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1. Technical Field of the Invention
The present invention relates generally to data entry and processing. Specifically, it provides a system and method for collaborative programming of data entry workflows between end users, system developers, and third party developers.
This method can be applied to any domain where record keeping is required. However, it will be of greatest benefit to the field of healthcare.
2. Description of Related Art
Current healthcare regulations require medical providers to collect complete and accurate patient information during encounters. Collected data is used in diagnosis, treatment, insurance claims, and pandemic reporting. Failure to document the unique needs of each patient could result in legal consequences or loss of life.
In order to comply with regulations, providers adopted Electronic Health Record (EHR) or Electronic Medical Record (EMR) systems to track patient information. The core of EHR/EMR systems comprise sequentially structured forms known as workflows, which allow providers to capture health information (e.g., heart rate, blood pressure, weight, etc. . . . ) during patient encounters. In order to meet the unique and changing needs of patients, providers must constantly create and modify workflows.
Prior art patents and other publications offer several attempts to meet these challenges. For example, in a plurality of EHR/EMR systems, software developers code new workflows and modify existing workflows. As a result, providers must plan the “business logic,” submit a new workflow or workflow change request, and follow an extensive revision and implementation cycle. This approach is inefficient and costly due to protracted back-and-forth communication between providers and software developers.
Other EHR/EMR systems attempt to reduce the need for new workflows by adding free notation features that capture unstructured patient information. The resulting data requires a technician to manually code it into structured format, thereby increasing inaccuracy due to human error.
Some prior art systems try to remedy the need for having system developers manually code workflows by allowing providers to create structured data fields. However, the large number of fields makes capturing data cumbersome. Furthermore, providers must constantly manage fields to prevent redundancy and data corruption.
Other prior systems describe methods of creating or modifying workflows to interface with third party peripheral devices, so that data field values are automatically entered into workflows. Unfortunately, current technology requires system developers to alter EHR/EMR software each time the software must accommodate a new peripheral device. One skilled in the art would recognize this process as tedious and time-consuming.
At least one system attempts to improve peripheral device integration by incorporating proprietary medical imaging machine interfaces into workflows. Differences among proprietary imaging device interfaces result in a lack of uniformity in terminology, navigation, and features. This lack of uniformity places an unnecessary burden on providers to learn the proprietary interface of each imaging device in order to use them effectively. The lack of uniformity also increases human error in patient data collection.
The above mentioned solutions, as well as others, are narrowly focused and inadequate for providing an efficient and effective means for creating and modifying workflows. Therefore, it is readily apparent that there is a need for a system and method that allows collaborative programming of data entry workflows between end users, system developers, and third party developers.
Briefly described, in a preferred embodiment, the present invention overcomes the above-mentioned disadvantages and meets the recognized need for such a device by providing a system and method for collaborative programming of data entry workflows between system developers, end users, and third party developers.
In the preferred embodiment, collaborative programming is achieved via the creation, modification, and arrangement of templates and workflows by system developers, end users, and third party developers through the EHR/EMR.
The EHR/EMR comprises at least one server, which comprises at least one application server, at least one database server, at least one template, and at least one workflow. End users can directly and independently build new templates and workflows with a networked device over a secure network connection or modify those that are already in use.
Generally speaking, system developers build and maintain the EHR/EMR. Conversely, third party developers create peripheral devices and/or external systems that interface with the EHR/EMR. In most cases, end users are medical providers including but not limited to physicians, physician assistants, and nurse practitioners.
The EMR/EHR collects all patient data gathered during a patient encounter (e.g., provider notes, imaging, lab work, vital signs) with at least one workflow comprised of at least one sequentially ordered template. Three template types are used to meet the needs of end users: form templates, system templates, and external system templates. Each template integrates unique functionality into workflows.
Form templates capture structured patient information with data fields (e.g., combo boxes, text boxes, list boxes, radio buttons, and check boxes). System developers create a plurality of default form templates to address the most common needs of end users. If needed, end users can create new form templates or modify existing form templates to meet their unique needs in a simple WYSIWYG (what you see is what you get) environment.
System templates provide more advanced functionality by capturing and processing information. System templates are built by system developers. End users input information into system templates in order to access advanced functionality built into the EHR/EMR. Processed information can be stored as structured patient information. In one embodiment, a system template searches for and schedules the next available appointment at a specified time with a specified provider.
External system templates provide complete integration with external devices and systems. Proprietary APIs (application programming interfaces) supply the framework for third party developers to seamlessly integrate external device functions into new and existing workflows. Each device function can be used independently when a specified condition is met. All types of users can specify said conditions.
Another feature of external system templates is interface uniformity. Prior art teaches systems where complex third party interfaces are displayed in windows. End users must select the proper functions of the peripheral device. The present invention allows third party developers to create situation-specific external system templates that only display the required peripheral functions.
In one embodiment, an end user is presented with an X-Ray machine external system template after diagnosing a patient with a broken arm. The external system template has default settings for scanning a broken arm and is ready to initiate a scan with the push of a button. Scan setting defaults are based on the diagnoses or can be manually altered during patient encounters.
Templates are arranged into default workflows by system developers, third party developers, and end users. Workflows are automatically chosen for end users based on the chief complaint collected during check-in. Unlike previous systems, end users can modify workflows during patient encounters by manually inserting templates or inactive workflows without leaving the active workflow.
Templates and inactive workflows can also be automatically injected into active workflows based on symptoms or diagnoses. In one embodiment, an external system template which controls an EKG machine is automatically inserted when the provider diagnoses a patient with chest pain. In another embodiment, a smoker intake workflow is automatically inserted when the provider notes a patient as a smoker. In a further embodiment, a diabetes well check workflow is inserted when the patient has been previously diagnosed with diabetes.
The present invention demonstrates significant advantages over prior art. One feature and advantage is increased EHR workflow functionality through seamless third party integration. Effectively, peripheral devices will become plug-and-play. API integration allows third party developers to provide more robust and interoperable templates and workflows with their devices. Therefore, peripheral devices will provide end users with unparalleled workflow efficiency out of the box.
Another feature and advantage is a uniform and friendly user interface. APIs and collaboratively programmed templates/workflows provide intuitive user interfaces. Further, novel use of the system's API ensures uniformity among all templates even when using third party devices thereby facilitating usability.
Still another feature and advantage is increased collaboration among system developers, end users, and third party developers. All parties collaboratively program and share EHR/EMR components. Thus, all parties can customize the EHR/EMR to meet their own needs.
Yet still another feature and advantage is automatic template injection based on symptoms or diagnoses. Providers no longer have to remember important associations between certain symptoms and actions/treatments. Thus the present invention reduces end users' malpractice liability stemming largely from the omission of mandatory treatments or procedures.
A further feature and advantage is automatic selection of pertinent workflow(s) prior to patient encounters based on chief complaints. In prior art, workflows were selected during patient encounters by the provider. Thus the present invention increases patient encounter efficiency.
The present invention will be better understood by reading the Detailed Description of the Preferred and Selected Alternate Embodiments with reference to the accompanying drawing figures, in which like reference numerals denote similar structure and refer to like elements throughout, and in which:
It is to be noted that the drawings presented are intended solely for the purpose of illustration and that they are, therefore, neither desired nor intended to limit the invention to any or all of the exact details of the construction shown, except insofar as they may be deemed essential to the claimed invention.
In describing the preferred and selected alternate embodiments of the present invention, as illustrated in
Referring now to
It will be recognized by those skilled in the art that distributed computing environment 111 may be a LAN, WAN, VPN, or any network configuration of electronic devices. It will further be recognized that application servers 515 and database servers 514 may function on separate computers (best shown in
Turning now to
Additionally, from the same specialty-specific workflow 205, the end-user 104 has the ability to interact directly with third-party services 207 and/or third-party devices 401 via third-party controls 403 via third-party developer workflows 109 comprised of external system templates 108. For example, the end-user 104 can add a third-party developer workflow for X-ray imaging 202, which utilizes third-party controls 301 that enable the X-ray device 401 to be controlled via an inserted X-ray Imaging external template 206 on the exemplary user interface 208 on the display device 200. This functionality removes other interfaces that have to be controlled separately. By using an API 302 third-party systems 401 and third-party services 402 can be seamlessly integrated, where appropriate into workflows 205 based on workflow logic 405 and patient data 404 (best shown in
Turning now more particularly to
It will be recognized by those skilled in the art that an API 302 provides superior interoperability. Because APIs are common in the art, but also understood to reveal security vulnerabilities when fully disclosed, the lack of further disclosure herein does not represent an unwillingness to disclose, but rather an acknowledgment and a sensitivity to the careful security measures in place in an exemplary embodiment, and a recognition by those skilled in the art of the general concept and methodology of an API. Inherent in this concept and methodology is the fact that API configuration can differ substantially while still achieving the same results, depending on the system in which they are integrated.
Turning now to
If the logic rule is evaluated as TRUE, the value or activated control is then imported into the supplemental workflow, template or question in the current workflow at step 603. On the other hand, if the logic rule is evaluated as FALSE, the value or activated control continues onto the next question in the current workflow or template at step 605. When the logic has fully evaluated the value or activated control, and has ended (i.e. in a return statement, return to control flow, etc.), the process restarts with the next value or activated control back at step 601.
The foregoing description and drawings comprise illustrative embodiments of the present invention. Having thus described exemplary embodiments of the present invention, it should be noted by those skilled in the art that the within embodiments are exemplary only, and that various other alternatives, adaptations, and modifications may be made within the scope of the present invention. Merely listing or numbering the steps of a method in a certain order does not constitute any limitation on the order of the steps of that method. Many modifications and other embodiments of the invention will come to mind to one skilled in the art to which this invention pertains having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Although specific terms may be employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation. Accordingly, the present invention is not limited to the specific embodiments illustrated herewith, but is limited only by the following claims.
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Number | Date | Country | |
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20140372965 A1 | Dec 2014 | US |