Patent application number | Description | Published |
20090019934 | Micro-sensor for sensing chemical substance - The invention discloses a micro-sensor for sensing a chemical substance. The micro-sensor according to the invention includes a substrate, a micro-cantilever, an electrode structure, and a measuring device. The micro-cantilever is formed on the substrate and has a capturing surface for capturing chemical substances. The electrode structure is for supplying an electrical field. The electrical field is disposed so as to assist the capturing surface in capturing chemical substances. The measuring device, coupled to the micro-cantilever, is for measuring a variation on a mechanical property of the micro-cantilever induced by the captured chemical substance and interpreting the variation on the mechanical property of the micro-cantilever into information relative to the chemical substance. | 01-22-2009 |
20090038492 | Micro-Stamping Method for Photoelectric Process - This invention discloses a micro-stamping method for photoelectric process. First of all, in this invention, the micro-stamping method provides a stamp, an ink, an inkpad and a substrate, wherein the stamp or the inkpad having specific protruding bodies and the ink is one element of the group consisting of red ink, green ink and blue ink. Further, by adherence of the ink to the stamp, the specific pattern can be transferred to the surface of the substrate. Furthermore, this micro-stamping method comprises an ink adherence process, a positioning process, a pattern transferring process and a fixation process, and the above-mentioned processes will repeat until the three inks, such as red ink, green ink and blue ink, all adhered and fixed on the predetermined places of substrate. Moreover, this invention can be applied in the fabricating of color filters of TFT-LCD, emitting layers of OLED (Organic Light Emitting Diode), emitting layers of PLED (Polymer Light Emitting Diode) or other related photoelectric processes. | 02-12-2009 |
20100274101 | WIRELESS MONITORING BIO-DIAGNOSIS SYSTEM - A MEMS wireless monitoring bio-diagnosis system includes an implantable biosensor system chip, a surface transmitter and an external monitor center. The implantable biosensor system chip contains a biosensor for a cardio-vascular indicator and a wireless transmitter to deliver detected bio-signal data. With the MEMS wireless monitoring bio-diagnosis system, the bio-signal data can be monitored effectively and transmitted to a remote medical unit. | 10-28-2010 |
20140209484 | VALPROIC ACID BIOSENSOR AND METHOD FOR MEASURING CONCENTRATION OF VALPROIC ACID - The present disclosure relates to a valproic acid biosensor. In some embodiments, the valproic acid biosensor may comprise a microcantilever, a self-assembly monolayer, and a valproic acid antibody layer. The self-assembly monolayer may immobilize on the microcantilever surface. The valproic acid antibody layer may immobilize on the self-assembly monolayer. The valproic acid antibody layer may be used to bind with valproic acid drug samples. The present disclosure further relates to methods for measuring the concentration of valproic acid drug samples. | 07-31-2014 |
20140212989 | PHENYTOIN BIOSENSOR AND METHOD FOR MEASURING CONCENTRATION OF PHENYTOIN - The present disclosure relates to a phenytoin biosensor. In some embodiments, the phenytoin biosensor may comprise a microcantilever, a self-assembly monolayer, and a phenytoin antibody layer. The self-assembly monolayer may immobilize on the microcantilever surface. The phenytoin antibody layer may immobilize on the self-assembly monolayer. The phenytoin antibody layer may be used to bind with phenytoin drug samples. The present disclosure further relates to methods for measuring the concentration of phenytoin drug samples. | 07-31-2014 |
Patent application number | Description | Published |
20090057789 | PACKAGE STRUCTURE FOR MICRO-SENSOR - The invention discloses a package structure for a micro-sensor including a micro-cantilever for capturing a chemical substance. The package structure, according to the invention, includes a first substrate, a second substrate, and a casing. The first substrate thereon forms a processing circuit. The micro-sensor is bonded to a first upper surface of the first substrate and is electrically connected to the processing circuit capable of outputting a signal relative to the chemical substance sensed by the micro-sensor. The second substrate has a formed-through aperture. The second substrate is bonded to the first substrate such that the micro-sensor is disposed in the formed-through aperture. The casing is bonded to the second substrate and includes a reaction chamber in which the micro-cantilever is installed and a fluid containing the chemical substance flows into. | 03-05-2009 |
20100002284 | METHOD OF MODULATING RESONANT FREQUENCY OF TORSIONAL MEMS DEVICE - A method of modulating resonant frequency of a torsional MEMS device is provided. A torsional MEMS device is provided and a resonant frequency test is performed to measure a raw frequency of the torsional MEMS device. If the raw resonant frequency of the torsional MEMS device is greater than a standard resonant frequency, at least one mass increaser is bonded to the torsional MEMS device. Therefore, the raw resonant frequency is reduced as much as the standard resonant frequency. | 01-07-2010 |
20100002285 | TORSIONAL MEMS DEVICE - A torsional MEMS device is disclosed. The torsional MEMS device includes a support structure, a platform, and at least two hinges, which connects the platform to the support structure. The platform has an active area and a non-active area. A plurality of sacrificial elements is disposed in the non-active area. If the resonant frequency of the torsional MEMS device is less than a predetermined standard resonant frequency of the torsional MEMS device, at least one sacrificial element is removed to reduce the total mass of the torsional MEMS device, and so as to increase the resonant frequency of the torsional MEMS device. | 01-07-2010 |
20100134870 | METHOD OF MODULATING RESONANT FREQUENCY OF TORSIONAL MEMS DEVICE - A torsional MEMS device is disclosed. The torsional MEMS device includes a support structure, a platform, and at least two hinges, which connects the platform to the support structure. The platform has an active area and a non-active area. A plurality of sacrificial elements is disposed in the non-active area. If the resonant frequency of the torsional MEMS device is less than a predetermined standard resonant frequency of the torsional MEMS device, at least one sacrificial element is removed to reduce the total mass of the torsional MEMS device, and so as to increase the resonant frequency of the torsional MEMS device. | 06-03-2010 |
20110158288 | Apparatus With Temperature Self-Compensation And Method Thereof - A system for compensating a thermal effect is provided and includes a substrate structure and a microcantilever. The substrate structure includes a first piezoresistor. The first piezoresistor is buried in the substrate structure and has a first piezoresistance having a first relation to a first variable temperature. The microcantilever has the thermal effect and a second piezoresistance having a second relation to the first variable temperature, wherein the thermal effect is compensated based on the first and the second relations. | 06-30-2011 |