Medical Image Capture System and Method

Abstract

As patient video images are captured in a lab, they are converted into an uncompressed data set and stored locally on a hospital site server, where they are immediately viewable by diagnosticians in the hospital. The hospital site server generates a plurality of compressed data sets for use by the Internet Data Center. Additionally, the uncompressed data set and a plurality of compressed data sets are stored permanently on a centralized Internet Data Center, from which they can be searched out and displayed by any client device running web-browser software. A client is provided with immediate access to the uncompressed images when pausing and requesting the images of interest from the server. The patient video images are automatically delivered to any authorized Clinical Research Organizations, they are delivered back to the treating hospital when the patient returns for subsequent visits, and are viewable through in-hospital viewing stations over a private high-speed network.

Description

RELATED APPLICATIONS [0001] This application is a Continuation of U.S. application Ser. No. 09 / 974,406, filed on Oct. 9, 2001, which claims the benefit under 35 U.S.C. 119(e) of U.S. Provisional Application No. 60 / 240,681, filed on Oct. 16, 2000, both of which are incorporated herein by reference in their entirety.BACKGROUND OF THE INVENTION [0002] 1. Field of the Invention [0003] The invention relates to systems and methods for collecting medical video images of a patient and delivering the video images to a remote station. More specifically, the invention is directed to a system and method for transferring cardiac video images with negligible image degradation, archiving the images in long-term storage media, and providing a streaming multi-media video file that allows medical diagnosis and collaboration by doctors located outside the immediate treating hospital. [0004] 2. Description of the Related Art [0005] Current advances in technologies related to compression, storage, and r...

AI Technical Summary

Benefits of technology

"The invention is a system that captures and stores video images during a cardiac catheterization procedure. The system converts the video data into a digital format and sends it to a server computer in real-time. The server computer stores the video data in a secure and high-speed network. The video data can be accessed by other practitioners in the hospital through a secure connection. The system also generates thumbnail images from the video data to make it easier to view the procedure. The thumbnail images are sent to the server computer and can be used for viewing the procedure video. The video is then sent to a data center for storage and retrieval. The system also allows users to stop and review specific frames of the video. The video is then sent to a web-based client running web-browser software. The system uses a method called streaming media to ensure that the video plays quickly and smoothly without interruption. The video is sent in sequential order, but the frames are organized so that the video loop contains frames that are out of sequence in comparison to the original capture. This is more efficient than previous systems because no frames are skipped. Overall, the invention allows for quicker and more convenient viewing of video images during cardiac catheterization procedures."

Problems solved by technology

Traditional methods of archiving patient records involve substantial costs incurred from the physical media and allocating shelf space to store the same.

Traditional paper and film storage methods require a significant amount of space, oftentimes requiring an entire filing room to store the accumulation of data.

Newer digital methods of storing patient information require a system of removable high-capacity storage devices, such as tape drives, magneto-optical disk drives and recordable compact disks, which require a significant amount of cost and time to file and retrieve.

The time required to file and retrieve physical media in a storage facility is cumbersome, as a filing clerk is required to understand the filing structure, find the correct digitally recorded media, and then deliver the media to the diagnostician requesting the record.

Archiving and retrieving of such films are expensive and cumbersome.

First of all, there is a significant cost associated with the chemicals required to develop the film.

The chemicals must be replaced frequently or there is a risk of compromising the quality of the medical image.

This results in a higher cost for facilities with low volume.

Secondly, this requires the creation and maintenance of a storage facility at optimum atmospheric conditions to preserve the film.

Thirdly, the space required to store large numbers of film canisters takes up a significant amount of space.

Finally, the process of reviewing a linear film to find a particular physiological event is time consuming.

A serious disadvantage of this method, like the cine′ film, is the tedious searching along the linear videotape to find a specific physiological event a diagnostician wishes to view.

These are expensive and are not typically available in each of the many locations in a building where a physician may wish to review the image data.

In a situation where the physician needs to consult the images before treating the patient, it is always possible he or she will be interrupted on the way back to the patient, thus affecting his or her retention of the image.

Another inherent disadvantage is the physical size of the videotape and the storage area necessary to harbor large quantities of patient information.

Still another disadvantage is the fact that any relevant patient demographic information is only available visually and does not allow electronic databasing for quick retrieval.

Thus, videotape is not an ideal solution to storage and retrieval of medical video images.

However, there are still considerable drawbacks in current digital archiving systems.

An inherent problem associated with digital storage of medical video data is the file size that can be many megabytes per procedure.

Files of these sizes can require a large amount of bandwidth, storage space, and memory.

Unfortunately, the inherent sacrifice with compression is that as compression ratios are increased, image quality is decreased.

While some of the prior art systems allow for video storage, many of these systems require the doctor to have access to, or a copy of, the removable storage media.

This is inefficient because without additional copies, only one physician can view the video data at a time, and viewing the data from a remote location requires video data media to be mailed or transmitted electronically such as through e-mail.

This is a time consuming process that requires a large amount of storage space due to the large image file sizes.

Moreover, either method of delivering video data to a remote location is critically deficient when a doctor must immediately diagnose a patient condition and does not possess the storage media or have the data saved locally on a computer.

Unfortunately, it is tedious and costly to make copies of digital video media and mail them to the various organizations requiring the patient video data.

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