Abstract: Aligning image data of a patient with actual views of the patient using an optical code affixed to the patient. In some embodiments, a method may include affixing an optical code to a patient, affixing a pattern of markers to the patient, capturing image data of the patient, sensing the optical code affixed to the patient and a position of the optical code in a 3D space, accessing the image data, calculating the position of the pattern of markers in the 3D space, registering the position of the inner layer of the patient in the 3D space by aligning the calculated position of the pattern of markers in the 3D space with the position of the pattern of markers in the image data, and displaying in real-time, in an alternate reality (AR) headset, the inner layer of the patient from the image data projected onto actual views of the patient.

Abstract: Technology is described for storing and reading a data file using a token encoded in a printed optical code. The method can include receiving the data file over a computer network from a client device. The data file can be sent to be stored in a data store of virtualized data storage accessible via the internet. A token may be received from the data store and the token can be used to access the data file. The data file is returned from the data store when the token is later received from a client device. The token is encoded into an optical code. The optical code can be sent to the client device, where the client device has access to a printer to print the optical code with the token encoded. Any electronic copy of the token can be destroyed.

Abstract: Technology is described to adjust for eye location variations of a user when using an augmented reality (AR) headset. The method can include registering a position and size of an optical code using a visual camera and the AR headset. An alignment marker may be projected through the AR headset to be aligned with the optical code for a right eye and left eye of a user of the AR headset. Right eye and left eye adjustments to the alignment marker may be received independently to align the alignment marker with a portion of the optical code as viewed by either the right eye or left eye of the user. The left eye adjustments and right eye adjustments may be applied to virtual images displayed through the AR headset in order to improve the accuracy of alignment between objects in the physical view and the virtual images displayed using the AR headset.

Abstract: A technology is described for using a medical implement or a fluoroscopic image with reference to an image data set and a body of a person. A method may include detecting visual image data of a body of a patient and a medical implement. The optical codes on the body of the patient and on the medical implement may be identified. One operation is aligning the image data set with the body of the person using one or more optical codes on the body of the person and the fixed position of an image visible marker with respect to the optical code. A position of the medical implement with respect to the body of the person may be determined using one or more optical codes on the medical implement and the body of the person to reference the medical implement to the image data set and the body of the person.

Abstract: Augmenting real-time views of a patient with three-dimensional (3D) data. In one embodiment, a method may include identifying 3D data for a patient with the 3D data including an outer layer and multiple inner layers, determining virtual morphometric measurements of the outer layer from the 3D data, registering a real-time position of the outer layer of the patient in a 3D space, determining real-time morphometric measurements of the outer layer of the patient, automatically registering the position of the outer layer from the 3D data to align with the registered real-time position of the outer layer of the patient in the 3D space using the virtual morphometric measurements and using the real-time morphometric measurements, and displaying, in an augmented reality (AR) headset, one of the inner layers from the 3D data projected onto real-time views of the outer layer of the patient.

Abstract: Technology is described for augmenting medical imaging for use in a medical procedure. The method can include the operation of receiving an image of patient anatomy captured by a visual image camera during the medical procedure. An acquired medical image associated with the patient anatomy can then be retrieved. Another operation can be associating the acquired medical image to the patient anatomy. An augmentation tag associated with a location in one layer of the acquired medical image can be retrieved. A further operation can be projecting the acquired medical image and the augmentation tag using an augmented reality headset to form a single graphical view as an overlay to the patient anatomy in either 2D, 3D or holographic form.

Abstract: Aligning image data of a patient with actual views of the patient using an optical code affixed to the patient. In some embodiments, a method may include affixing an optical code to a patient, affixing a pattern of markers to the patient, capturing image data of the patient, sensing the optical code affixed to the patient and a position of the optical code in a 3D space, accessing the image data, calculating the position of the pattern of markers in the 3D space, registering the position of the inner layer of the patient in the 3D space by aligning the calculated position of the pattern of markers in the 3D space with the position of the pattern of markers in the image data, and displaying in real-time, in an alternate reality (AR) headset, the inner layer of the patient from the image data projected onto actual views of the patient.

Abstract: Augmenting real-time views of a patient with three-dimensional (3D) data. In one embodiment, a method may include identifying 3D data for a patient with the 3D data including an outer layer and multiple inner layers, determining virtual morphometric measurements of the outer layer from the 3D data, registering a real-time position of the outer layer of the patient in a 3D space, determining real-time morphometric measurements of the outer layer of the patient, automatically registering the position of the outer layer from the 3D data to align with the registered real-time position of the outer layer of the patient in the 3D space using the virtual morphometric measurements and using the real-time morphometric measurements, and displaying, in an augmented reality (AR) headset, one of the inner layers from the 3D data projected onto real-time views of the outer layer of the patient.

Abstract: Technology is described for incorporating statistical strength from neighboring voxels in an fMRI image. The method can include the operation of capturing an fMRI image of a human organ and the fMRI image includes statistical values for voxels in order to detect changes associated with blood flow representing organ activity. The statistics of the fMRI image can be upsampled to a larger coordinate size. Another operation can be resampling the statistical values of the fMRI image to improve the statistical strength for target voxels in the fMRI by identifying strong statistical values in neighboring voxels in a defined neighborhood of the target voxels and improving statistical values of the target voxels using the strong statistical values. The statistics of the fMRI image can integrated into a region of interest identified for the human organ to improve data values of the target voxels while retaining regional boundaries.

Abstract: Augmenting real-time views of a patient with three-dimensional (3D) data. In one embodiment, a method may include identifying 3D data for a patient with the 3D data including an outer layer and multiple inner layers, determining virtual morphometric measurements of the outer layer from the 3D data, registering a real-time position of the outer layer of the patient in a 3D space, determining real-time morphometric measurements of the outer layer of the patient, automatically registering the position of the outer layer from the 3D data to align with the registered real-time position of the outer layer of the patient in the 3D space using the virtual morphometric measurements and using the real-time morphometric measurements, and displaying, in an augmented reality (AR) headset, one of the inner layers from the 3D data projected onto real-time views of the outer layer of the patient.

Abstract: Technology is described for incorporating statistical strength from neighboring voxels in an fMRI image. The method can include the operation of capturing an fMRI image of a human organ and the fMRI image includes statistical values for voxels in order to detect changes associated with blood flow representing organ activity. The statistics of the fMRI image can be upsampled to a larger coordinate size. Another operation can be resampling the statistical values of the fMRI image to improve the statistical strength for target voxels in the fMRI by identifying strong statistical values in neighboring voxels in a defined neighborhood of the target voxels and improving statistical values of the target voxels using the strong statistical values. The statistics of the fMRI image can integrated into a region of interest identified for the human organ to improve data values of the target voxels while retaining regional boundaries.

Abstract: Technology is described for augmenting medical imaging for use in a medical procedure. The method can include the operation of receiving an image of patient anatomy captured by a visual image camera during the medical procedure. An acquired medical image associated with the patient anatomy can then be retrieved. Another operation can be associating the acquired medical image to the patient anatomy. An augmentation tag associated with a location in one layer of the acquired medical image can be retrieved. A further operation can be projecting the acquired medical image and the augmentation tag using an augmented reality headset to form a single graphical view as an overlay to the patient anatomy in either 2D, 3D or holographic form.

Abstract: Technology is described for augmenting medical imaging for use in a medical procedure. The method can include the operation of receiving an image of patient anatomy captured by a visual image camera during the medical procedure. An acquired medical image associated with the patient anatomy can then be retrieved. Another operation can be associating the acquired medical image to the patient anatomy. An augmentation tag associated with a location in one layer of the acquired medical image can be retrieved. A further operation can be projecting the acquired medical image and the augmentation tag using an augmented reality headset to form a single graphical view as an overlay to the patient anatomy in either 2D, 3D or holographic form.

Abstract: A method for monitoring productivity may include monitoring performance of a medical procedure at a local device. Medical procedure data may be received at the local device from a management device. The medical procedure data may include relative value units (RVUs) associated with the medical procedure. Medical professional productivity data related to the medical procedure may be provided for display at the local device based on the monitoring of the performance of the medical procedure and the medical procedure data. A procedure completion notification may be transmitted from the local device to the management device when the medical procedure is completed.

Abstract: Augmenting real-time views of a patient with three-dimensional (3D) data. In one embodiment, a method may include identifying 3D data for a patient with the 3D data including an outer layer and multiple inner layers, determining virtual morphometric measurements of the outer layer from the 3D data, registering a real-time position of the outer layer of the patient in a 3D space, determining real-time morphometric measurements of the outer layer of the patient, automatically registering the position of the outer layer from the 3D data to align with the registered real-time position of the outer layer of the patient in the 3D space using the virtual morphometric measurements and using the real-time morphometric measurements, and displaying, in an augmented reality (AR) headset, one of the inner layers from the 3D data projected onto real-time views of the outer layer of the patient.

Abstract: An image processing method may include capturing images of a subject using an image capture device. The images may be aligned and one image may be subtracted from another to obtain a remainder image. The remainder image may be marked and then recombined with one of the images.

Abstract: A method for monitoring productivity may include monitoring performance of a medical procedure at a local device. Medical procedure data may be received at the local device from a management device. The medical procedure data may include relative value units (RVUs) associated with the medical procedure. Medical professional productivity data related to the medical procedure may be provided for display at the local device based on the monitoring of the performance of the medical procedure and the medical procedure data. A procedure completion notification may be transmitted from the local device to the management device when the medical procedure is completed.