Abstract: The present invention relates to a system and method for performing a protocol-driven ultrasound examination for generating an image of moving cardiac structure and blood of a heart. One embodiment comprises a front-end and at least one processor. The front end is arranged to transmit ultrasound waves into the moving cardiac structure and blood, generating received signals in response to the ultrasound waves backscattered from the moving cardiac structure and blood. The at least one processor, responsive to the received signals, acquires at least one image of the structure in at least one of a predetermined order and a predefined protocol, and selects at least one of the acquired images taken along at least one of a given view and study.

Abstract: A physiology system is provided that includes an ultrasound beamformer that is configured to receive signals from an ultrasound probe that is located proximate the region of interest. The system includes an ultrasound processor module for generating an ultrasound image, based on the ultrasound data, that is representative of an anatomical structure of a portion of the region of interest contained in the scan plane. A physiology signal processor module is also provided and configured to receive physiology signals from a catheter located proximate the region of interest. The physiology signal processor module produces physiology data representative of the physiology activity of the portion of the region of interest contained in the scan plane. A display processor module forms a display image combining the ultrasound image and physiology data.

Abstract: A method for managing outputs to peripheral devices in medical systems devices is described. The method includes providing an instruction to provide an output, creating a data object based on the instruction, and storing the data object in a first memory if a peripheral device that provides the output is not available to accept the data object, where the first memory stores the data object for a longer term than a second memory.

Abstract: A physiology workstation is provided that comprises a communications interface conveying physiology signals derived from a subject and ultrasound data representative of a region of interest of the subject. The ultrasound data is obtained by an ultrasound device in real-time during a procedure carried out on the subject. An physiology processing unit receives and processes the physiology signals. An ultrasound processing unit receives and processes the ultrasound data to generate ultrasound images. The physiology processing unit combines the physiology signals with the ultrasound images from the ultrasound processing unit. A display unit displaying the physiology signals and the ultrasound images. The physiology signals and ultrasound signals are presented jointly to a user in real-time during the procedure being carried out on the subject.

Abstract: The present invention relates to a system and method for performing a protocol-driven ultrasound examination for generating an image of moving cardiac structure and blood of a heart. One embodiment comprises a front-end and at least one processor. The front end is arranged to transmit ultrasound waves into the moving cardiac structure and blood, generating received signals in response to the ultrasound waves backscattered from the moving cardiac structure and blood. The at least one processor, responsive to the received signals, acquires at least one image of the structure in at least one of a predetermined order and a predefined protocol, and selects at least one of the acquired images taken along at least one of a given view and study.

Abstract: A physiology system is provided that includes an ultrasound beamformer that is configured to receive signals from an ultrasound probe that is located proximate the region of interest. The beamformer, based on the receive signals, produces ultrasound data representative of a scan plane including the region of interest. The system also includes an ultrasound processor module for generating an ultrasound image, based on the ultrasound data, that is representative of an anatomical structure of a portion of the region of interest contained in the scan plane. A physiology signal processor module is also provided and configured to receive physiology signals from a catheter located proximate the region of interest. The physiology signal processor module produces physiology data representative of the physiologic activity of the portion of the region of interest contained in the scan plane. A registration module registers the ultrasound image and physiology data within a common coordinate reference system.

Abstract: A physiology network is provided that is configured to operate with a medical network. The physiology network includes a physiology workstation that receives, processes and display's physiology signals obtained from a subject during a physiology procedure carried out on the subject. The physiology workstation has a network interface configured to be joined to the medical network. A database is provided that stores patient records associated with the subject undergoing the physiology procedure. The server is joined to the network and the database for managing and controlling access to the database. The server provides, to the physiology workstation, a patient record associated with the subject. The physiology workstation co-displays the physiology signals and information from the patient record to an operator of the physiology workstation.

Abstract: A physiology workstation is provided that comprises a communications interface conveying physiology signals derived from a subject and ultrasound data representative of a region of interest of the subject. The ultrasound data is obtained by an ultrasound device in real-time during a procedure carried out on the subject. An physiology processing unit receives and processes the physiology signals. An ultrasound processing unit receives and processes the ultrasound data to generate ultrasound images. The physiology processing unit combines the physiology signals with the ultrasound images from the ultrasound processing unit. A display unit displaying the physiology signals and the ultrasound images. The physiology signals and ultrasound signals are presented jointly to a user in real-time during the procedure being carried out on the subject.

Abstract: A physiology workstation is provided that comprises an physiology input configured to receive physiology signals from at least one of an intracardiac (IC) catheter inserted in a subject and surface ECG leads provided on the subject. The physiology signals are obtained during a procedure. A video input is configured to receive image frames, in real-time during the procedure. The image frames contain diagnostic information representative of data samples obtained from the subject during the procedure. A control module controls physiology operations based on user inputs. A display module is controlled by the physiology control module. The display module displays the physiology signals and the image frames simultaneously, in real-time, during the procedure. Optionally, the workstation may include a video processor module that formats the physiology signals into a display format.

Abstract: An apparatus and method for synchronizing the hemodynamic measurements from a patient monitoring system and the ultrasound images from an ultrasound monitoring system. The synchronized images and measurements can be combined and displayed on a single display that includes both the ultrasound images and the hemodynamic patient measurements. The combined display receives synchronized information from both the ultrasound monitoring system and the hemodynamic patient monitoring system and displays the combined information on a single monitor. In addition to displaying the synchronized combined information, the system stores the synchronized information for later playback. The playback of the stored images and measurements is synchronized such that the clinician can be presented with the combined information in a usable manner.

Abstract: The present invention relates to a system and method for performing a protocol-driven ultrasound examination for generating an image of moving cardiac structure and blood of a heart. One embodiment comprises a front-end and at least one processor. The front end is arranged to transmit ultrasound waves into the moving cardiac structure and blood, generating received signals in response to the ultrasound waves backscattered from the moving cardiac structure and blood. The at least one processor, responsive to the received signals, acquires at least one image of the structure in at least one of a predetermined order and a predefined protocol, and selects at least one of the acquired images taken along at least one of a given view and study.

Abstract: A method for managing outputs to peripheral devices in medical systems devices is described. The method includes providing an instruction to provide an output, creating a data object based on the instruction, and storing the data object in a first memory if a peripheral device that provides the output is not available to accept the data object, where the first memory stores the data object for a longer term than a second memory.