The present disclosure presents glucose sensing methods and systems. One such system comprises an electrospun-nanofibrous-membrane (ENFM)-based amperometric glucose sensor integrated on a silicon chip, in which the glucose sensor has a working electrode, a reference electrode, and a counter electrode, wherein the working electrode comprises an ENFM-based sensing electrode. The system further comprises a potentiostat circuit integrated on the silicon chip such that the potentiostat circuit comprises a voltage control unit to control a voltage difference between the working electrode and the reference electrode and a transimpedance amplifier to measure a current flow between the working electrode and the counter electrode, in which a strength of the current flow corresponds to an amount of glucose present in a sample of blood on the glucose sensor.

An object of the present invention is to provide a device for evaluating a state of interstitial fluid, blood, urine, tears, sweat, saliva of human and non-human organisms, foods and drinks, brewed product, etc., a system, a program, and an evaluation method using these.

The present invention is to provide a device for evaluating a state of a sample which comprises an action part for allowing lactate dehydrogenase to act on a sample, and a sensor for sensing the state of the sample on which lactate dehydrogenase is allowed to act, a system, a program, a method for evaluating the state of the sample using these, and an enzyme to be used therefor.

Oxidase-based sensors and methods of using the sensors are provided.

Methods and analyte sensors including at least a first working electrode having a first active area thereon, and performing a dip coating operation to deposit a bilayer membrane upon the first working electrode and the first active area. The bilayer may include an inner layer having a first membrane polymer and an outer layer having a second membrane polymer, the first membrane polymer and the second membrane polymer differing from one another. The dip coating operation may comprise one or more first dips in a first membrane formulation to form the inner layer of the bilayer membrane and one or more second dips in a second membrane formulation to form the outer layer of the bilayer membrane upon the inner layer.

Among the various aspects of the present disclosure is the provision of a noninvasive and localized brain liquid biopsy using focused ultrasound. Briefly, therefore, the present disclosure is directed to methods and systems to identify brain lesion or tumor characteristics without the need for a solid brain biopsy.

Provided is a technique of predicting prognosis of skin cancer. A method for prognosis prediction of skin cancer includes: a step of obtaining a correlation amount correlated with an expression level of a glucose-6-phosphate dehydrogenase in a sample collected from a patient with the skin cancer; and a step of determining that the prognosis of the skin cancer is poorer when the correlation amount is large than that when the correlation amount is small.

A system for determining a level of hematocrit includes a test strip configured to receive a sample; a meter configured to receive the test strip; and further including circuitry and a microprocessor, the circuitry and microprocessor configured to apply electrical energy to the test strip and the sample and determine an electrical property of the sample, either the impedance phase angle or the impedance magnitude of the test strip and the sample and, based on the electrical property, calculate the level of hematocrit in the sample.

An aspect of the invention provides a method of selectively necrosing cells, comprising: providing a plurality cells, including at least one cancer cell and at least one non-cancerous cell; and administering to the cells a compound, including an HDM-2 targeting component and a cytotoxic component attached to the HDM-2 targeting component, wherein said compound comprises a membrane-active form.

The present disclosure presents glucose sensing methods and systems. One such system comprises an electrospun-nanofibrous-membrane (ENFM)-based amperometric glucose sensor integrated on a silicon chip, in which the glucose sensor has a working electrode, a reference electrode, and a counter electrode, wherein the working electrode comprises an ENFM-based sensing electrode. The system further comprises a potentiostat circuit integrated on the silicon chip such that the potentiostat circuit comprises a voltage control unit to control a voltage difference between the working electrode and the reference electrode and a transimpedance amplifier to measure a current flow between the working electrode and the counter electrode, in which a strength of the current flow corresponds to an amount of glucose present in a sample of blood on the glucose sensor.

The object is to provide a novel enzyme exhibiting cholesterol dehydrogenase activity. Provided is a mutant enzyme having an amino acid sequence of a microorganism-derived cholesterol oxidase, which is composed of: (1) an amino acid corresponding to the amino acid at the position 113 of the amino acid sequence of SEQ ID NO: 1; (2) an amino acid corresponding to the amino acid at the position 362 of the amino acid sequence of SEQ ID NO: 1; (3) an amino acid corresponding to the amino acid at the position 402 of the amino acid sequence of SEQ ID NO: 1; (4) an amino acid corresponding to the amino acid at the position 412 of the amino acid sequence of SEQ ID NO: 1; (5) an amino acid corresponding to the amino acid at the position 468 of the amino acid sequence of SEQ ID NO: 1; and others.