Digital droplet reactors are useful as chemical and biological containers to discretize reagents into picolitre or nanolitre volumes for analysis of single cells, organisms, or molecules. However, most DNA based assays require processing of samples on the order of tens of microlitres and contain as few as one to as many as millions of fragments to be detected. Presented in this work is a droplet microfluidic platform and fluorescence imaging setup designed to better meet the needs of the high-throughput and high-dynamic-range by integrating multiple high-throughput droplet processing schemes on the chip. The design is capable of generating over 1-million, monodisperse, 50 picolitre droplets in 2-7 minutes that then self-assemble into high density 3-dimensional sphere packing configurations in a large viewing chamber for visualization and analysis. This device then undergoes on-chip polymerase chain reaction (PCR) amplification and fluorescence detection to digitally quantify the sample's nucleic acid contents. Wide-field fluorescence images are captured using a low cost 21-megapixel digital camera and macro-lens with an 8-12 cm(2) field-of-view at 1× to 0.85× magnification, respectively. We demonstrate both end-point and real-time imaging ability to perform on-chip quantitative digital PCR analysis of the entire droplet array. Compared to previous work, this highly integrated design yields a 100-fold increase in the number of on-chip digitized reactors with simultaneous fluorescence imaging for digital PCR based assays.
Epoxides
are useful intermediates for the manufacture of a diverse
set of chemical products. Current routes of olefin epoxidation
either involve hazardous reagents or generate stoichiometric side
products, leading to challenges in separation and significant waste
streams. Here, we demonstrate a sustainable and safe route to epoxidize
olefin substrates using water as the oxygen atom source at room temperature
and ambient pressure. Manganese oxide nanoparticles (NPs) are shown
to catalyze cyclooctene epoxidation with Faradaic efficiencies above
30%. Isotopic studies and detailed product analysis reveal an overall
reaction in which water and cyclooctene are converted to cyclooctene
oxide and hydrogen. Electrokinetic studies provide insights into the
mechanism of olefin epoxidation, including an approximate first-order
dependence on the substrate and water and a rate-determining
step which involves the first electron transfer. We demonstrate that
this new route can also achieve a cyclooctene conversion of ∼50%
over 4 h.
Three-dimensional (3D) microstructures created by microfabrication and additive manufacturing have demonstrated value across a number of fields, ranging from biomedicine to microelectronics. However, the techniques used to create these devices each have their own characteristic set of advantages and limitations with regards to resolution, material compatibility, and geometrical constraints that determine the types of microstructures that can be formed. We describe a microfabrication method, termed StampEd Assembly of polymer Layers (SEAL), and create injectable pulsatile drug-delivery microparticles, pH sensors, and 3D microfluidic devices that we could not produce using traditional 3D printing. SEAL allows us to generate microstructures with complex geometry at high resolution, produce fully enclosed internal cavities containing a solid or liquid, and use potentially any thermoplastic material without processing additives.
With the aid of borylation and oxidative coupling reactions, six new polycyclic aromatic hydrocarbons (PAHs) doped by nitrogen−boron−nitrogen (NBN) units were achieved. The structure−optoelectronic property relationship for this group of compounds was examined. All six compounds are fluorescent with contrasting emission colors and quantum yields.
We present a tunable three-dimensional (3D) self-assembled droplet packing method to achieve high-density micro-reactor arrays for greater imaging efficiency and higher-throughput chemical and biological assays. We demonstrate the capability of this platform's high-density imaging method by performing single molecule quantification using digital polymerase chain reaction, or digital PCR, in multiple self-assembled colloid-like crystal lattice configurations. By controlling chamber height to droplet diameter ratios we predictively control three-dimensional packing configurations with varying degrees of droplet overlap to increase droplet density and imaging sensor area coverage efficiency. Fluorescence imaging of the densely packed 3D reactor arrays, up to three layers high, demonstrates high throughput quantitative analysis of single-molecule reactions. Now a greater number of microreactors can be observed and studied in a single picture frame without the need for confocal imaging, slide scanners, or complicated image processing techniques. Compared to 2D designs, tunable 3D reactor arrays yield up to a threefold increase in density and use 100% of the sensor's imaging area to enable simultaneous imaging a larger number of reactions without sacrificing digital quantification performance. This novel approach provides an important advancement for ultra-high-density reactor arrays.
New BN-heterocyclic compounds have been found to undergo double arene photoelimination, forming rare yellow fluorescent BN-pyrenes that contain two BN units. Most significant is the discovery that the double arene elimination can also be driven by excitons generated electrically within electroluminescent (EL) devices, enabling the in situ solid-state conversion of BN-heterocycles to BN-pyrenes and the use of BN-pyrenes as emitters for EL devices. The in situ exciton-driven elimination (EDE) phenomenon has also been observed for other BN-heterocycles.
Boranes with the general formula of HBR2 have been found to undergo a facile 1,1-hydroboration reaction with pyrido[1,2-a]isoindole (A), resulting in insertion of a BR2 unit into a CN bond and the formation of a variety of BN heterocycles. Investigation on the thermal reactivity of the BN heterocycles revealed that these molecules have two distinct and competitive thermal elimination pathways: HBR2 elimination (or retro-hydroboration) versus RH elimination, depending on the R group on the B atom and the chelate backbone. Mechanistic aspects of these highly unusual reactions have been established from both experimental and computational evidence. Adduct formation between HBR2 and A was found to be the key intermediate in 1,1-hydroboration of A.
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