Abstract: The present invention relates to a method for extending a half-life of a protein, comprising substituting one lysine residue in each of the amino acid sequences in two proteins, or to a protein having an extended half-life. The protein in which lysine residues have been substituted according to the present invention remains in the body for an extended period of time, and exhibits excellent treatment results. In addition, two proteins can be produced and provided in a single production process.

Abstract: Disclosed are a semiconductor device and a method of fabricating the same. The semiconductor device may include a substrate having a groove therein extending in a first direction, a gate insulating layer in the groove, a first conductive pattern in the groove and on the gate insulating layer, and a word line capping pattern in the groove and on the first conductive pattern. The first conductive pattern may include a first material and may include a first conductive portion adjacent to the word line capping pattern and a second conductive portion adjacent to a bottom end of the groove. A largest dimension of a grain of the first material of the first conductive portion may be equal to or larger than that of the first material of the second conductive portion.

Abstract: Embodiments relate to a semiconductor device including a body made of a first conducting semiconductor material, a source and a drain made of a second conducting semiconductor material and formed on the body, a first gate formed on the body with a gate insulating layer interposed between the first gate and the body, a second gate formed opposite the first gate with respect to the body, and an insulating layer stack having a charge storage layer formed between the body and the second gate, and a method for controlling a synapse weight of a target semiconductor device within a neural network including semiconductor devices.

Abstract: Semiconductor circuits are provided for emulating neuron firing process using a positive feedback transistor having first and second gate electrodes in the longitudinal direction of a channel region. The first gate electrode is connected to a gate electrode of a first p-channel MOSFET to be an input terminal and the second gate electrode is connected to a drain to be applied with a supply voltage. Thus electrons and holes can accumulate separately in a channel region (i.e., a body) under each of the gate electrodes by applying input signals to the input terminal and drastically reduce the wasted power consumption in the non-fired neurons because the current is turned on and off only at a moment that corresponds to a firing of the neuron. Thus, the semiconductor circuits can be driven by low power and have the same level of endurance as a general MOSFET.

Abstract: Semiconductor circuits are provided for emulating neuron firing process using a positive feedback transistor having first and second gate electrodes in the longitudinal direction of a channel region. The first gate electrode is connected to a gate electrode of a first p-channel MOSFET to be an input terminal and the second gate electrode is connected to a drain to be applied with a supply voltage. Thus electrons and holes can accumulate separately in a channel region (i.e., a body) under each of the gate electrodes by applying input signals to the input terminal and drastically reduce the wasted power consumption in the non-fired neurons because the current is turned on and off only at a moment that corresponds to a firing of the neuron. Thus, the semiconductor circuits can be driven by low power and have the same level of endurance as a general MOSFET.