Abstract: A method for preparing a high entropy alloy (HEA) structure includes the steps of: preparing an alloy by arc melting raw materials comprising five or more elements; drop casting the melted alloy into a cooled mold to form a bulk alloy; applying an external force against the bulk alloy to reshape the bulk alloy; and heat-treating the reshaped bulk alloy, wherein the bulk alloy is reshaped and/or heat-treated for manipulating the distribution of the microstructure therein. The present invention also relates to a high entropy alloy structure prepared by the method.

Abstract: The present invention provides a method of in situ 4D printing of high-temperature materials including 3D printing a structure of an ink including a precursor. The structure is treated with controlled high energy flow to create a portion which has a different coefficient of thermal expansion/thermal shrinkage ratio. The structure is heated and the difference in the coefficient of thermal expansion creates an interface stress to cause a selected level of deformation. Alternatively, two structures with different coefficients of expansion/thermal shrinkage ratio may be printed. Thermal treatment of the two structures creates an interface stress to cause a selected level of deformation.

Abstract: An object of the present invention is to prepare a functional intestinal organoid from pluripotent stem cells. An intestinal organoid is prepared from pluripotent stem cells, by the following steps (1) to (4): (1) differentiating pluripotent stem cells into endoderm-like cells; (2) differentiating the endoderm-like cells obtained in step (1) into intestinal stem cell-like cells; (3) culturing the intestinal stem cell-like cells obtained in step (2) to form spheroids; and (4) differentiating the spheroids formed in step (3) to form an intestinal organoid, the step including culture in the presence of a MEK1/2 inhibitor, a DNA methylation inhibitor, a TGF-? receptor inhibitor, and a ?-secretase inhibitor, in addition to an epidermal growth factor, a BMP inhibitor, and a Wnt signal activator.

Abstract: This invention relates to a zinc powder electrode formed on a MXene framework. The zinc powder anode formed on an MXene framework, referred to as an MXene@Zn electrode can act as an anode and/or cathode for an electrochemical cell or battery. As such, the present invention further relates to an electrode comprising MXene@Zn and a battery comprising such an electrode.

Abstract: A microfluidic device for detection of an analyte in a fluid is described. The microfluidic device comprises a substrate having a first surface defining entrances to one or more chambers defined in the substrate, surfaces of the chambers defining a second surface of the substrate, the first surface being modified for selective targeting and capture of at least one analyte to operably effect a blocking of the entrance to at least one of the chambers, and wherein a response characteristic of the microfluidic device is operably varied by the blocking of the entrance to the at least one of the chambers, thereby providing an indication of the presence of the analyte within the fluid.

Abstract: The present invention provides a versatile method which has a high diagnostic accuracy rate on the suitability of esophageal cancer for endoscopic therapy and enables the simple and objective determination of the suitability or unsuitability for endoscopic therapy.

Abstract: An on-chip antenna comprising an electrically insulating substrate having first and second faces; a metal layer arranged on the second face; and, a dipole antenna structure arranged on the first face, the dipole antenna structure comprising a dipole antenna and a feed structure connected to the dipole antenna; the on-chip antenna being configured such that when the feed structure is fed with an electrical signal it operates simultaneously in (i) at least one dielectric resonator mode to function as a dielectric resonance antenna, and (ii) at least one dipole mode to function as a cavity backed dipole antenna.

Abstract: The present invention provides a means for treating and/or preventing peripheral nerve disorder by facilitating regeneration of peripheral nerves. Specifically, the present invention provides a composition for treating and/or preventing peripheral nerve disorder comprising a compound represented by the general formula (I): wherein R1 is lower alkyl substituted with lower alkoxy, lower alkyl substituted with a heterocyclic group, a heterocyclic group, or a group represented by the formula (IIa): R4O—R5m??(IIa) wherein R4 is lower alkyl, R5 is lower alkylene, and m is an integer of 1 to 6; R2 is lower alkyl optionally substituted with phenyl; and R3 is lower alkyl optionally substituted with halogen, lower alkoxy, or phenyl; condensed polycyclic hydrocarbon; or hydrogen.

Abstract: Three-dimensional (3D) hierarchical morphologies widely exist in natural and biomimetic materials, which impart preferential functions including liquid and mass transport, energy conversion, and signal transmission for various applications. While notable progress has been made in the design and manufacturing of various hierarchical materials, the state-of-the-art approaches suffer from limited materials selection, high costs, as well as low processing throughput. Herein, by harnessing the configurable elastic crack engineering-controlled formation and configuration of cracks in elastic materials, an effect normally avoided in various industrial processes, the present invention provides a facile and powerful technique to enable the faithful transfer of arbitrary hierarchical structures with broad material compatibility and structural and functional integrity.

Abstract: The present invention provides an integrated system of moisture removal, air purification, and air ventilation of the process air while some of the energy and resources required for operation of the system are self-sustained, or in some aspects the present system is self-regenerated such as heating and cooling of air and water exchanged among various elements/modules/members within the system or between the system and the surroundings, such that it becomes an all-time and all-round air dehumidifier, purifier and ventilator. Related method for removing air moisture from the surroundings using the present system is also provided.

Abstract: Received is a main program representing one Engineering Design Optimization Problem (EDOP), the EDOP including polynomial terms with product values. A number (N) of available parallel processors for parallel processing are identified. The main program is partitioned into N subprograms, N being a positive integer greater than one. The N subprograms have fewer overlapping product values between them compared to existing solutions, and the partitioning is prime-number based. Each of the available parallel processors then independently solve a unique subprogram of the N subprograms, resulting in N unique solutions. A best solution is automatically chosen from among the N unique solutions and the best solution is automatically applied to the EDOP.

Abstract: A method of making a magnetically-drivable microrobot that is suitable for carrying and delivering cells includes photo-curing a photo-curable material composition to form a body of the magnetically-drivable microrobot. The photo-curable material composition includes a degradable component, a structural component, a magnetic component, and a photo-curing facilitation composition including a photoinitiator component and a photosensitizer component.

Abstract: A screening system provided with a potential-dependent Na ion channel that extends the duration of the action potential associated with depolarization, and a K ion channel that deepens the resting membrane potential in the negative direction, said screening system furthermore including cells provided with ion channels that contribute to deepening the resting membrane potential in the negative direction and/or shortening the duration of the action potential as target ion channels. By such cells, the action of a test compound on the target ion channel can be easily evaluated by providing an inhibitor for the K ion channel to control the probability of cell death.

Abstract: An interactive wearable device includes a ring body and a detector. The ring body includes a top insulating layer, a bottom insulating layer, and an intermediate insulating layer disposed in between the top and the bottom insulating layers. The detector includes a receiving electrode layer disposed in between the top and the intermediate insulating layers, a transmitting electrode layer disposed in between the intermediate and the bottom insulating layers, and a ground electrode layer embedding in the bottom insulating layer and electrically coupled to an electrical ground. The receiving electrode layer has a plurality of receiving electrode portions separated from each other and arranged in a matrix and along a curve path. The interactive wearable device is configured to analyze the movement event at least according to a variation of a data set in response to the movement event, measured by receiving electrode portions.

Abstract: The present disclosure provides a method for forming piezoelectric films on surfaces of arbitrary morphologies. The method includes providing a sol for forming the piezoelectric film; spraying the sol onto the surface thereby forming a liquid film containing the sol on the surface; wiping the liquid film with a flattening tool for flattening the liquid film; drying the flattened liquid film thereby forming a gel layer; and annealing the gel layer thereby forming the piezoelectric film. The piezoelectric films with high uniformity and desired thickness can be formed on curved and even wrinkled surfaces by the present method.

Abstract: A wearable device that is capable of harvesting kinetic energy from wrist motions using piezoelectric and/or electromagnetic energy harvesters is disclosed. A first part of the device is worn on the user and second part of the device is movable against the second part to accentuate the frequency of movements.

Abstract: The present invention provides wideband millimeter-wave SIW-fed FPC filtering antenna comprising a partially reflecting surface (PRS) and a filtering source configured to radiate a millimeter-wavelength electromagnetic wave. The filtering source comprises a conductive reflecting plane configured to work with the PRS to form a Fabry-Perot cavity; radiating elements including a pair of shorted radiating patches electrically connected to a ground plane through a pair of probes; and a substrate integrated waveguide (SIW) feeding structure coupled to the pair of radiating patches through a coupling aperture. The SIW-fed FPC filtering antenna has the advantages of wider bandwidth, higher directivity/gain, reduced structural complexity, compact size and appropriate feeding type for millimeter-wave applications.

Abstract: The present invention provides a marker gene capable of detecting the undifferentiated cells that remain or become included in a differentiated cell population. Undifferentiated cells present in a differentiated cell population are detected by using at least one gene selected from the group consisting of LINC00678 and PRDM14 as an undifferentiation marker. A method of detecting undifferentiated cells; a method of using the gene as an undifferentiation marker; and a kit for detecting undifferentiated cells. A method of selecting an undifferentiated cell clone is also provided.

Abstract: A power supply apparatus includes a power supply configured to apply an alternating current to a magnetic field generation apparatus; and a controller configured to control the alternating current applied by the power supply. The controller controls the power supply to apply the alternating current having a waveform pattern including a plurality of current waveforms having different frequency spectrums from each other.

Abstract: A nano scale robotic system for single cell DNA sequencing of a strand of DNA positioned on a slide utilizes an atomic force microscope (AFM) having an end effector in the form of a cantilever with a tip. The AFM causes its cantilever tip to scan over the base pairs of the DNA strand. A pair of spaced-apart electrodes at the tip makes contact with opposite sides of the DNA strand and the current between bases of the DNA strand is measured by a current measurement system connected to the electrodes. An artificial intelligence-based data analytic system determines the DNA sequence based on the current from the current measuring system. The AFM tip is guided over the DNA strand by comparing compressed desired intensity local scan images and compressed actual intensity local scan images and using the difference to control the location of the tip.