Abstract: Provided herein is technology relating to radiology and radiotherapy and particularly, but not exclusively, to apparatuses, methods, and systems for multi-axis medical imaging of patients in vertical and horizontal positions.

Abstract: The invention relates to a method for prognosing ACS in a subject, the method comprising determining plasma MIF and Nt-proBNP (or BNP) concentrations in a sample from the subject, diagnosing ACS when the subject plasma concentrations are greater than a reference MIF and Nt-proBNP (or BNP) plasma concentration, and prognosing the magnitude of ACS from the subject plasma MIF and Nt-proBNP (or BNP) concentrations. Also provided is a method of treating ACS in a subject, a device, a kit, and a cardiac biomarker related to the methods of prognosing ACS.

Abstract: A method for diagnosing acute coronary syndrome (ACS) in a subject, the method comprising measuring plasma macrophage migration inhibitory factor (MIF) concentration in a sample from the subject, and diagnosing ACS when the subject plasma MIF concentration is greater than a reference plasma MIF concentration, wherein the sample is taken less than 4 hours after symptom onset. The invention also relates to a method for prognosing ACS in a subject, the method comprising measuring plasma MIF concentration in a sample from the subject, diagnosing ACS when the subject plasma MIF concentration is greater than a reference plasma MIF concentration, and prognosing the magnitude of ACS from the subject plasma MIF concentration. Also provided is a method of treating ACS in a subject, a device, a kit, and a cardiac biomarker related to the methods of diagnosing and prognosing ACS.

Abstract: Non-limiting examples described herein relate to representation of intelligent object movement. Examples described herein replace pre-canned object movement actions and provide new data transformations that better emphasize context related to object movement. An action for placement of a data object may be received. Non-limiting examples of actions comprise a movement of a data object or an object insertion of one or more data objects. The action is analyzed using an object movement data model that evaluates a context for placement of the data object. Insertion characteristics are applied to the data object based on analysis by the object movement data model. A movement of the data object is surfaced, through a user interface, based on the applied insertion characteristics. An exemplary surfaced movement presents a motion animation of the data object from an initial position within the digital canvas to a resting position within the digital canvas.

Abstract: Provided is a method for prognosing ACS in a subject, the method comprising determining plasma MIF and Nt-ProBNP (or BNP) concentrations in a sample from the subject, diagnosing ACS when the subject plasma concentrations are greater than a reference MIF and Nt-proBNP (or BNP) plasma concentration, and prognosing the magnitude of ACS from the subject plasma MIF and Nt-proBNP (or BNP) concentrations. Also provided are a device, a kit and a cardiac biomarker panel related to the methods of prognosing ACS.

Abstract: The invention relates to a method for prognosing ACS in a subject, the method comprising determining plasma MIF and Nt-proBNP (or BNP) concentrations in a sample from the subject, diagnosing ACS when the subject plasma concentrations are greater than a reference MIF and Nt-proBNP (or BNP) plasma concentration, and prognosing the magnitude of ACS from the subject plasma MIF and Nt-proBNP (or BNP) concentrations. Also provided is a method of treating ACS in a subject, a device, a kit, and a cardiac biomarker related to the methods of prognosing ACS.

Abstract: Techniques for ink anchoring are described. In one or more implementations, an interactive canvas is displayed on one or more display devices of a computing device. An ink object is generated by digitizing ink input received to the interactive canvas. In response to determining that the ink object overlaps an object in the interactive canvas, the ink object is anchored to the object such that a spatial relationship between the ink object and the object is maintained if the ink object or the object is manipulated.

Abstract: Non-limiting examples described herein relate to representation of intelligent object movement. Examples described herein replace pre-canned object movement actions and provide new data transformations that better emphasize context related to object movement. An action for placement of a data object may be received. Non-limiting examples of actions comprise a movement of a data object or an object insertion of one or more data objects. The action is analyzed using an object movement data model that evaluates a context for placement of the data object. Insertion characteristics are applied to the data object based on analysis by the object movement data model. A movement of the data object is surfaced, through a user interface, based on the applied insertion characteristics. An exemplary surfaced movement presents a motion animation of the data object from an initial position within the digital canvas to a resting position within the digital canvas.

Abstract: Techniques for object selection mode are described. In one or more implementations, digital content is generated as an interactive canvas, and the interactive canvas is displayed on one or more display devices of a computing device. Additional digital content is also displayed on the interactive canvas as one or more objects. The one or more objects are anchored to the interactive canvas in an anchor mode which prevents user input to the interactive canvas from being interpreted as input to manipulate the one or more objects. A trigger event to trigger an object selection mode is detected, and an object selection mode is initiated in response to the trigger event. The object selection mode causes user input to the interactive canvas to be interpreted as input to manipulate the one or more objects.

Abstract: Techniques for object insertion are described. In one or more implementations, user input is received to an interactive canvas and the user input is detected as corresponding to a closed shape. In response to detecting that the user input corresponds to the closed shape, an object insertion menu is displayed on the interactive canvas. The object insertion menu includes selectable representations corresponding to multiple different object types which may be inserted into the interactive canvas within the closed shape. In response to receiving a user selection of a selectable representation associated with an object type from the object insertion menu, an object insertion control associated with the selected object type is displayed in the object insertion menu. The object insertion control includes additional selectable representations corresponding to objects associated with the selected object type which are selectable to insert a respective object into the interactive canvas within the closed shape.

Abstract: Techniques for contextual object manipulation are described. In one or more implementations, digital content is generated as an interactive canvas, and the interactive canvas is displayed on one or more display devices. Additional digital content is also generated as one or more objects, and the one or more objects are displayed on the interactive canvas. In response to detection of a user selection of an object displayed in the interactive canvas, a type of the selected object is determined. Next, one or more controls that are contextual to the selected object are displayed on the interactive canvas. In response to a user selection of one of the controls, the selected control is applied to the selected object.

Abstract: Techniques for page-based navigation for a dual display device are described. In one or more implementations, a journal application maintains multiple different journals. A navigation manager enables navigation through different journals in response to a first set of user gestures, and enables navigation through a sequence of interactive pages of a selected journal in response to a second set of gestures. In one or more implementations, the navigation manager enables navigation forward and backward through the sequence of interactive pages of the journal application using single-page navigation for a dual-display device.

Abstract: Techniques for ink anchoring are described. In one or more implementations, an interactive canvas is displayed on one or more display devices of a computing device. An ink object is generated by digitizing ink input received to the interactive canvas. In response to determining that the ink object overlaps an object in the interactive canvas, the ink object is anchored to the object such that a spatial relationship between the ink object and the object is maintained if the ink object or the object is manipulated.

Abstract: Techniques for ink anchoring are described. In one or more implementations, an interactive canvas is displayed on one or more display devices of a computing device. An ink object is generated by digitizing ink input received to the interactive canvas. In response to determining that the ink object overlaps an object in the interactive canvas, the ink object is anchored to the object such that a spatial relationship between the ink object and the object is maintained if the ink object or the object is manipulated.

Abstract: Techniques for smart templates are described. In one or more implementations, digital content is generated as pages of a journal application. Selectable representations associated with various smart templates are displayed via a user interface of the journal application. Responsive to user selection of one of the selectable representations, a smart page is generated by altering the digital content of an identified page and causing the identified page to inherit one or more rules or functionalities associated with the smart template. Subsequently, free-form user input is received to the smart page, and additional digital content corresponding to the free-form user input is generated on the smart page. The free-form user input is then processed by applying the one or more rules or functionalities to the free-form user input to generate page data.

Abstract: Techniques for object insertion are described. In one or more implementations, digital content is generated as an interactive canvas, and the interactive canvas is displayed on one or more display devices of a computing device. User input is received to the interactive canvas and the user input is detected as corresponding to a closed shape. In response to detecting that the user input corresponds to the closed shape, the user input is digitized and displayed as additional digital content on the interactive canvas and an object insertion mode is initiated by displaying an object insertion menu on the interactive canvas. In response to selection of an object from the object insertion menu, the selected object is inserted into the interactive canvas within the closed shape.

Abstract: A method for diagnosing acute coronary syndrome (ACS) in a subject, the method comprising measuring plasma macrophage migration inhibitory factor (MIF) concentration in a sample from the subject, and diagnosing ACS when the subject plasma MIF concentration is greater than a reference plasma MIF concentration, wherein the sample is taken less than 4 hours after symptom onset. The invention also relates to a method for prognosing ACS in a subject, the method comprising measuring plasma MIF concentration in a sample from the subject, diagnosing ACS when the subject plasma MIF concentration is greater than a reference plasma MIF concentration, and prognosing the magnitude of ACS from the subject plasma MIF concentration. Also provided is a method of treating ACS in a subject, a device, a kit, and a cardiac biomarker related to the methods of diagnosing and prognosing ACS.