Abstract: Disclosed is an approach for generating interactive visualizations for multi-nodal transfers that may involve terminal nodes and multiple transitional nodes by using various protocols to acquire data from computing systems or devices associated with each node. A first visualization layer comprising a set of geographic or physical indicators in a multi-nodal transfer route (which comprises a set of three or more nodes) may be generated. API protocols (and/or non-API protocols) corresponding to each node in the transfer route may be identified. The protocols may be executed to obtain, from computing systems and devices associated with the nodes, data packets used to generate a second visualization layer, which may comprise graphics that visually depict details of a transfer along the transfer route. An overlay of visualization layers may be displayed such that the graphics are displayed in association with multiple nodes.

Abstract: The present invention provides an effective High Performance Liquid Chromatography (SE-HPLC) method to separate or resolve the pre-peak, post-peak and main peak of CTLA4-IgG1 fusion protein, where pre-peak resolution is more than 1.3. The invention further provides effective separation and resolution of post peak impurity present in CTLA4 IgG1 protein. Moreover, the present invention also provides the method for the estimation and/or quantification of pre-peak, post-peak and main peak of the protein mixture.

Abstract: Disclosed is an approach for generating interactive visualizations for multi-nodal transfers that may involve terminal nodes and multiple transitional nodes by using various protocols to acquire data from computing systems or devices associated with each node. A first visualization layer comprising a set of geographic or physical indicators in a multi-nodal transfer route (which comprises a set of three or more nodes) may be generated. API protocols (and/or non-API protocols) corresponding to each node in the transfer route may be identified. The protocols may be executed to obtain, from computing systems and devices associated with the nodes, data packets used to generate a second visualization layer, which may comprise graphics that visually depict details of a transfer along the transfer route. An overlay of visualization layers may be displayed such that the graphics are displayed in association with multiple nodes.

Abstract: Disclosed is an approach for generating interactive visualizations for multi-nodal transfers that may involve terminal nodes and multiple transitional nodes by using various protocols to acquire data from computing systems or devices associated with each node. A first visualization layer comprising a set of geographic or physical indicators in a multi-nodal transfer route (which comprises a set of three or more nodes) may be generated. API protocols (and/or non-API protocols) corresponding to each node in the transfer route may be identified. The protocols may be executed to obtain, from computing systems and devices associated with the nodes, data packets used to generate a second visualization layer, which may comprise graphics that visually depict details of a transfer along the transfer route. An overlay of visualization layers may be displayed such that the graphics are displayed in association with multiple nodes.

Abstract: Disclosed is an approach for generating interactive visualizations for multi-nodal transfers that may involve terminal nodes and multiple transitional nodes by using various protocols to acquire data from computing systems or devices associated with each node. A first visualization layer comprising a set of geographic or physical indicators in a multi-nodal transfer route (which comprises a set of three or more nodes) may be generated. API protocols (and/or non-API protocols) corresponding to each node in the transfer route may be identified. The protocols may be executed to obtain, from computing systems and devices associated with the nodes, data packets used to generate a second visualization layer, which may comprise graphics that visually depict details of a transfer along the transfer route. An overlay of visualization layers may be displayed such that the graphics are displayed in association with multiple nodes.

Abstract: The present invention provides tissue scaffolds, methods of generating such scaffolds, and methods of use of such scaffolds to generate aligned and functional neural tissues for use in methods including regenerative medicine, wound repair and transplantation.

Abstract: The present invention provides tissue scaffolds, methods of generating such scaffolds, and methods of use of such scaffolds to generate aligned and functional tissues for use in methods including regenerative medicine, wound repair and transplantation.

Abstract: The present invention provides tissue scaffolds, methods of generating such scaffolds, and methods of use of such scaffolds to generate aligned and functional tissues for use in methods including regenerative medicine, wound repair, and transplantation.

Abstract: The present invention provides tissue scaffolds, methods of generating such scaffolds, and methods of use of such scaffolds to generate aligned and functional neural tissues for use in methods including regenerative medicine, wound repair and transplantation.

Abstract: The present invention provides tissue scaffolds, methods of generating such scaffolds, and methods of use of such scaffolds to generate aligned and functional tissues for use in methods including regenerative medicine, wound repair and transplantation.

Abstract: The present invention provides tissue scaffolds, methods of generating such scaffolds, and methods of use of such scaffolds to generate aligned and functional tissues for use in methods including regenerative medicine, wound repair, and transplantation.

Abstract: This invention relates to a rodent repellant composition having 5-50% ethylene vinyl acetate by weight of low density polyethylene, 0.25-10% rodent repellent material by weight of low density polyethylene and the remainder being low density polyethylene mixed together in the form of a semi solid compound. According to the process of this invention low density polyethylene at a temperature of 110-160° C. is added to 5-50% ethylene vinyl acetate by weight of low density polyethylene is mixed therewith homogeneously. 0.25-10% rodent repellent material is added into said mixture. The mixture so obtained is subjected to the further step of mixing at the constant temperature and then shredded at room temperature in order to obtain a compound in the form of flakes. The flakes so obtained are subjected to conventional steps of film making.