize the genetic damage produced by each agent with regard to (1) mutagenic potency, and (2) the spectrum of specific-locus mutations induced in a lower eukaryotic organism. As in higher eukaryotes, specific-locus mutations in the ad-3 region of H-12 result from gene/point mutations, multilocus deletion mutations, and multiple-locus mutations. Specific-locus mutations resulting from gene/point mutation and multilocus deletion mutation can be detected in higher eukaryotes, but multiple-locus mutations can be detected only with difficulty or not at all. Our experiments with the ad-3 forward-mutation assay have demonstrated that TEM is a strong mutagen (maximum forward-mutation frequency between 100 and 1000 ad-3 mutations per 10(6) survivors) and EI is a moderate mutagen (maximum forward-mutation frequency between 10 and 100 ad-3 mutations per 10(6) survivors) for the induction of specific-locus mutations in the ad-3 region. Classical genetic tests were used to identify the different genotypic classes and subclasses among the EI- and TEM-induced ad-3 mutations from each experiment. The overall data base demonstrates that both EI- and TEM-induced ad-3 mutations result predominantly from gene/point mutations at the ad-3A and ad-3B loci (97.3% and 95.5%, respectively), and infrequently from multilocus deletion mutations (2.7% and 4.5%, respectively). Heterokaryon tests for allelic complementation on TEM- and EI-induced ad-3B mutations, however, have revealed a difference between the percentages showing allelic complementation (63.1% and 40.9%, respectively). Based on the specific revertibility of complementing and noncomplementing ad-3B mutations induced by other agents, this difference in the percentages of ad-3B mutations showing allelic complementation results from a difference between the spectrum of genetic alterations at the molecular level. In addition, comparison of the ratio of TEM-induced ad-3A and ad-3B mutations with those induced by EI has revealed a difference between the ad-3B/ad-3A ratios. Additional comparisons are made of the mutagenic effects of TEM and EI with those of other chemical mutagens and carcinogens in the ad-3 specific-locus assay in Neurospora.