Abstract: A structural insulation panel (SIP) is made of a central insulation material or block core covered with cementitious material. The layers of cementitious material are reinforced with fiber mesh sheets, rebar and corner blocks. The corner blocks are held in thickened cementitious material edges by reinforcement pins that are fixed to the corner blocks. The corner blocks are accessible for lifting the panel and for assembling multiple panels to build a wall.

Abstract: An example method includes detecting, using sensors, packets throughout a datacenter. The sensors can then send packet logs to various collectors which can then identify and summarize data flows in the datacenter. The collectors can then send flow logs to an analytics module which can identify the status of the datacenter and detect an attack.

Abstract: A method and apparatus for use in a flow through assay process is disclosed. The method is characterised by a “pre-incubation step” in which the sample which is to be analysed, (typically for the presence of a particular protein), and a detection analyte (typically an antibody bound to colloidal gold or a fluorescent tag) which is known to bind to the particular protein may bind together for a desired period of time. This pre incubation step occurs before the mixture of sample and detection analyte come into contact with a capture analyte bound to a membrane. The provision of the pre-incubation step has the effect of both improving the sensitivity of the assay and reducing the volume of sample required for an assay. An apparatus for carrying out the method is disclosed defining a pre-incubation chamber for receiving the sample and detection analyte having a base defined by a membrane and a second membrane to which a capture analyte is bound.

Abstract: The present invention provides a method for isolating and/or identifying an immunogenic protein from a protein complex comprising an immunoglobulin or a mixture thereof or an immunoglobulin-containing fraction.

Abstract: A method and apparatus for use in a flow through assay process is disclosed. The method is characterised by a “pre-incubation step” in which the sample which is to be analysed (typically for the presence of a particular protein), and a detection analyte (typically one or more antibodies bound to colloidal gold or a fluorescent tag) which is known to bind to the particular protein may bind together for a desired period of time. This pre-incubation step occurs before the mixture of sample and detection analyte come into contact with a capture analyte bound to a membrane. The provision of the pre-incubation step has the effect of both improving the sensitivity of the assay and reducing the volume of sample required for an assay. An apparatus for carrying out the method is disclosed defining a pre-incubation chamber for receiving the sample and detection analyte having a base defined by a membrane and a second membrane to which a capture analyte is bound.

Abstract: A method and apparatus for use in a flow through assay process is disclosed. The method is characterised by a “pre-incubation step” in which the sample which is to be analysed, (typically for the presence of a particular protein), and a detection analyte (typically an antibody bound to colloidal gold or a fluorescent tag) which is known to bind to the particular protein may bind together for a desired period of time. This pre incubation step occurs before the mixture of sample and detection analyte come into contact with a capture analyte bound to a membrane. The provision of the pre-incubation step has the effect of both improving the sensitivity of the assay and reducing the volume of sample required for an assay. An apparatus for carrying out the method is disclosed defining a pre-incubation chamber for receiving the sample and detection analyte having a base defined by a membrane and a second membrane to which a capture analyte is bound.

Abstract: Separation of macromolecules by one-dimensional or two-dimensional methods, such as gel electrophoresis, produces an array of macromolecules, which can be transferred to a support, thereby producing the same array as on the gel. In the case of one-dimensional gel electrophoresis, because of the regular spacing of the gel lanes and the predictable direction of migration of the macromolecules, the positions of the macromolecule spots or bands in the array can be predicted to be at least within the area of the support corresponding to the lanes of the gel. Where the molecular weight of a macromolecule of interest is known, molecular weight markers can be used to determine where the macromolecule band is on the support, even if the macromolecule is not stained in the gel or on the support.

Abstract: An array (100) of macromolecules (the primary array), typically proteins is generated by 2D electrophoresis, for example, and subsequently transferred to a support membrane (102) by electroblotting or the like. An image of the primary array is captured (202) and the coordinates of the various macromolecular spots in the primary array are determined (402). The next step of the process is to print a secondary (or micro) array of one or more reagents or chemicals onto one or more spots/coordinates of the primary array with a pico-litre (pl) dispenser (702). If the macromolecules are proteins, the reagents may be enzymes such as Trypsin or GluC. Use of two different enzymes deposited onto different coordinates on the same spot will cleave the protein at different amino acid sites and, when the spot is analysed in a MALDI-TOP mass spectrometer, will provide increased coverage or matching of peptides in the protein.