Abstract: The present disclosure relates to a resistive exercise harness, a rack for use with the harness, and a cart for transporting one or more of the harness, the rack, or weights. The resistive exercise harness can be used to perform various functional movements/exercises and simulate loaded carries/movements relevant to certain occupations/sports/recreations. The resistive exercise harness can promote efficient biomechanics and decrease mechanical stresses on a user's knees and/or lower back relative to other resistive exercises such as a barbell squat. The rack can be assembled in a variety of indoor/outdoor environments for harness usage and disassembled for convenient storage and/or transportation. The cart can interface with the harness and disassembled rack for convenient storage and/or transportation in a variety of indoor/outdoor environments.

Abstract: Disclosed are linear discrete PEG constructs, which can be created and produced in a precise and reproducible way. Key to being able to do these things, where x in the discrete PEGx can vary from about 2 to about 64, is that the processes used to make each linear portion is controlled to give essentially one oligomer/one compound. Having a variable length linear discrete PEG construct that is (a) primarily an linear discrete PEG construct with diagnostic or therapeutic groups attached along a chain of attachment cores, which is attached to a preferential locator; (b) is an m-discrete PEG as the terminal construct on the linear portion, and “hidden”; (c or linear discrete PEG with a terminus group that can be either negatively or positively charged, or neutral; and any of the discrete PEG portions can be designed to be cleaved after entering the cell.

Abstract: Disclosed are discrete PEGylated dyes, that is, dyes, generally ones that are fluorescent, but could also include chemiluminescent or electrochemiluminescent and related dye or dye precursors, that have discrete PEG constructs chemically attached in various configurations on the dye, and in the entire range of constructs, discrete PEG compounds (polyethylene glycol oligomers that are made synthetically according to methods disclosed in U.S. Pat. No. 7,888,536 and US Pub. No. 2013/0052130). The dyes are modified in a range of ways to control or optimize the properties of water solubility, non-specific binding (in vitro), biodistribution (in vivo), cell internalization (non-cell or cell based assays in vitro, and in vivo diagnostics and therapy), as well as aggregation. The modified dyes do not contain sulfonate groups and, thus, are asulfonate modified dyes.

Abstract: Disclosed are discrete PEGylated dyes, that is, dyes, generally ones that are fluorescent, but could also include chemi-luminescent or electrochemiluminescent and related dye or dye precursors, that have discrete PEG constructs chemically attached in various configurations on the dye, and in the entire range of constructs, discrete PEG compounds (polyethylene glycol oligomers that are made synthetically according to methods disclosed in U.S. Pat. No. 7,888,536 and US Pub. No. 2013/0052130). The dyes are modified in a range of ways to control or optimize the properties of water solubility, non-specific binding (in vitro), biodistribution (in vivo), cell internalization (non-cell or cell based assays in vitro, and in vivo diagnostics and therapy), as well as aggregation.

Abstract: Disclosed are linear discrete PEG constructs, which can be created and produced in a precise and reproducible way. Key to being able to do these things, where x in the discrete PEGx can vary from about 2 to about 64, is that the processes used to make each linear portion is controlled to give essentially one oligomer/one compound. Having a variable length linear discrete PEG construct that is (a) primarily an linear discrete PEG construct with diagnostic or therapeutic groups attached along a chain of attachment cores, which is attached to a preferential locator; (b) is an m-discrete PEG as the terminal construct on the linear portion, and “hidden”; (c or linear discrete PEG with a terminus group that can be either negatively or positively charged, or neutral; and any of the discrete PEG portions can be designed to be cleaved after entering the cell.

Abstract: A longitudinal pavement joint for joining pavement lanes, the longitudinal pavement joint comprising: one or more joining surfaces having respective slope angles between about 0 and about 45 degrees; and optionally, one or more wall surfaces having respective slope angles between about 45 and about 90 degrees, the joining surfaces and the wall surfaces being disposed adjacent one another, and one or more of the joining surfaces comprising a respective joining surface feature.