Abstract: An electronic assembly may include a chassis, and electronic modules mounted within the chassis. Each electronic module may include a printed circuit substrate, heat-generating electronic components mounted on the printed circuit substrate, and a heat sink body mounted to the printed circuit substrate and having a plurality of heat pipe receiving passageways extending between opposing side edges and overlying corresponding heat-generating components. A respective elongate, passive, heat pipe may extend within each heat pipe receiving passageway and be removably fastened to at least one end to the heat sink body for enhanced conductive heat transport.

Abstract: A method for analyzing a bipartite graph data structure to condense reaction pathways of a metabolic network is described herein. A cell's metabolic network is structured as a bipartite graph, with molecule nodes representing the molecules within metabolism and edges connecting molecule nodes representing chemical reactions or processes. Molecule nodes within the bipartite graph are categorized according to the number of edges leading into and out of each node. If the structure of the bipartite graph indicates that the molecule node does not contribute to flux value solutions of a mathematical model of the metabolic network, then the node and its connected reaction pathway is blocked or removed from the bipartite graph. Thus the complexity of the bipartite graph may be reduced, and crucial nodes and pathways identified.

Abstract: A pipe fitting configured to be coupled to a pipe. The pipe fitting includes a body that is elongate along a central axis that extends in a longitudinal direction. The body includes a shell, a stiffener, and a shell-stiffener. The shell includes a shell inner surface that defines a shell through hole that extends through the shell in the longitudinal direction. The stiffener is positioned within the shell through hole, and the stiffener includes a stiffener outer surface that faces the shell inner surface such that the stiffener outer surface and the shell inner surface cooperate to define a pocket configured to receive the pipe. A shell-stiffener seal member is positioned about the stiffener such that a seal member inner surface is substantially flush against the stiffener outer surface and a seal member outer surface abuts against the shell inner surface.

Abstract: The bypass plungers are disclosed that are configured to provide a mechanical lock between a valve face of plunger and a the valve element of the plunger. More specifically, the valve face and the valve seat are correspondingly configured to allow the valve face to wedge into the interior of the valve seat such that the valve head becomes stuck within the interior of the valve seat.

Abstract: A method of processing media output events, each having a corresponding duration, from a plurality of media content receivers within a media distribution system, comprises: a. dividing the output events into a plurality of segments, such that output events having similar properties are placed into the same one of said segments; b. within each said segment, identifying a long duration threshold based on the distribution of the durations of the output events within that segment; c. and applying the long duration thresholds of each said segment for control and/or analysis of the media distribution system.

Abstract: The bypass plungers are disclosed that are configured to provide a mechanical lock between a valve face of plunger and a the valve element of the plunger. More specifically, the valve face and the valve seat are correspondingly configured to allow the valve face to wedge into the interior of the valve seat such that the valve head becomes stuck within the interior of the valve seat.

Abstract: Systems (300) and methods (1200) for inserting an electronic module in a structure. The methods comprise: sliding at least one glide mechanism on a rail of the structure or a surface of the electronic module as the electronic module is being inserted into the structure; actuating a coupler to secure the electronic module to the rail and compress a thermal interface material between the electronic module and the rail; thus causing the glide mechanism to be retracted into the electronic module or rail while the coupler is being actuated. The thermal interface material first comes in contact with the rail while the coupler is being actuated. The glide mechanism is integrated with the electronic module or the rail and is resiliently biased in a direction away from the electronic module or rail so as to partially extend out from the electronic module in a direction towards the electronic module or rail.

Abstract: An electronic assembly may include a chassis, and electronic modules mounted within the chassis. Each electronic module may include a printed circuit substrate, heat-generating electronic components mounted on the printed circuit substrate, and a heat sink body mounted to the printed circuit substrate and having a plurality of heat pipe receiving passageways extending between opposing side edges and overlying corresponding heat-generating components. A respective elongate, passive, heat pipe may extend within each heat pipe receiving passageway and be removably fastened to at least one end to the heat sink body for enhanced conductive heat transport.

Abstract: A bipartite graph structure is utilized to better store data. The bipartite graph structure may be used in a biochemical database to efficiently store a variety of molecules and processes that might occur between the molecules. Molecules are represented as molecule nodes, which may have metadata fields including a molecule name, a molecule type, a molecular formula, a sequence, a molecular charge, a set of molecular properties, and a set of component molecules. Processes operating on the molecules are represented by process nodes, which may have metadata fields including a process name, a set of process roles, a set of process properties, and a set of sub-processes. Edges, called roles, each associate a molecule node with a process node and represent the role the associated molecule plays in the associated process. The roles may contain metadata identifying the role type and the stoichiometry coefficient of the molecule in the process.

Abstract: An electronic assembly may include a chassis, and electronic modules mounted within the chassis. Each electronic module may include a printed circuit substrate, heat-generating electronic components mounted on the printed circuit substrate, and a heat sink body mounted to the printed circuit substrate and having a plurality of heat pipe receiving passageways extending between opposing side edges and overlying corresponding heat-generating components. A respective elongate, passive, heat pipe may extend within each heat pipe receiving passageway and be removably fastened to at least one end to the heat sink body for enhanced conductive heat transport.

Abstract: A bipartite graph structure is utilized to better store data. The bipartite graph structure may be used in a biochemical database to efficiently store a variety of molecules and processes that might occur between the molecules. Molecules are represented as molecule nodes, which may have metadata fields including a molecule name, a molecule type, a molecular formula, a sequence, a molecular charge, a set of molecular properties, and a set of component molecules. Processes operating on the molecules are represented by process nodes, which may have metadata fields including a process name, a set of process roles, a set of process properties, and a set of sub-processes. Edges, called roles, each associate a molecule node with a process node and represent the role the associated molecule plays in the associated process. The roles may contain metadata identifying the role type and the stoichiometry coefficient of the molecule in the process.

Abstract: A method for modulating a response signal includes introducing functionalized particles into a lumen of subsurface vasculature, wherein the functionalized particles are configured to interact with one or more target analytes present in blood circulating in the subsurface vasculature; and non-invasively detecting the one or more target analytes. A response signal, which may include a background signal and an analyte response signal related to interaction of the functionalized particles with the one or more target analytes, is transmitted from the subsurface vasculature. A modulation configured to alter the response signal such that the analyte response signal is affected differently than the background signal may be applied to a portion of subsurface vasculature. Analyte detection may be achieved by differentiating the analyte response signal from the background signal.

Abstract: Food products and systems and methods for their production involve microfiltration (“MF”) of fluid skim to form a MF retentate, combining the MF retentate with cream and subjecting the combination to ultrafiltration (“UF”) to form a UF retentate. Prior to UF, the composition is formed of non-acidified components. Following UF, the UF retentate is acidified and forms a food product including a high solids content. The solids content may be further increased using evaporation. The resulting cheese or cheese base contains a lower whey protein ratio in a fat:casein:whey protein ratio compared to systems and methods that do not employ MF.

Abstract: A method for modulating a response signal includes introducing functionalized particles into a lumen of subsurface vasculature, wherein the functionalized particles are configured to interact with one or more target analytes present in blood circulating in the subsurface vasculature; and non-invasively detecting the one or more target analytes. A response signal, which may include a background signal and an analyte response signal related to interaction of the functionalized particles with the one or more target analytes, is transmitted from the subsurface vasculature. A modulation configured to alter the response signal such that the analyte response signal is affected differently than the background signal may be applied to a portion of subsurface vasculature. Analyte detection may be achieved by differentiating the analyte response signal from the background signal.

Abstract: Food products and systems and methods for their production involve microfiltration (“MF”) of fluid skim to form a MF retentate, combining the MF retentate with cream and subjecting the combination to ultrafiltration (“UF”) to form a UF retentate. Prior to UF, the composition is formed of non-acidified components. Following UF, the UF retentate is acidified and forms a food product including a high solids content. The solids content may be further increased using evaporation. The resulting cheese or cheese base contains a lower whey protein ratio in a fat:casein:whey protein ratio compared to systems and methods that do not employ MF.

Abstract: Systems (300) and methods (1200) for inserting an electronic module in a structure. The methods comprise: sliding at least one glide mechanism on a rail of the structure or a surface of the electronic module as the electronic module is being inserted into the structure; actuating a coupler to secure the electronic module to the rail and compress a thermal interface material between the electronic module and the rail; thus causing the glide mechanism to be retracted into the electronic module or rail while the coupler is being actuated. The thermal interface material first comes in contact with the rail while the coupler is being actuated. The glide mechanism is integrated with the electronic module or the rail and is resiliently biased in a direction away from the electronic module or rail so as to partially extend out from the electronic module in a direction towards the electronic module or rail.

Abstract: The behavior and/or internal activities of a microorganism can be simulated using a model of the microorganism. Such simulations can be used to determine the efficacy of treatments, disinfectants, antibiotics, chemotherapies, or other methods of interacting with the microorganism, or to provide some other information about the microorganism. Systems and methods are provided herein for fitting, refining, or otherwise improving such models in an automated fashion. Such systems and methods include performing whole-cell experiments to determine a correspondence between the predictions of such models and the actual behavior of samples of the microorganism. Such systems and methods also include, based on such determined correspondences, directly assessing determined discrete sets of properties of the microorganism and/or of constituents of the microorganism and updating parameters of the model corresponding to the properties of the discrete set such that the overall accuracy of the model is improved.

Abstract: A method for analyzing a bipartite graph data structure to condense reaction pathways of a metabolic network is described herein. A cell's metabolic network is structured as a bipartite graph, with molecule nodes representing the molecules within metabolism and edges connecting molecule nodes representing chemical reactions or processes. Molecule nodes within the bipartite graph are categorized according to the number of edges leading into and out of each node. If the structure of the bipartite graph indicates that the molecule node does not contribute to flux value solutions of a mathematical model of the metabolic network, then the node and its connected reaction pathway is blocked or removed from the bipartite graph. Thus the complexity of the bipartite graph may be reduced, and crucial nodes and pathways identified.

Abstract: A grilling tool is described herein that has a replaceable tip, and can be used with a variety of other attachments. The grilling tool can be made of a heat-conformable material such that during use grooves are formed in the replaceable tip that correspond to a grilling surface on which it is used. Once the grooves are too deep or the tip is fully used, the tip can be replaced.

Abstract: A method for simulating a biochemical environment utilizes a heterogeneous process model, which evaluates both a flux balance analysis and one or more detailed models each on a different but overlapping sets of molecules in the biochemical environment. The heterogeneous process model evaluates the flux balance analysis based on a stoichiometric matrix, a flux vector including initial internal exchange flux values, and an objective function. The heterogeneous process model evaluates the one or more detailed models based on an initial set of molecule concentrations and a plurality of detailed model parameters. The results are then used to update the exchange fluxes and molecules concentrations. The process is repeated thereby integrating the results of the flux balance analysis with the one or more detailed models.