Abstract: Nutritive proteins are provided. In some embodiments the nutritive proteins comprise a first polypeptide sequence comprising a fragment of a naturally-occurring nutritive protein. In some embodiments the fragment comprises at least one of a) an enhanced ratio of branch chain amino acid residues to total amino acid residues present in the nutritive protein; b) an enhanced ratio of leucine residues to total amino acid residues present in the nutritive protein; and c) an enhanced ratio of essential amino acid residues to total amino acid residues present in the nutritive protein.

Abstract: A method of detecting arcing between two electrical conductors the method including generating an image of the electrical conductors; determining a region of interest in the image where arcing between the electrical conductors is likely to occur, isolating the region of interest processing arcing candidates captured in the image and falling within the region of interest to screen the arcing candidates to reject artefacts likely to have been caused by factors other than arcing, and validating that a selected arcing candidate is an arc by further processing the selected arcing candidate.

Abstract: A system for detecting arcing between two electrical conductors includes an image capture arrangement including a plurality of image capture devices configured to be arranged in spaced relationship relative to one another and to a contact region between the electrical conductors so as to provide depth information. A processor is responsive to the image capture arrangement for computing a depth range of the contact region between the electrical conductors relative to a first image capture device of the image capture arrangement and determining if an arcing candidate appears within the computed depth range for the first image capture device of the image capture arrangement and at least one further image capture device of the image capture arrangement and, if it does, flagging the candidate as arcing at the contact region.

Abstract: Charged nutritive proteins provided. In some embodiments the nutritive proteins an aqueous solubility of at least 12.5 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 50 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 100 g/L at pH 7.

Abstract: Nutritive proteins comprising no phenylalanine (Phe) are provided. In some embodiments the nutritive proteins comprise at least one of a level of a) a ratio of branch chain amino acid residues to total amino acid residues present in the nutritive protein equal to or greater than the ratio of branch chain amino acid residues to total amino acid residues present in a benchmark protein; b) a ratio of leucine residues to total amino acid residues present in the nutritive protein equal to or greater than the ratio of leucine residues to total amino acid residues present in a benchmark protein; and c) a ratio of essential amino acid residues to total amino acid residues present in the nutritive protein equal to or greater than the ratio of essential amino acid residues to total amino acid residues present a benchmark protein.

Abstract: Nutritive proteins are provided. In some embodiments the nutritive proteins comprise at least one of a level of a) a ratio of branch chain amino acid residues to total amino acid residues present in the nutritive protein equal to or greater than the ratio of branch chain amino acid residues to total amino acid residues present in whey protein; b) a ratio of leucine residues to total amino acid residues present in the nutritive protein equal to or greater than the ratio of leucine residues to total amino acid residues present in whey protein; and c) a ratio of essential amino acid residues to total amino acid residues present in the nutritive protein equal to or greater than the ratio of essential amino acid residues to total amino acid residues present in whey protein.

Abstract: Methods of producing an unsaturated free fatty acid comprising at least 18 carbon atoms are provided. In some embodiments, the methods comprise culturing an engineered microorganism in a culture medium, wherein the engineered microorganism comprises at least one recombinant enzyme selected from acyl-lipid desaturase delta-9 (EC:1.14.19.1), acyl-lipid desaturase delta-12 (EC:1.14.19.6), acyl-lipid desaturase delta-15 (EC:1.14.19.-), and thioesterase (EC:3.1.2.14). Engineered microorganisms comprising at least one of those recombinant enzymes are also provided. The methods and organisms can be used to produce at least one free fatty acid selected from oleic acid, linoleic acid and ?-linolenic acid.

Abstract: Nutritive proteins are provided. In some embodiments the nutritive proteins comprise a first polypeptide sequence comprising a fragment of a naturally-occurring nutritive protein. In some embodiments the fragment comprises at least one of a) an enhanced ratio of branch chain amino acid residues to total amino acid residues present in the nutritive protein; b) an enhanced ratio of leucine residues to total amino acid residues present in the nutritive protein; and c) an enhanced ratio of essential amino acid residues to total amino acid residues present in the nutritive protein.

Abstract: Charged nutritive proteins are provided. In some embodiments the nutritive proteins an aqueous solubility of at least 12.5 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 50 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 100 g/L at pH 7.

Abstract: Charged nutritive proteins are provided. In some embodiments the nutritive proteins an aqueous solubility of at least 12.5 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 50 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 100 g/L at pH 7.

Abstract: Charged nutritive proteins are provided. In some embodiments the nutritive proteins an aqueous solubility of at least 12.5 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 50 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 100 g/L at pH 7.

Abstract: A fastening system for use with a modular panel assembly having at least two panels includes one or more securing apertures formed through a first panel and one or more engaging projections provided on a second panel, each one of the engaging projections being sized and positioned to be engageable with a corresponding one of the securing apertures on the first panel. Panels for use in forming a modular panel assembly, modular containers, and methods of constructing modular containers are provided.

Abstract: Charged nutritive proteins are provided. In some embodiments the nutritive proteins an aqueous solubility of at least 12.5 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 50 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 100 g/L at pH 7.

Abstract: Modular panels for forming a container have a plurality of securing receptacles on a first end of the panel and a plurality of securing receptacles on a second end of the panel. Each one of the securing receptacles on the first end of the panel is position at approximately the same height as a corresponding one of the securing receptacles on the second end of the panel. Each pair of corresponding securing receptacles is dimensioned to receive a securing bar therein that can be locked in place to hold adjacent panels in a secured position.

Abstract: A fastening system for use with a modular panel assembly having at least two panels includes one or more securing apertures formed through a first panel and one or more engaging projections provided on a second panel, each one of the engaging projections being sized and positioned to be engageable with a corresponding one of the securing apertures on the first panel. Panels for use in forming a modular panel assembly, modular containers, and methods of constructing modular containers are provided.

Abstract: Charged nutritive proteins are provided. In some embodiments the nutritive proteins an aqueous solubility of at least 12.5 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 50 g/L at pH 7. In some embodiments the nutritive proteins an aqueous solubility of at least 100 g/L at pH 7.

Abstract: A semiconductor device may include a semiconductor layer having a first conductivity type, a well region of a second conductivity type in the semiconductor layer wherein the first and second conductivity types are different, and a terminal region of the first conductivity type in the well region. An epitaxial semiconductor layer may be on the surface of the semiconductor layer including the well region and the terminal region with the epitaxial semiconductor layer having the first conductivity type across the well and terminal regions. A gate electrode may be on the epitaxial semiconductor layer so that the epitaxial semiconductor layer is between the gate electrode and portions of the well region surrounding the terminal region at the surface of the semiconductor layer.

Abstract: A semiconductor device may include an insulating layer and a semiconductor electrode on the insulating layer. An area of increased electrical resistance may separate a contact area of the semiconductor electrode from an active area of the semiconductor electrode. In addition, a metal contact may be provided on the contact area of the semiconductor electrode opposite the insulating layer.

Abstract: A method of forming a semiconductor device may include forming a terminal region of a first conductivity type within a semiconductor layer of the first conductivity type. A well region of a second conductivity type may be formed within the semiconductor layer wherein the well region is adjacent at least portions of the terminal region within the semiconductor layer, a depth of the well region into the semiconductor layer may be greater than a depth of the terminal region into the semiconductor layer, and the first and second conductivity types may be different. An epitaxial semiconductor layer may be formed on the semiconductor layer, and a terminal contact region of the first conductivity type may be formed in the epitaxial semiconductor layer with the terminal contact region providing electrical contact with the terminal region. In addition, an ohmic contact may be formed on the terminal contact region. Related structures are also discussed.

Abstract: A semiconductor device may include an insulating layer and a semiconductor electrode on the insulating layer. An area of increased electrical resistance may separate a contact area of the semiconductor electrode from an active area of the semiconductor electrode. In addition, a metal contact may be provided on the contact area of the semiconductor electrode opposite the insulating layer.