SYSTEMS AND METHODS FOR MANIPULATING MEDICAL DATA VIA A DECISION SUPPORT SYSTEM
BACKGROUND OF THE INVENTION 1. The Field of the Invention
This invention relates to a decision-support system where information is analyzed to provide an individual with one or more suggested recommendations. More specifically, the present invention relates to a decision-supporting system that provides recommendations to a clinician in a standardized and reproducible form. 2. The Prior State of the Art
The U.S. health care delivery system has undergone breathtaking changes since the late 1980's. Today's medical marketplace is characterized by escalating costs, diminishing resources, demands for accountability, inescapable conflicts regarding meaningful outcomes measures, and an expanding medical knowledge base. Health care, in general, is an information intensive industry where clinicians and health care providers analyze and digest an ever-increasing knowledge base of health care practices and procedures. Clinicians and health care providers use these practices and procedures to give appropriate medical care for each patient that seeks medical care.
Increasingly clinicians and health care researchers experience demands for more accurate and accessible information. The complexity of health care, its burgeoning information base, and the turbulence of the medical marketplace contribute to a medical system that grapples to efficiently synthesize and disseminate information, standardize care, and to continue to create and innovate. The obstacles to these goals are the same regardless of whether the health care delivery provider is a small hospital, long- term/skilled nursing facility, medical clinic, home health agency, hospice, emergent care unit, or large institution. All providers are faced with the need to identify solutions to manage information and make better decisions, whether those decisions are medical or business-related in nature.
Clinical decisions are of particular interest since they often influence the balance of human suffering and well-being. Clinical decisions are typically based upon the evidence-base of medicine, patient-physician factors and interactions, and external and internal constraints. Whether clinicians are serving individual patients or populations, they have always sought to base their decisions on the best available evidence or
knowledge. The rapid expansion of the scientific and clinical evidence has changed the health care landscape so that no longer is the question how much of medical practice is based in evidence, but rather how much of the available evidence is applied at the front lines of patient care.
Clinicians and health care providers are acutely aware of the issues associated with practicing the available evidence at the front lines. Many attempts have been made to provide information to a clinician in a meaningful manner that supports the clinician's decision-making process. One current trend is to utilize artificial intelligence (Al) technologies to meet information management and decision-supporting needs. Al technologies or expert systems attempt to simulate the decision-support process that is easily accomplished by the human brain. The expert system typically includes a knowledge base that stores data representative of the currently available knowledge within a particular field of endeavor. An inference engine and associated "rules" or statements that control how the expert system reacts to a particular situations work with the knowledge base to generate solutions to problems posed to the expert system, such as the dose of a drug that a patient is to receive.
Various types of expert system have been developed in the medical field. For example, one type of expert system aids a physician with treating physical trauma. The expert system gathers patient data, such as the patient's height, weight, age, and sex, while collecting information related to the physical trauma. As the data is collected, the expert system generates a working file that is specific to the patient and the particular injury. This working file with a knowledge base of physical trauma and orthopedic fractures is used by the expert system to assist the clinician in treating the patient's physical trauma. Unfortunately, each working file is specific to the particular patient and the specific injury. Hence, each time the expert system is used, a new working file is generated, including the need to ask for patient data, patient history, and the like.
Another type of expert system guides a clinician with the administration and selection of therapeutic drugs and associated treatment regimens for a known disease. The expert system utilizes information gathered from a patient physical examination with a knowledge base to generate suggested treatment regimens for a known disease or medical condition. Although this type of expert system allows a clinician and a patient to generate treatment regimens together for a known disease, the expert system is limited to
only those known diseases identified by the clinician. Additionally, initial generation of patient data is time consuming and cumbersome.
Therefore, there is a need for an expert system that allows for an evaluation of a patient over an extended period without the need to re-input patient data each time a clinician examines the same patient. Additionally, there is a need for a system that effectively gathers patient data without the clinician spending a long period examining the patient and evaluates the data to identify known or unknown medical conditions.
SUMMARY OF THE INVENTION
As disclosed previously, clinicians are influenced by a number of complex and varied constraints as a clinician gives medical care to multiple patients each having varied medical conditions. Constraints on the time that a clinician may spend consulting with each patient limit the clinician's effectiveness in diagnosing and treating each patient. Furthermore, although clinicians educate themselves with the advances in medical care, during the rigors of performing medical care for a large number of patients such knowledge may not raise to the clinician's memory. This may result in a misdiagnosis, mistreatment, or at worst the death of the patient. In accordance with the invention as embodied and broadly described herein, systems and methods for providing clinicians with patient specific data and at least one medical diagnosis and at least one medical care recommendation that are based upon a large expert knowledge base are disclosed.
One of the modules implemented by one embodiment of the present invention is a decision-support module. The decision-support module is configured to generate decision-supported patient data that may be accessed by a user module via a network. The decision-supported patient data may optionally be contained within one or more files, records, fields or data storages termed a decision-supported progress note specific to each patient.
The decision-supported patient data represents patient specific information and data that have been evaluated by a knowledge base of expert medical knowledge, resulting in a diagnosis of a patient's medical condition and a medical care recommendation. Each decision-supported progress note, therefore, includes data representative of at least one medical condition and at least one medical care recommendation for a patient. Additionally, the decision-supported progress note provides a qualitative and quantitative analysis of the patient assessment process
performed by the decision-support module and the clinician and the recommended plan of medical care suggested by the decision-support module over a short or long time period.
Another one of the modules implemented by one embodiment of the present invention is a user module. The user module communicates with the decision-support module by way of a web browser to act as an interface between the decision-support module and the clinician. In this manner, the clinician is presented with decision- supported patient data (such as in the form of the decision-supported progress note) through the web browser that gives the clinician an efficient and effective representation of the current medical condition of the patient.
The user module, either solely or in combination with the decision-support module, may generate a summarized version of the decision-supported patient data to assist the clinician in treating each patient that the clinician is to examine. The summarized version presents the clinician with the pertinent medical information associated with the patient's previous, existing, and any anticipated medical conditions.
According to another aspect of the present invention, in a decision-support system having data stored in a knowledge base, a method for delivering decision-supported patient data to a clinician to aid the clinician with the diagnosis and treatment of a medical condition is disclosed. The method optionally includes gathering patient data from a patient in response to a decision-supported questionnaire. The questionnaire includes a number of questions and decision-supported questions aimed at the patient. Alternatively, patient data may be gathered from one or more data storage modules or other databases.
Upon gathering the patient data, the method provides for the patient data to be evaluated with expert data stored in a knowledge base to generate decision-supported patient data. The evaluating step may include collecting medical condition information based upon the patient data. Once the medical condition is identified, the clinical classification of the medical condition is collected. Subsequently, data representative of one or more causes of the medical condition is collected. This data may be used to identify the microbial susceptibilities to the medical condition if the one or more causes of the medical condition are organism specific. Alternatively, mitigating factors based on the one or more causes of the medical condition are collected. Consequently, the medical condition identified is evaluated to generate the decision-supported patient data
that includes at least one medical condition and at least one medical care recommendation.
Following generation of the medical f condition and the medical care recommendation, the decision-supported patient data is transmitted to a user module in the form of a decision-supported progress note. The user modules present the clinician with the decision-supported patient data specific to the patient in a format that assists the clinician in treating each patient.
In this manner, the present invention is capable of receiving patient data, optionally directly from the patient and generating decision-supported patient data that assists a clinician in making decisions related to the medical care of a patient.
Similarly, by generating data on a patient's relatives, the present invention is capable of generating decision-supported data that assists a clinician in making decisions related to the medical care of a patient and furthermore in making decisions related to the medical care of one or more of the patient's relatives.
BRIEF DESCRIPTION OF THE DRAWINGS
In order that the manner in which the above-recited and other advantages and features of the invention are obtained, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments thereof that are illustrated in the appended drawings. Understanding that these drawing depict only typical embodiments of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
Figure 1 illustrates an exemplary system that provides a suitable operating environment for the present invention;
Figure 2 is a schematic representation of one embodiment of the system of the present invention;
Figure 3 is a more detailed a schematic representation of the system of Figure 2;
Figure 4 is a flow diagram representing data flow through the system of Figures 2 and 3 in an outpatient setting;
Figure 5 is a flow diagram representing data flow through the system of Figures 2 and 3 in an outpatient setting where an unknown medical condition is identified;
Figure 6A-6E illustrate Table 1 that contains statements that may be presented to the clinician and the underlying rules used by an inference module to generate the statements for the medical condition of Pneumonia;
Figure 7 illustrates Table 2 that contains mitigating factor rules used by an inference module for the medical condition of Pneumonia;
Figure 8 illustrates Table 3 that contains susceptibility rules used by an inference module for the medical condition of Pneumonia
Figure 9 illustrates Table 4 that contains duration rules used by an inference module for the medical condition of Pneumonia
Figure 10 illustrates Table 5 that contains caveat rules used by an inference module for the medical condition of Pneumonia
Figure 11 is a flow diagram representing data flow through the system of Figures 2 and 3 in an inpatient setting.
Figure 12A-B is a schematic block diagram illustrating the various etiologic classifications for a Urinary Tract Infection that may be presented to the clinician in accordance with the teaching of the present invention;
Figure 13A-F illustrates Table 6 that contains statements that maybe presented to the clinician and the underlying rules used by an inference module to generate the statements for the medical condition of a Urinary Tract Infection;
Figure 14 illustrates Table 7 that contains statements that the present invention may present to the clinician and the underlying rules used by an inference module to generate the statements for a Candida medical condition and other miscellaneous organism associated with a Urinary Tract Infection;
Figure 15 illustrates Table 8 that contains duration rules and statements associated with the medical condition of a Urinary Tract Infection;
Figure 16 illustrates Table 9 that contains caveat rules and statements associated with the medical condition of a Urinary Tract Infection;
Figure 17 illustrates Table 10 that contains mitigating factor rules and statements associated with the medical condition of a Urinary Tract Infection;
Figure 18 illustrates Table 11 that contains sequential mitigating factor rules and statements associated with the medical condition of a Urinary Tract Infection;
Figure 19 illustrates Table 12 that contains illustrative medication contraindications for the medical condition of a Urinary Tract Infection;
Figure 20A-B is a schematic representation of the decision-support process for a medical condition of meningitis;
Figure 21A-C illustrates Table 13 that contains statements that the present invention may presented to the climcian and the underlying rules used by an inference module to generate the statements for the medical condition of Meningitis;
Figure 22 illustrates Table 14 that contains duration rules associated with the medical condition of Meningitis;
Figure 23 illustrates Table 15 that contains mitigating factor rules associated with the medical condition of Meningitis; and
Figure 24 illustrates Table 16 that contains caveat rules associated with the medical condition of Meningitis.
DETAILED DESCRIPTION OF THE INVENTION
The present invention extends to both methods and systems for delivering decision-supported patient data to a climcian to aid the clinician with the diagnosis and treatment of a medical condition. The embodiments of the present invention may comprise a special purpose or general purpose computer including various other computer hardware and/or software modules and components, as discussed in greater detail below.
Embodiments within the scope of the present invention also include computer- readable media for carrying or having computer-executable instructions or data structures stored thereon. Such computer-readable media can be any available media that can be accessed by a general purpose or special purpose computer. By way of example, and not limitation, such computer-readable media can comprise RAM, ROM, EEPROM, CD- ROM or other optical disk storage, magnetic disk storage or other magnetic storage devices, or any other medium which can be used to carry or store desired program code means in the form of computer-executable instructions or data structures and which can be accessed by a general purpose or special purpose computer. When information is transferred or provided over a network or another communications connection (either hardwired, wireless, or a combination of hardwired or wireless) to a computer, the computer properly views the connection as a computer-readable medium. Thus, any such a connection is properly termed a computer-readable medium. Combinations of the
above should also be included within the scope of computer-readable media. Computer- executable instructions comprise, for example, instructions and data which cause a general purpose computer, special purpose computer, or special purpose processing device to perform a certain function or group of functions.
Figure 1 and the following discussion are intended to provide a brief, general description of a suitable computing environment in which the invention may be implemented. Although not required, the invention will be described in the general context of computer-executable instructions, such as program modules, being executed by computers in network environments. Generally, program modules include routines, programs, objects, components, data structures, etc. that perform particular tasks or implement particular abstract data types. Computer-executable instructions, associated data structures, and program modules represent examples of the program code means for executing steps of the methods disclosed herein. The particular sequence of such executable instructions or associated data structures represents examples of corresponding acts for implementing the functions described in such steps.
Those skilled in the art will appreciate that the invention may be practiced in network computing environments with many types of computer system configurations, including personal computers, hand-held devices, multi-processor systems, microprocessor-based or programmable consumer electronics, network PCs, minicomputers, mainframe computers, and the like. The invention may also be practiced in distributed computing environments where tasks are performed by local and remote processing devices that are linked (either by hardwired links, wireless links, or by a combination of hardwired or wireless links) through a communications network. In a distributed computing environment, program modules may be located in both local and remote memory storage devices.
With reference to Figure 1, an exemplary system for implementing the invention includes a general purpose computing device in the form of a conventional computer 20, including a processing unit 21, a system memory 22, and a system bus 23 that couples various system components including the system memory 22 to the processing unit 21. The system bus 23 may be any of several types of bus structures including a memory bus or memory controller, a peripheral bus, and a local bus using any of a variety of bus architectures. The system memory includes read only memory (ROM) 24 and random
access memory (RAM) 25. A basic input/output system (BIOS) 26, containing the basic routines that help transfer information between elements within the computer 20, such as during start-up, may be stored in ROM 24.
The computer 20 may also include a magnetic hard disk drive 27 for reading from and writing to a magnetic hard disk 39, a magnetic disk drive 28 for reading from or writing to a removable magnetic disk 29, and an optical disk drive 30 for reading from or writing to removable optical disk 31 such as a CD-ROM or other optical media. The magnetic hard disk drive 27, magnetic disk drive 28, and optical disk drive 30 are connected to the system bus 23 by a hard disk drive interface 32, a magnetic disk drive- interface 33, and an optical drive interface 34, respectively. The drives and their associated computer-readable media provide nonvolatile storage of computer-executable instructions, data structures, program modules and other data for the computer 20. Although the exemplary environment described herein employs a magnetic hard disk 39, a removable magnetic disk 29 and a removable optical disk 31, other types of computer readable media for storing data can be used, including magnetic cassettes, flash memory cards, digital video disks, Bernoulli cartridges, RAMs, ROMs, and the like.
Program code means comprising one or more program modules may be stored on the hard disk 39, magnetic disk 29, optical disk 31, ROM 24 or RAM 25, including an operating system 35, one or more application programs 36, other program modules 37, and program data 38. A user may enter commands and information into the computer 20 through keyboard 40, pointing device 42, or other input devices (not shown), such as a microphone, joy stick, game pad, satellite dish, scanner, or the like. These and other input devices are often connected to the processing unit 21 through a serial port interface
46 coupled to system bus 23. Alternatively, the input devices may be connected by other interfaces, such as a parallel port, a game port or a universal serial bus (USB). A monitor
47 or another display device is also connected to system bus 23 via an interface, such as video adapter 48. In addition to the monitor, personal computers typically include other peripheral output devices (not shown), such as speakers and printers.
The computer 20 may operate in a networked environment using logical connections to one or more remote computers, such as remote computers 49a and 49b. Remote computers 49a and 49b may each be another personal computer, a server, a router, a network PC, a peer device or other common network node, and typically
includes many or all of the elements described above relative to the computer 20, although only memory storage devices 50a and 50b and their associated application programs 36a and 36b have been illustrated in Figure 1. The logical connections depicted in Figure 1 include a local area network (LAN) 51 and a wide area network (WAN) 52 that are presented here by way of example and not limitation. Such networking environments are commonplace in office-wide or enterprise-wide computer networks, intranets and the Internet.
When used in a LAN networking environment, the computer 20 is connected to the local network 51 through a network interface or adapter 53. When used in a WAN networking environment, the computer 20 may include a modem 54, a wireless link, or other means for establishing communications over the wide area network 52, such as the Internet. The modem 54, which may be internal or external, is connected to the system bus 23 via the serial port interface 46. In a networked environment, program modules depicted relative to the computer 20, or portions thereof, may be stored in the remote memory storage device. It will be appreciated that the network connections shown are exemplary and other means of establishing communications over wide area network 52 may be used.
Figure 2 is a block diagram illustrating a decision support system implementing one embodiment of the present invention. As shown, system 200 includes a decision- support module 210 that communicates with one or more user modules 214a-214n via network 212. Alternatively, system 200 may include multiple decision-support modules that communicate with a single user module. Through the configuration illustrated in Figure 2, a patient or clinician may input information regarding the patient's health, medical conditions, billing information, and past and current medical care, termed "patient data". Subsequently, system 200 may evaluate this patient data to create data that assists the clinician in making a medical diagnosis, a medical care recommendation or decision, medical treatment, a referral to another clinician or medical provider, or the like. Such data is termed "decision-supported patient data."
Optionally, the decision-supported patient data may be configured in the form of a decision-supported progress note. The decision-supported progress note is a module, data file, record, field, one or more data storages that contain information and data that represents a qualitative and quantitative analysis of the patient assessment process
performed by the decision-support module 210 and the clinician and the recommended plan of medical care suggested by decision-support module 210. Such qualitative and quantitative analysis may extend over a long period, such as with an outpatient situation, or over a shorter period, such as with an inpatient situation. hi this manner, system 200 may gather and analyze stored patient data with input patient data to generate decision-supported patient data, optionally, in real-time or perceived real time. Although discussion is made to the use of the present invention in a decision-support system, it may be appreciated that the novel features of the present invention are not limited to use with a decision-support system, but may be used in various other systems.
As illustrated in Figure 2, system 200 includes decision-support module 210. Decision-support system 210, in one embodiment, allows a patient to store and access patient data, while allowing a clinician to store, update, and access the patient data and decision-supported patient data that contain information regarding the diagnosis and treatment of various medical conditions. Additionally, the clinician may access a knowledge base that includes data representative of the current expert medical knowledge within a variety of medial areas and assists the clinician with the diagnosis and medical care of the patient. The patient data, the decision-supported patient data, and the knowledge base need not be incorporated within decision-support module 210, but may be located remotely from decision-support module 210 and accessible by decision- support module 210. For example, optional medical module 216, as illustrated by dotted lines, may include one or more servers that store the patient data, the decision-supported patient data, and the knowledge base.
Facilitating communication between decision-support module 210, user modules 214a-214n, and optionally medical module 216 is network 212. In one embodiment, network 212 is the Internet so that various user modules 214a-214n using web browsers may access the patient data, decision-supported patient data, and decision-supported progress notes stored within decision-support module 210. Network 212 may also be a local area network (LAN) such as a hospital or clinic intranet, wide area network (WAN), wireless network, packetized network, real-time network, and various other networks known by one skilled in the art, so long as the network configuration and architecture allow a user module to access decision-support module 210.
Decision-support module 210 may communicate with user modules 214a-214n via various types of communication line connections, such as but not limited to, cable or cable modems, satellite, telephone lines, whether analog or digitally based, the Internet, DSL, G-Lite, wireless technology, infra-red (IR) technology, other high-speed data connections, or any other suitable transmission technology or medium. One skilled in the art may identify various other types of network and/or communication line connections that are capable of performing the desired function of allowing decision- support module 210 to commtmicate with user modules 214a-214n and optionally medical module 216.
Each user module 214a-214n communicates with decision-support module 210 to allow the clinician or patient to gather patient data and receive decision-supported patient data or the decision-supported progress note in real-time or perceived real-time. As discussed herein, the operation of either transmitting data and/or receiving data, in various forms and types, shall be termed collectively as "transceiving" and the operation of tranceiveing data between decision-support module 210, user module 214a-214n, and medical module 216 without a substantial delay between an input and a response is considered real-time or perceived real-time communication.
Those skilled in the art will appreciate that each user module 214a-214n may take various configurations. For example, each user module 214a-214n may be the same or different personal computer, hand-held device, multi-processor system, microprocessor- based or programmable consumer electronic device, telephone, network PC, minicomputer, mainframe computer, and the like. Generally, each user module 214a- 214n may include the structure and functionality of computer 20 with associated application programs 36 and memory 22 to store the application programs 36, patient data, decision-supported patient data, and optional decision-supported progress note.
Medical module 216 represents the various hardware and software modules and components of a medical facility, such as a hospital, clinic, and the like. Each medical facility may store business data, medical data, patient data, decision-supported patient data, decision-supported progress notes, and the like. Medical module 216, in one embodiment, includes various modules associated with the medical facility's intranet or internal network that links various departments of a hospital or clinic. For example, the departments may include radiology, the pharmacy, administration, the laboratories, and
the like. Additionally, medical module 216 may include the hardware and software modules and components for medical module 216 to communicate with decision-support module 210 and user modules 214a-214n by a communication line connection known to one skilled in the art in light of the teaching contained herein.
According to another aspect of the present invention, system 200 optionally includes a third party module 218. Third party module 218 represents the various other modules that may communicate with decision-support module 210, user modules 214a- 214n, and medical module 216. For example, third party module 218 may represent a medical provider, an insurance carrier, a referred clinician, a referring clinician, a third party paging service, and the like. In this manner, a clinician may communicate with outside sources to obtain approval for services and/or give information to the outside sources. For example, system 200 may allow decision-support module 210 to communicate with an insurance carrier, heath care management organization (HMO), or other similar health care provider to receive authority to give a recommended medical treatment. One skilled in the art may identify various other third parties that may obtain benefits from the present invention.
Generally, the configuration of system 200 facilitates the gathering of patient data and delivery of decision-supported patient data to a clinician and patient. Optionally, system 200 may present the clinician or patient with a summarized version of the available medical and non-medical information via user module 214a-214n. Such medical and non-medical information provides the clinician and the patient with recommendations regarding the patient's care and may include warnings or alerts with respect to recommended treatments or potential medical conditions of the patient. For example, the alerts may identify potential side effects associated with the use of the medication.
By summarizing the decision-support patient data, the clinician is not bombarded with a large quantity of information through which he or she must search. Rather, the clinician may view the current decision-supported patient data, i.e., recent laboratory test results, vital statistics, current drug usage, and the like. In this fashion, the clinician is given a simplified representation of the patient's medical condition based upon the current medical knowledge and the current patient data. Thus, medical costs are reduced and a higher quality of medical care is provided to each patient.
Furthermore, the configuration of system 200 facilitates the delivery of patient data to the clinician in a standardized and reproducible manner. The clinician may request real-time patient data from decision-support module 210, medical module 216, or third- party module 218 on demand and receive the patient data in a standardized format. Such patient data may be delivered to the clinician via user module 214a-214n and displayed to the clinician through a browser or other user interface. Additionally, the configuration of system 200 facilities the delivery of important or critical information and patient data to the clinician, whether in a synchronized basis or upon the occurrence of an alerted event, such as when a patient has heart attack or an adverse reaction to prescribed medication.
Generally, each of the modules, 210, 214a-214n, 216, and 218 may be incorporated within various types of computer 20 and remote computers 49a, 49b as depicted in Figure 1. Each module 210, 214a-214n, 216, and 218, therefore, may include system memory 22 and storage devices 50a and 50b, while optionally including hard disk drive 27, magnetic disk drive 28, optical disk drive 30, and associated interfaces 32, 33, and 34. Additionally, each module 210, 214a-214n, 216, and 218 may communicate one with another via a variety of different manners and communication line connections. Hence, the functionality of each module 210, 214a-214n, 216, and 218 may be incorporated within one or more of the other modules. For example, the functionality of decision-support module 210 and/or of user modules 214a-214n may be incorporated within medical module 216.
With reference to the more detailed schematic representation of one embodiment of the present invention depicted in Figure 3, only a single decision-support module 210 and a single user module 214 are depicted. The following discussion will relate to the interaction between one decision-support module 210 and one user module 214. One skilled in the art may appreciate, however, that a similar discussion may be recited for the interaction of multiple decision-support modules and multiple user modules.
According to one embodiment of the present invention decision-support module 210 includes a patient storage module 220. Patient storage module 220 stores the patient data that may be used by the clinician and decision-support module 210 to establish the type of medical care received by the patient. As illustrated, patient storage module 220 includes one or more databases 222a-222n that maintain the patient data. Each database 222a-222n may have various architectures, such as but not limited to, relational, network,
flat, and hierarchical databases, with associated database management systems (not shown) that control the flow of data to and from databases 222a-222n. Although multiple databases are represented, one skilled in the art may appreciate that system 200 may include only a single database.
The patient data maintained in databases 222a-222n may include, but is not limited to, the patient's billing information (e.g., name, address, telephone number, birth data, social security number, and insurance information) and patient's demographic information (e.g., age, sex, height, and weight). Additionally, databases 222a-222n include the patient's past and current: (i) medical conditions; (ii) medical care; (iii) tracked cure and failure information; (iv) medications prescribed and associated adverse effects of drug interactions; (v) laboratory tests and results; (vi) clinical consequences of treatment; (vii) family histories; (viii) genetic susceptibilities and pharmacological and non-pharmacological information; (ix) decision-supported patient data and progress notes; (x) and the like. Such data may be stored in a variety of different fields, files, and records that are associated one with another to allow an appropriate database management system (not shown) to access the stored data in an efficient manner when requested by interface module 230. hi accordance with another aspect of the present invention, decision-support module 210 includes a knowledge module 226. Knowledge module 226, and associated databases 228a-228n, act as the repository of medical information, data, and associated rules and parameter descriptions i.e., "knowledge", which decision-support module 210 uses to identify an unknown medical condition of a patient or provide recommendations for treatment of the medical condition when the condition is known or unknown. The rules represent logic sectors or elements that act upon information gathered by system 200 to generate the decision-supported patient data and the decision-supported progress note. The rules are either sequential or non-sequentially followed to generate the medical care recommendations. Following hereinafter are a list of illustrative rules that system 200 may use to generate the decision-supported patient data and decision-supported progress note based upon stored and newly gathered patient data and/or patient data associated with the patient's relatives.
The medical information and data stored within knowledge module 226 are based on information from experts within the relevant fields of medicine, such as such as
Geriatric Medicine, Genetic Medicine and Gene Therapy, Cardiovascular diseases, Respiratory diseases, and the like. Knowledge module 226, therefore, may include information related to, but not limited to, Critical Care Medicine, Renal diseases, Genitourinary diseases, Gastrointestinal diseases, Diseases of the liver, gallbladder, and bile ducts, Hematologic diseases, Oncology, Metabolic diseases, Nutritional diseases, Endocrine diseases, Women's Health, Diseases of bone and bone mineral metabolism, Diseases of the immune system, Musculoskeletal and connective tissue diseases, Infectious diseases, HIV and Acquired immunodeficiency syndrome, Diseases of protozoa and metazoa, Neurological Diseases, Eye, Ear, Nose, and Throat diseases, Skin diseases, Pediatric Medicine, and the like.
The rules and parameter descriptions stored in knowledge module 226 may include one or more software modules, files, and records that define how decision-support module 210 uses the expert information to analyze the patient's current medical information. In this manner, the clinician is guided with the identification and treatment of a patient's medical condition. Such rules and parameters are dynamic in that as system 200 gathers more "knowledge" the rules and parameters changes to accommodate the increased knowledge. This is in contrast to many existing expert systems that utilize hard coded rules and parameters that are difficult to vary based upon an increasing knowledge base. Illustrative rules and parameters related to Pneumonia, Meningitis, and Urinary tract Infection will be discussed hereinafter.
As with databases 222a-222n, each database 228a-228n may have various architectures, such as but not limited to, relational, network, flat, and hierarchical databases, with associated database management systems (not shown) that control the flow of data to and from databases 228a-228n. It may be appreciated that is preferable that databases 222a-222n and 228a-228n have the same architecture, however, each database 222a-222n and 228a-228n may have differing architectures.
Although Figure 3 illustrates each database 222a-222n and 228a-228n as being incorporated within decision-support module 210, one skilled in the art may appreciate that such databases 222a-222n and 228a-228n and/or patient storage module 220 and knowledge module 226 may be remotely located from decision-support module 210. Alternatively, in one configuration, patient storage module 220 and/or databases 222a- 222n may be incorporated within a hospital or clinic's administrative system and/or
network (medical module 216) that allow decision-support module 210 to access the information stored therein. In another configuration, patient storage module 220 and/or databases 222a-222n are located remotely from decision-support module 210 and a hospital or clinic's administrative system and/or network (medical module 216).
Communicating with patient storage module 220 and/or knowledge module 226 is an interface module 230. Interface module 230 facilitates the decision-support process by providing access to databases 222a-222n and 228a-228n. Interface module 230, therefore, allows decision-support module 210 to obtain patient data from medical module 216. Such communication between interface module 230 and medical module 216 may be via a variety of communication protocols and communication line connections. In one illustrative embodiment, interface module 230 allows communication via the Health Level 7 protocol, via Extensible Markup Language (XML), or by some other communication protocol known by one skilled in the art in light of the teaching contained herein. As may be understood by one skilled in the art, interface module 230 may be generated by a variety of different software tool and products, such as but not limited to Enterprise Java Beans (EJB), Common Object Request Broker Architecture (COBRA), and Common Object Model (COM) compliant services, and the like.
Communicating with interface module 230 is inference module 232. Inference module 232 controls the manner by which decision-support module 210 generates solutions to the known or unknown medical conditions of the patient. Stated another way, inference module 232 generates the decision-supported patient data based upon the newly gathered patient data, stored patient data within patient module 220, and the knowledge base contained within knowledge module 226. For example, inference module 232 may use the genetic susceptibilities of the patient to identify the various medical conditions that the patient may be susceptible to in the future and prescribe medical care recommendations to reduce the likelihood of such medical conditions occurring.
Inference module 232, in one embodiment, includes one or more inference engines 233 and an application module 235 to drive the one or more inference engines 233. The one or more inference engines 233 apply the rules and parameters stored in knowledge module 226 to generate the medical diagnosis and the medical care
recommendation for the patient. Application module 235, in one embodiment, includes the software modules to cause inference engine 233 to generate such medical diagnosis and medical care recommendations. The functionality and operation of these elements are commonly known by one skilled in the art and need not be discussed further herein. A variety of other modules and components may be included within inference module 232 as known by one skilled in the art in light of the teaching contained herein.
As illustrated, inference module 232 is depicted as being incorporated within decision-support module 210. One skilled in the art may appreciate that inference module 232 may optionally be integrated with medical module 216 by connecting decision- support module 210 directly to medical module 216 by an Internet Inter-Object Request Broker Protocol (HOP) or remotely by a Remote Method Invocation (RMI). Alternatively, inference module 232 may be incorporated partially or completely within medical module 216 and hence decision-support module 210 is devoid of inference module 232. Additionally, inference module 232 may be incorporated within an application server hosted by decision-support module 210 or may be incorporated within an application server hosted by medical module 216.
Decision-support module 210, in one embodiment, includes an optional progress note module 236. Progress note module 236 communicates with inference module 232 to receive the decision-supported patient data and subsequently generate a decision- supported progress note. The decision-supported progress note presents the clinician with the decision-supported patient data in a standardized and reproducible configuration so that system 200 minimizes the potential for misdiagnosis of a medical condition or recommended medical treatment based upon the illegibility of a clinician's notes. Furthermore, the decision-supported progress note provides a clinician with a standardized format for collecting additional patient data and a list of recommended follow-up questions, tests, and other medical care to perform during a physical exam or visit with the patient. Optionally, the clinician may modify the particular configuration of the progress note so that the clinician may more effectively give medical care to a patient. Consequently, progress note module 236 may allow a clinician to define how the decision-supported patient data is to be displayed in the decision-supported progress note.
In one setting, a clinician may request that progress note module 236 summarize the decision-supported patient data generated by inference module 232. The summarized
decision-supported patient data contains the pertinent information related to the medical condition of the patient in an easily viewed display. For example, if the patient has diabetes, progress note module 236 will generate a decision-supported progress note that summarizes the pertinent medical parameters associated with the patient's diabetes, such as the most recently acquired heart rate, blood pressure, blood sugar level, and the like, while providing warnings or alerts to the climcian. Similarly, when a therapeutic regimen is suggested, progress note module 236 summarizes decision-supported patient data includes drug name and type, dose, route, interval and duration of therapy specific to the patient and the drug, patient demographics, and the like, while providing warnings or alerts to the clinician.
In this manner, progress note module 236 may provide the clinician with the pertinent patient specific decision-supported patient data in a summarized arrangement requested by the clinician. By summarizing the pertinent data, a clinician more capably treats a patient in an efficient manner.
In another configuration, progress note module 236 generates a decision- supported progress note that includes a calendar representing when a patient is to take medication that is prescribed by the clinician. Optionally, the calendar includes a visual representation of the medication prescribed. For example, if the clinician prescribes lOOOmg of ganciclovir then the calendar may include a visual representation of two (2) 500mg pills containing ganciclovir. this manner, the calendar both reminds the patient when to take their medication, while also giving a visual representation of the number of the pills prescribed.
To allow inference module 232 and/or progress note module 236 to transceive information to and from user module 214, decision-support module 210 optionally includes a web module 238. Web module 238, in one embodiment may be a web server that facilitates data transceiving between decision-support module 210 and user module 214. Web module 238, either alone or in combination with inference module 232 and/or progress note module 236 may control how and when the decision-supported patient data is presented to the clinician and/or patient. For example, in one embodiment, web module 238 provides the decision-supported patient data by way of a web page that is accessible by clinicians and/or patients via user module 214. Therefore, web module 238 defines the layout or format of the web page. Optionally, the climcian and/or the patient
may vary the particular configuration of the web page upon which they will view the decision-supported patient data.
One skilled in the art may identify various other configurations of web module 238 that are applicable. For example, in one configuration, web module 238 automatically delivers patient data to the clinician as the clinician accesses web module 238, such as broadcasting updated patient data, h still another configuration, such as with an inpatient setting, web module 238 continually or periodically updates the decision-supported patient data or decision-supported progress noted and subsequently transmits (or broadcasts) warning or alerts to the clinician based upon the updated patient data. For instance, upon completing laboratory tests a laboratory clinician may broadcast the updated laboratory results to decision-support module 210 by way of laboratory module 262. Subsequently, web module 238 updates decision-support patient data and decision-supported progress notes and delivers a notification or warning to the clinician's user module, such as a pager, telephone, PDA, a clinician's assistant that may forward the notification or warning, some third party service provider or the like. In another configuration, web module 238 delivers patient data, decision-supported patient data, and or decision supported progress note to third party module 218. For example, if decision-support module 210 identifies that as a medical care recommendation the patient may be referred to a specialist, upon authorization by the clinician, web module 238 delivers a decision-supported progress note to the clinician with a referral request to an identified clinician or to an insurance carrier or other medical provider. Subsequently, upon authorization from the climcian, web module 238 may send the referral request directly to an identified clinician or to an insurance carrier or other medical provider. In another configuration, web module 238 allows a patient or clinician to request additional information via electronic mail (e-mail) or by some other manner from a group of specialists. For example, a clinician may identify that a patient has contracted tuberculosis and request guidance from a medical care specialty group (such as third party 218) on what actions to take in light of the medical condition. In response, the specialty group or a clinician part thereof may response the to clinician's request via e-mail or some other manner, such as telephone, video-conference, and the like.
Web module 238 may transceive information and data via Hypertext Transfer Protocol (HTTP), File Transfer Protocol (FTP), Wireless Application Protocol (WAP), or
various other communication protocols and communication line connections. One skilled in the art may identify various other communication protocols and connections that are applicable for allowing web module 238 to transceive data between user module 214 and medical module 216. For example, web module 238 may use TCP/IP communication protocol, a connection orientated or connectionless network protocol, via asynchronous transfer mode (ATM) technology, X.25 protocol, Frame Relay protocol, packet switching protocols, circuit switching protocols, dynamic packet switching protocols, 802.11RF protocol, and the like to transceive data through network 212. Therefore, web module 238 and hence decision-support module 210 may use a variety of different interface types, such as but not limited to a wireless interface thereby utilizing _R, F, satellite, blue tooth transmission and associated protocols, a modem, cable modem, ADSL connection, ISDN, Ethernet, or similar other connections, and the like.
One skilled in the art may appreciate that inclusion of web module 238 within decision-support module 210 is optional. In the event that decision-support module 210 is partially or completely incorporated within medical module 216, decision-support module 210 is devoid of web module 238 and may utilize an appropriate web module incorporated within medical module 216 to allow communication with user module 214 via network 212.
Optionally included within decision-support module 210 is a billing module 240. Billing module 240 is configured to communicate with web module 238 and generate the appropriate billing codes and proper documentations required to allow accurate billing of medical care to insurance carriers, government agencies, Medicare, and the like. Once a clinician has completed a patient examination, web module 238 receives the clinician's authorization for the medical care proscribed. Subsequently, billing module 240 tracks the medical care authorized by the climcian for each patient and creates the billing codes and documentation for each procedure, drug prescribed, test requested, and the like. Although billing module 240 is depicted as being incorporated within decision-support module 210, one skilled in the art may recognize that billing module 240 may be take the form of a stand-alone module. Alternatively, billing module 240 may be incorporated within medical module 216. Optionally, billing module 240 may communicate with medical module 216 and generate the billing codes and documentation through the medical facilities accounting, administration, or other facilities.
Referring again to Figure 3, communicating with decision-support module 212 is user module 214. User module 214 allows a clinician and/or patient to gather patient data and subsequently receive real-time or perceived real-time decision-supported patient data or decision-supported progress notes. User module 214, as mentioned above, may take the form of computer 20 and/or remote computer 49a and 49b that allows a clinician and/or patient to gather and view medical information and associated medical diagnoses and treatments. Illustratively, user module 214 may be a personal digital assistant (PDA) or other hand-held hardware device, including, but not limited to, a Palm Pilot, or CE based palm computer, with associated software applications and operating systems, a general purpose computer, a special purpose computer, a pager, a wireless telephone, pocket PC, and the like. Additionally, such user modules 214 may synchronize or communicate with decision-support module 212 to transceive patient data, decision- supported patient data, and decision-supported progress notes on a continuous, substantially continuous, periodic, and/or sporadic manner. Such synchronization or communication may be achieved through wireless, direct dial, desktop or some other synchronization and by one of a variety of communication line connections as discussed herein and known to one skilled in the art.
User module 214, in one embodiment, includes a communication interface 242, a control module 244, and a user interface 246. Communication interface 242 of user module 214 is adapted to transceive data between decision-support module 210, medical module 216, and user module 214. Depending on the type of communication line connection between modules 210, 214, and 216, communication interface 242 may have a variety of configurations and perform a number of functions. For example, communication interface 242 may be a wireless interface thereby utilizing _R, RF, satellite, blue tooth transmission and associated protocols, a modem, cable modem, ADSL connection, ISDN, Ethernet, or similar other connections and other communication line connections known to one skilled in the art in light of the teaching contained herein. Additionally, communication interface 242 may compress, decompress, encrypt, decrypt, and perform such other functions as known by one skilled in the art.
As implied above, communication interface 242 communicates with control module 244. Control module 244 performs a number of operations and functions to allow a clinician and/or patient to gather patient data through user interface 246. Additionally,
control module 244 manages the flow of decision-supported patient data and decision- supported progress notes to user interface 246. Control module 244, therefore, optionally manages the flow of patient data: (i) to and from the clinician and patient; (ii) from data storage module 248 to user interface 246; (iii) between user module 214 and decision- support module 210; and (iv) from medical module 216 to user module 214.
In addition to controlling the flow of patient data between the various modules and components of system 200, control module 244 may control the configuration of user interface 246. Stated another way, control module 244, in one embodiment, may receive display instructions from the climcian regarding how the decision-supported patient data and decision-supported progress note received from decision-support module 210 is to be displayed or arranged. Control module 244 may deliver such instructions to web module 238 or progress note module 236 for such modules to prepare the decision-supported patient data in accordance with the clinician's instructions. Alternatively, control module 244 may either receive the decision-supported patient data (or the decision-supported progress note) and convert the data into a form consistent with the clinician's instructions or function with inference module 232, progress note module 236, and web module 238 to generate the desired display.
In the later case, control module 244 may: (i) receive through communication interface 242 the decision-supported patient data or the decision-supported progress note; (ii) store the decision-supported patient data or the decision-supported progress note in data storage module 248, decision-support module 210, medical module 216, and/or third-party module 218; (iii) summarize the decision-supported patient data (or decision- supported progress note) in accordance with the clinician's instructions to display the pertinent information to the clinician; and (iv) display the summarized decision-supported patient data (or decision-supported progress note) to the clinician through user interface 246.
Optionally, control module 244 may vary the display configuration requested based upon the particular hardware device and software modules that will present the decision-supported patient data or decision-supported progress note. For example, the limitations on allowable display configurations is greater for a PDA or "thin" client than for a general purpose computer; hence control module 244 may limit or eliminate the
allowable choices or merely display the decision-supported patient data in a form applicable for the particular hardware device no matter the clinician's instructions.
In addition to controlling the manner by which the decision-supported patient data is to be displayed to the clinician, control module 244 may allow the clinician and/or patient to access detailed patient data or decision-supported patient data stored in decision-support module 210 or medical module 216. Alternatively, control module 244 may display the decision-supported patient data, without summarizing the information associated with the decision-supported patient data.
Control module 244 may include various hardware and/or software modules to perform the above-referenced functions, such as but not limited to one or more microcontrollers, central processing units, state machines, programmable logic arrays, network logical arrays, or gates, ASIC processors, software-based controllers, combination logic, combinations thereof, and a variety of other controllers known by one skilled in the art. Control module 244 may communicate with communication interface 242, user interface 246, and data storage module 248 by a variety of connections, such as but not limited to electrical communication, an analog or digital, wireless, optical, or various other types of connection by way of one of a variety of communication line connections known by one skilled in the art.
As referenced above, a clinician or patient may update the patient data, the decision-supported patient data, and the decision-supported progress note through user interface 246. Similarly, the clinician or patient may receive a graphical representation of all or a summarized version of the available the patient data, the decision-supported patient data, and the decision-supported progress note through the same user interface 246. Optionally, a clinician may control the amount of patient data, whether decision- supported or not that the patient may view hrough user interface 246.
User interface 246, either alone or in combination with control module 244 and decision-support module 210, may allow a clinician or patient to define the display format of the decision-supported patient data and other patient data transmitted to user module 214 from decision-support module 210 and/or medical module 216. A clinician may, in one embodiment, select from a number of stored display configurations, use the default display configuration, or generate a clinician specific display configuration. No matter the particular display configuration selected by the clinician, the particular display
configuration assists a clinician in diagnosing, treating, and providing medical care to the patient. hi one embodiment, user interface 246 is a web browser. One skilled in the art may identify various other interfaces that are capable of performing the desired function of allowing a clinician and/or patient to gather and subsequently view medical information. For example, user interface 246 may be a graphical user interface (GUI), textual, interactive, drop-down menu, voice activated, and the like interface. User interface 246 may allow a user to select choices through pushing buttons, selecting icons, scanning bar codes, vocalization of procedure codes or medical treatments, or through some other method, system, hardware device, and/or software application known to one skilled in the art. The above described interfaces may be developed from a variety of software packages such as HTML, dynamic HTML (DHTML) (including JavaScript, Cascading Style Sheets, Common Gateway Interface (CGI) scripts, cookies, Java, ActiveX, Server-Side Includes (SSI)), and the like.
According to another aspect of the present invention, system 200 includes medical module 216. As depicted in Figure 3, medical module 216 optionally includes a web module 252 that communicates with network 212. Web module 252, such as a web server, delivers the information stored in medical module 216 over network 212 to those hardware and/or software modules that access web module 252 and have appropriate access rights. Upon receiving a request from a hardware and/or software module, such as user module 214 or decision-support module 210, web module 252 provides the requested documents or information in an appropriate language, such as Hyper Text Markup Language (HTML), XML, or some other language. Web module 252 may provide the requested information via Secured Socket Layers (SSL) protocol, a Virtual Private Network (VPN), asymmetric or symmetric encryption, or some other security protocol or process known to one skilled in the art. One skilled in the art may also recognize that although a single server is depicted as part of medical module 216, medical module 216 may include a plurality of web modules 252.
Communicating with web module 252 is an application module 254, such as an application server. Application module 254 provides the conduit between the information stored in medical module 216 and any requests for such information through web module 252. Application module 254 acts as an intermediary between the information or data
storage of medical module 216 and the hardware and/or software modules that request access to the desired information. In the illustrated configuration of Figure 3, such information from the ancillary module 256 may pass through application module 254 upon a request through web module 252 to access the medical information stored in the ancillary module 256. Alternatively, such information may be directly delivered to decision-support module 210 over a secure connection.
According to another aspect of the present invention, medical module 216 includes ancillary module 256. Ancillary module 256 includes one or more other modules that represent the various hardware and/or software modules of the individual departments within the medical facility, such as the hospital or clinic, and their associated connection to medical module 216 and network 212. As illustrated, ancillary module 256 may include a pharmacy module 260, laboratory module 262, admit/discharge/transfer module 264, radiology 266, and the like. One skilled in the art may identify various other modules that may be included within ancillary module 256. For example, ancillary module 256 may include computer physician order entry systems, other order entry systems, and the like.
Generally, pharmacy module 260 maintains information and data representative of drugs requested and proscribed for each of a plurality of patients, whether a patient is an inpatient or an outpatient. Similarly, laboratory module 262 maintains information and data representative of the laboratory tests ordered and performed for each of a plurality of patients. Admit/discharge/transfer module 264, in this configuration, maintains information and data representative of the billing information and scheduling information associated with each of a plurality of patients, while radiology module 266 maintains information and data representative of the Computed Tomographic (CT) scans, fetal ultrasounds, magnetic resonance imaging (MRI), mammographs, and X-rays, ordered and performed for each of a plurality of patients.
Generally, system 200 suggests the various embodiments or configurations by which the present invention may be implemented for various network configurations. For example, when network 212 is the Internet, system 200 illustrates the communication of clinicians and patients with a decision-support module 210 having the configuration of a web site. In this manner, decision-support module 210 acts as an application service provider where the modules and components of decision-support module 210 are
centrally located and connected to via a secure Internet connection. To access decision- support module 210 a clinician and/or patient pays a regular subscription fee and uses a traditional web browser, such as Microsoft® Internet Explorer, Netscape, and the like. This particular configuration reduces the installation costs for those medical facilities that wish to utilize the beneficial properties of the present invention. However, this configuration requires the clinician and/or patient to input the patient information to be stored in patient module 220.
Alternatively, when network 212 is a LAN, system 200 illustrates the communication of clinicians and patients with decision-support module 210 that is integrated with medical module 216, as illustrated by the dotted lines in Figure 2. Such integration may be achieved by connecting inference module 232 of decision-support module 210 directly to application module 254 of medical module 216 by an Internet Inter-Object Request Broker Protocol (HOP) or remotely by a Remote Method Invocation (RMI). In this configuration, clinicians and patients obtain the decision-supported patient data (or the decision-supported progress note) via a secure intranet using one of a variety of web browsers known to one skilled in the art. In this manner, decision-support module 210 may be integrated with medical module 216 and may receive patient data stored in patient module 220 and/or ancillary module 256. The medical module 216 and the individual modules included within ancillary module 256 may be considered as an electronic medical record (EMR) system that is typically used within the medical field.
In still another configuration, again when network 212 is a LAN, system 200 illustrates the communication of clinicians and patients with decision-support module 210 that is integrated with application server 254 of medical module 216. In this configuration, ancillary module 254 acts as patient module 220 and requests decision- supported patient data (or decision-supported progress notes) from inference module 232 and progress note module 236 directly. This is achieved by interfacing application server 254 with knowledge module 226, whether or not knowledge module 226 resides on application server 254. In this configuration, a clinician receives decision-supported patient data transparently without the clinician switching to a different application or having to learn new software products.
Figures 4 and 5 are flow diagrams representing the operational process of providing medical care by a climcian in an "outpatient" setting, such as at a clinic. The
discussions will be generalized with respect to the configuration of system 200 with respect to the interaction of decision-support module 210, user module 214, and medical module 216 through network 212, i.e., whether network 212 is a LAN, WAN, the Internet, and the like. It may be appreciated, that the method steps described herein are only illustrative of one method of performing the desired function.
Referring now to Figure 4, a description of the methodology of the present invention shall be provided as it relates to obtaining decision-supported data by a clinician in an outpatient setting, where the patient has known medical conditions, such as diabetes. The methodology description refers to Figures 2 and 3, thereby illustrating the method of processing data through the various illustrative modules and components of the present invention.
Initially, in an "outpatient" setting, such as in a clinic, a patient arrives at the clinic and is admitted, or otherwise identifies themselves as having an appointment to meet with the clinician, as represented by block 300. Upon paying any fees and completing any admission paper work, the patient may access a user module 214 by providing the patient's name, birth date, social security number, or the like. By giving the identification information, the patient gains access to system 200, as represented by block 302. For example, in one embodiment a patient provides the identification information through a cathode ray tube (CRT) monitor with a touch sensitive user interface 246.
Upon accessing system 200, decision-support module 210 accesses patient specific information contained within patient module 220, as represented by block 304. Based upon the patient's identification information, decision-supported patient data from decision-support module 210 is used to generate standardized questions to be asked of the patient, as represented by block 306. Alternatively, control module 244 may receive the standardized questions from data storage module 248 of user module 214. hi either case, the standardized questions may be modified by any of the patient's pre-existing medical conditions. For example, in this illustrative example, the patient has diabetes and the questions asked by system 200 may be modified by one or more rules to thereby review the current medical condition of the patient with respect to their diabetes.
As the patient is asked questions, as represented by block 308, and provides answers, as represented by block 310, control module 244 tracks the answers and transmits the same to decision-support module 210. Upon receiving the answers,
inference module 232 and/or knowledge module 226 (with associated rules) evaluate the responses, as represented by block 312, to determine whether additional information is need to generate a recommendation. Until a recommendation is reached, system 200 will continue to ask questions, receive answers and evaluate answers, as represented by decision block 314.
Once a recommendation is reached, if a recommendation is required, system 200 generates a decision-supported progress note that may be used by the clinician during a physical examination of the patient, as represented by block 316. For example, the decision-supported progress note can provide the clinician with a ranked list of recommendations with side-effects or problems associated with each recommendation.
In the event that the question and answer session results in decision-support module 210 identifying educational materials that may aid the patient with their medical condition, user module 214 may prompt the patient as to the desirability of obtaining such educational materials, as represented by decision block 318. If the patient wishes the educational materials, user module 214 may retrieve such information from data storage 248 or alternatively from decision-support module 210 and/or medical module 216 and print or otherwise deliver the materials to the patient, as represented by block 320. Optionally, system 200 may always provide the patient with the educational material, without the patient having the option to select whether they receive the educational materials.
Following receipt of the educational materials, whether receipt occurs before or after the decision-supported progress not is created, the patient receives a brief physical exam, such as height, weight, blood pressure, and the like by a clinician's assistant, or optionally the clinician, as represented by block 322. The newly obtained physical exam data is input into system 200 through user interface 246 and the patient data is updated, as represented by block 324.
Upon receiving the updated patient data, inference module 232 reevaluates the recommendation previously developed in light of the updated patient data, as represented by block 326. This new recommendation, as with the previous recommendation may be based upon not only the medical information contained in knowledge module 226 but may be based upon the patient's insurance provider, the cost of the drug or other
treatment, effectiveness of the treatment, and such other factors as known by one skilled in the art.
Subsequently, decision-support module 210 applies the same or different rules to generate a new decision-supported progress note, as represented by block 328, which is delivered to the clinician so that the clinician may complete the clinician's examination of the patient, as represented by block 330.
To complete the "outpatient" process, the clinician may review the questions or other information that decision-support module 210 has identified as a medical area requiring a more detailed analysis of the patient's medical condition. For example, although a patient may be visiting the clinician for a scheduled check-up, the patient's responses to the posed questions may suggest another medical conditions, such as an unknown disease, or other medical condition.
Referring now to Figure 5, an illustrative process for identifying and recommending a treatment for an unknown disease is depicted. Continuing with the above-described illustrative example, a patient with a known disease, such as diabetes, is determined to have an unknown disease. Initially, the clinician may review the patient's medical history contained within decision-support module 210 or optionally collect new patient history or demographic information, as represented by block 340
Following receipt of the demographic information, the climcian may collect disease information, as represented by block 342. This may be obtained through laboratory tests or from the question and answers provided to the clinician by system 200. Furthermore, the question and answers used to initially collect current medical information may be used to collect medical condition information regarding the patient's relatives. Therefore, system 200 may analyze the patient's predisposition for particular medical conditions in light of the newly gathered or stored patient data.
Let us assume that the unknown medical condition is a disease. Once the disease is identified, a clinical classification is identified based upon the disease, as represented by block 344. For example, let us assume that the disease is identified as pneumonia; the clinical classification may include deciding whether the pneumonia is to be treated with outpatient therapy or inpatient therapy. Alternatively, the clinician may select an undecided choice, thereby allowing system 200 to give the clinician information regarding the possible benefits of one or other of the possible therapy regimes. When the
clinician is undecided or uncertain as to whether the patient should be treated as an inpatient or an outpatient, the clinician may optionally access or be prompted to access information within knowledge module 226 that gives the clinician the criteria for admission.
Following the therapy clinician classification, the acquisition clinician classification may be determined. The clinician may determine whether the medical condition was hospital acquired (HAP) (ventilator associated or non-ventilator associated), nursing home acquired, HIN-associated pneumonia, Cystic Fibrosis- associated pneumonia, or community acquired (CAP).
Once the clinical classification is identified, the rules control the manner by which system 200 collects the etiology based on the clinical class, as represented by block 346. This may include distinguishing between an uncertain organism requiring an empiric therapy and an organism identified through laboratory results. For example, the organism may be a gram-positive (GP) bacteria, such as Streptococcus pneumoniae (S. pneumoniae) or Staphylococcus aureus (S. aureus) or a gram-negative (GΝ) bacteria, such as Hemophilus influenzae (H. influenzae), Klebsiella pneumoniae (K. pneumoniae), Moraxella catarrhalis, Pseudomonas aeruginosa (P. aeruginosa), or L. pneumophila. If the organism is an atypical pathogen the clinician may select from a list of appropriate pathogens depending upon the type of acquired pneumonia. For example: (i) an Atypical bacterial, such as M. pneumoniae or Chlamydia pneumoniae; (ii) Rickettsiae, such as Coxiella burnetii (Q Fever); (iii) an Acid-fat bacteria, such as M. tuberculosis or MAC complex; (iv) a Fungi Protozoa, such as Coccidiodomycosis, Histoplasmosis, Blastomycosis, P. carinii; (v) a virus, such as Influenza A, Influenza B, Hantavirus, and the like. For example, if the pneumonia is community acquired (CAP) the clinician may be given the options of Legionella, Mycoplasma, Influenza, Chlamydia pneumoniae, Chlamydia psittaci, Coxiella burnetii (Q Fever), and the like. Similarly, if the organism is a Pyogenic pathogen and community acquired, the clinician may select from Streptococcus pneumoniae, Hemophilus influenzae, Staphylococcus aureus, Group A Streptococcus, Pseudomonas aeruginosa, Klebsiella pneumoniae, Νeisseria meningitides, Moraxella catarrhalis, and the like.
Following receipt of the etiology, the rules may present the clinician with various genetic or other susceptibilities of the disease if etiology is organism specific, as
represented by block 348. hi this manner, the clinician may define the etiology of the organism. In this particular example, let us assume that the organism is identified as Staphylococcus aureus. The climcian may provide system 200 with information related to the organism's susceptibilities within the particular patient. For example, the organism may be resistant to linezolid, oxacillin, vancomycin, and dalfopristin-quinupristin. Alternatively, the clinician may not know the susceptibilities thereby relying on system 200 to recommend a treatment that may work.
Upon defining any organism susceptibilities, the rules used by inference module 230 may aid the clinician in defining one or more mitigating factors based upon the etiology, as represented by block 350. The clinician may define factors that may have caused the pneumonia. For example, the patient may have recently aspirated, be immunosuppressed, recently received antibiotics, and the like. Additionally, the mitigating factors may be specific to whether the organism is identified or whether the empiric therapy is to be used for an unknown organism. For example, for an identified organism the clinician may provide information related to abnormal kidney function, Antimicrobial resistance, current or recent treatment failure, and the like. Similarly, if the organism is unknown, the clinician may define information and data related to Abnormal kidney function, Recurrence/relapse, Age, Comorbidities, Severity/Acuteness of illness, Neutropenia, Neutropenia with IV access, Neutropenia and fever despite therapy, Aspiration, Suspicion of organism (esp. HAP, CF), CD4 count (HIV), Disease stage (CF), and the like.
Following the data collection, system 200, and more specifically, decision-support module 210 generates a recommendation for treatment of the patient, optionally using the information gathered by the clinician, the stored patient data, mircorbial susceptibilities and genetic predispositions based upon the patient's family history and relative's medical conditions, the rules, as represented by block 352. Such recommendation may entail decision-support module 210 analyzing: (i) patient's drug allergies; (ii) patient's genetic variations with regard to drug metabolizing enzymes or genetic predisposition to diseases; (iii) genetic variations in the patient's ability to metabolize specific drugs; (iv) drug-drug interactions; (v) dosing requirements based on height, weight, age, sex, and the like; (vi) price; (vii) probability of success for curing the disease; (viii) monographs; (ix) antibiograms or antimicrobial-susceptibility patterns; and (x) formulae of the drug.
System 200 may also use pharmacogenomic data to select particular medical treatment modalilties; thereby using a patient's genetic structure to define responses to prescribed drugs.. For example, a patient may be found through genetic testing to lack an enzyme necessary for a particular drug's metabolism. Hence, decision support module 210 would use such pharamacogenomic information to suggest an alternative drug that avoids toxicity and treatment failure, while being consistent with the patient's condition and pertinent medical parameters.
Additionally, recommendations may include analyzing the need for a referral, other tests, microbial susceptibility or genetic predispositions to the disease or medical condition, family history, behavioral and lifestyle changes, and patient education related to the medical condition or avoiding the medical condition. In this manner, system 200 may optionally evaluate the patient's long-term risk for contracting or their predisposition or susceptibility to various medical conditions. Thus, decision-supported patient data or a decision supported progress note is created.
As mentioned throughout, the above-recited process to generate the decision- supported patient data and the decision-supported progress note may use one or more, rules and provide statements to the clinician to assist the clinician with making an informed decision of medical treatment. Such statements and rules, stored in knowledge module 226, are used by inference module 232 to make the decision-supported recommendation for treatment of the medical condition.
Illustrative rules and statements for the diagnosis and treatment of Pneumonia are represented in Tables 1-5 of Figures 6-10. As illustrated, Table 1 contains a plurality of rules that may be used by inference module 230 to generate the decision-supported patient data and the decision-supported progress note, thereby providing the clinician with a recommended medical treatment for a medical condition. Tables 2-5 (Figures 7-10) contain a number of rules specific to certain information collected by system 200; specifically, optionally sequentially activated rules associated with the analysis of mitigating factors, susceptibilities, and duration of treatment. One skilled in the art may appreciate that various other rules may be appropriate to generate a recommendation for treatment of Pneumonia.
The clinician determines whether the recommendation is correct by analyzing this recommendation. If correct, the treatment is finalized, as represented by block 332 of
Figure 4. Otherwise, system 200 and clinician progress through an iterative process to generate new recommendations based upon other factors that the clinician identifies using the same and/or additional rule specific to other medical conditions identified by the clinician.
It may be appreciated that one skilled in the art may perform the method described herein in a variety of manners, such as in differing order of steps, elimination of one or more steps, inclusion of all, some or addition steps, and the like. For example, steps 340- 350 need not be performed by the clinician but are alternately performed by system 200 based upon patient data stored within patient module 220 and knowledge module 226. Additionally, the method may include various steps associated with system 200 prompting the clinician to complete a medchart to be sent to the Centers for Disease Control (CDC). Additionally, the above method may require checking with the CDC to determine whether a particular medical condition is gaining prevalence within a given regional area or to provide information to the CDC regarding the prevalence of the medical condition within the area that is served by the medical provider utilizing the beneficial properties of the present invention.
Referring now to Figure 11, an illustrative flow diagram for the treating a patient in an "inpatient" setting is depicted. Let us assume that the patient has a known medical condition, such as a urinary tract infection. During a visit with the patient, such as during "rounds", a clinician accesses system 200 through user module 214. Upon identifying the patient with whom he or she is visiting, as depicted by block 370, user module 214 requests the most up to date decision-supported patient data or decision-supported progress notes for the patient. Subsequently, decision-support module 210, either solely or in combination with medical module 216 gathers patient data for the patient selected, as represented by block 372. This may entail each or a combination of the following: (i) searching patient module 220, with its associated databases 222a-222n (Figure 3); (ii) searching one or more modules of ancillary module 256 (Figure 3) of medical module 216; and (iii) receiving patient data from the clinician through user module 214.
Once decision-support module 210 gathers the patient data, inference module 232 of decision-support module 210 updates the decision-supported patient data based upon the most current patient data with the data (such as one or more rules) stored within knowledge module 226, as represented by block 374. Decision-support module 210 then
updates the decision-supported progress note for delivery to the clinician. Analysis of the patient data to update the progress note may be performed in a similar manner as that described with respect to Figure 5.
For example, decision-support module 210 reviews the clinical classification of the infection defined by the clinician and system 200. In this example, decision-support module 210 retrieves information related to the urine collection method, i.e., clean catch, Foley catheter, no urine collected, or other method, verifies the interpretation of the patient's symptoms and signs made by the clinician, i.e., whether the infection is lower tract, upper tract, or asymptomatic, and confirms whether the patient is being treated as an inpatient or an outpatient. In this example, let us assume that the patient is an inpatient and has a lower tract infection.
Upon retrieving the clinical classification, decision-support module 210 retrieves the etiology of the organism. This may include an identified or unidentified organism. If the organism is unidentified, decision-support module 210 checks to see if any cultures are pending. This may require decision-support module 210 to communicate with ancillary module 256 of medical module 216, and more specifically laboratory module 262, to determine whether any cultures are pending. Otherwise, decision-support module 210 analyzes the previous decision-supported patient data and decision-supported progress note for data representative of a request for organism cultures.
If the organism is identified, decision-support module 210 retrieves the information regarding the organism's etiology. For example, as illustrated in Figure 12, the infection may be a bacteria, fungi, a parasite, or a virus. If a bacteria, the organism may be categorized as having gram-negative rods (GNR), gram-negative cocci (GNC), gram positive cocci (GPC), gram-positive rods (GPR), or acid-fast bacteria. In one embodiment of the present invention, as illustrated in Figure 12, decision-support module 210 defines the bacteria to a more specific degree, but for illustrative purposes, the categorization of the bacteria is sufficient to present one skilled in the art with the required information and explanation of the present invention. If the organism is a fungus, the fungus may be Candida spp. or Non-candida spp. Similarly, the particular parasite or virus may be defined. For this illustrative example, let us assume that the patient has Chlamydia.
Following obtaining the etiology, decision-support module 210 gathers any susceptibilities and any mitigating factors. In this particular example, no susceptibilities are necessary. In contrast, however, a number of mitigating factors may be displayed or presented to the climcian. Such mitigating factors may include, but are not limited to pregnancy or post-partum state, renal transplant or other immunosuppression, use of diaphragm prior to onset, recurrence, early relapse of initial treatment failure, diabetes, neurogenic bladder, recent urologic surgery/instrumentation, obstruction or abnormal urological anatomy, duration of symptoms for longer than seven (7) days, age less than three (3) years, and the like. Each mitigating factor may include a rule stored in knowledge module 226 that may be used to guide the decision-support process of the present invention.
Upon completing the above analysis, decision-support module 210 generates an updated decision-supported patient data and decision-supported progress note with a ranked list of recommendations, as represented by blocks 376 and 378. In this example, decision-support module 210 also identifies whether the existing medical care is successful in treating the urinary tract infection and generates a recommendation based upon the current success of the regime.
The above-recited process to generate the decision-supported patient data and the decision-supported progress note may use one or more rules and present the clinician with one or more statements regarding the rule used, as illustrated in Figures 13-19. Such statements and rules, stored in knowledge module 226, are used by inference module 232 to make the decision-supported recommendation for treatment of the medical condition.
As illustrated, Table 6 contains a plurality of rules that are directed to the general decision-supporting process of determining a recommended medical treatment for a medical condition. The illustrated rules contain illustrative logic used to determine and display a particular medical treatment. When the recommended medical treatment is displayed to the clinician, the clinician may optionally select to obtain other medical treatments that would be equivalent to the medical treatment given to the climcian. For example, some of the illustrative rules contain recommended treatments that are underlined. Such medical treatments have associated equivalent medical treatments that the clinician may optionally review and select. For example, the recommended medical treatment may be the prescription of a certain classification of drug, such as
fluoroquinolone. A clinician may operate user interface 246 to obtain the various equivalent medications within the class of fluoroquinolone.
Tables 7-11 (Figures 13-18) contain a number of rules specific to certain information collected by system 200; specifically, optionally sequentially activated rules associated with the mitigating factors, susceptibilities, and duration of treatment. The statements and rules contained in Figures 13-18 are specific to the diagnosis and treatment of Urinary Tract Infection; however one skilled in the art may appreciate that various other rules may be appropriate. Table 12 (Figure 19) depicts illustrative medications that may be prescribed or recommended by decision-support module 210 with associated contraindications. Therefore, decision-support module 210 analyzes the patient's medical history to verify that the patient is not allergic or resistant to a particular recommended medication. If the patient is allergic or resistant, decision-support module 210 defines a new recommendation for the clinician.
As mentioned above, the decision-support progress note, generally, includes all pertinent patient data that relate to the recommended treatments suggested by decision- support module 210. For example, when a therapeutic regimen is suggested, such as when treating the urinary tract infection, the decision-supported patient data includes drug name and type, dose, route, interval, daily cost, duration of therapy, critical alerts and warnings specific to the patient and the drug, patient demographics, logic sectors (rules) that are specific to the patient and the medical condition or syndrome being treated that led to the suggested treatment, and the like. Such information will be specific to each patient. For example, the dose of the therapeutic drug may be defined by decision- support module 210 based upon the height, weight, age, gender, and past medical history of the patient, current laboratory test values, the patients pharamacogenomic data, and the like. Although the analysis performed by decision-support module 210 may not be illustrated or displayed to the clinician, such information may be provided to the clinician via user module 214 if requested by the clinician.
Once a decision-supported progress note is generated for the patient, decision- support module 210 delivers the decision-supported progress notes to the user module 214 through which the clinician has accessed system 200, as represented by block 380.
Upon receiving the required patient data (e.g., decision-supported patient data, patient data, and other patient specific information), the clinician may perform his or her
examination of the patient, as represented by block 382. The examination may be a physical examination, a question and answer session, or a combination thereof. Following the examination, the clinician may update the information stored within user module 214, as represented by block 384.
Subsequently, user module 214 connects to decision-support module 210 to generate new decision-supported patient data and a progress note, as represented by blocks 386 and 388. Following receipt of the new decision-supported patient data, the clinician selects the desired medical treatment or regime, as represented by block 390.
Alternatively, instead of the climcian asking a number of questions as prompted by the clinician's knowledge and information contained within the decision-supported patient data, a patient may answer a number of questions posed through another user module located at the patient's bed. hi this manner, when the clinician examines the patient the clinician merely has to select the desired medical treatment or regime, without connecting to decision-support module 210 to obtain new decision-supported patient data. Hence, steps related to connecting to decision-support module 210 to obtain new decision-supported patient data are optional to the flow diagram depicted in Figure 11.
Once the desired medical treatment or regime is selected, the clinician updates decision-support module 210, and optionally communicates with the necessary sub- modules of ancillary module 256 to request the desired treatment, as represented by block 392. For example, in the event that the medical care recommended by the clinician requires laboratory tests, user module 214 connects to laboratory module 262 to schedule such tests and notifies the nurse or other clinician assistant to obtain the necessary blood or other substances to perform the desired tests. Similarly, if a prescription medication is required, user module 214 connects with pharmacy module 260 to obtain the medication.
Example
Following hereinafter is a generalized discussion of the manner by which decision-support system 200 may be used to provide the clinician with decision-supported patient data and one or more decision-supported progress notes where the medical condition is Meningitis. The example provides more specific rules and parameters related to Meningitis, while further illustrating the flow of data through system 200.
Referring now to Figures 20A-B, a schematic representation of the decision- support process described herein is depicted. As shown, general patient data is obtain by reviewing the medical history or demographic information, as represented by block 400
Following receipt of the demographic information, the clinician may collect disease information such as discussed above. For example, the disease information may be obtained through laboratory tests, from the question and answers provided to the clinician, patient data previously collected, based upon susceptibilities and genetic information associated with the patient's relatives, and the like. Once the disease is identified, a clinical classification is identified based upon the medical condition, as represented by block 402. We are currently assuming that the medical condition meningitis. The clinical classification of meningitis may include determining the duration of the meningitis to thereby decide whether the meningitis is acute or chronic. Different decision-support processes are taken depending if the meningitis is acute or chronic as may be discussed hereinafter.
Once the clinical classification is identified, system 200 collects the etiology based on the clinical classification, as represented by block 404. This may include distinguishing between a bacterial, viral, fungal, and an uncertain etiological classification. Subsequently, the etiology of the disease is determined based upon whether the meningitis is acute or chronic. If acute, the infection may be selected from those listed in block 406 or remain unidentified. Alternatively, system 200 and optionally the clinician may identify the meningitis as chronic, thereby selecting the bacterial, viral, or fungal infection as represented by block 408, or optionally leaving the infection unidentified.
Following receipt of the etiology, a clinician may define the susceptibilities of the disease if etiology is organism specific. For example, different organisms may be resilient to different medical treatments. In the case of meningitis, the various rules may provide:
1. Antibiotic susceptibility list for GNRs (except pseudomonas, Stenotrophomonas, acinetobacter, Hemophilus), may include: Ampicillin/sulbactam, Cephalothin, Ceftazidime, Ceftriaxone, Cefotaxime, Ciprofloxacin, Gentamicin, hnipenem, Levofloxacin, Piperacillin, Piperacillin/tazobactam, Trimethoprim sulfamethoxazole.
2. Antibiotic susceptibility list for Pseudomonas may include: Ceftazidime, Ciprofloxacin, Gentamicin, hnipenem, Piperacillin, Piperacillin/tazobactam.
3. Antibiotic susceptibility list for Staphylococcus may include: Oxacillin, Vancomycin, Rifampin.
4. Antibiotic susceptibility list for Hemophilus may include a 3rd generation cephalosporin.
5. Similarly, antibiotic susceptibility list for Neisseria memngitidis may include a 3rd generation cephalosporin.
6. Susceptibility for Streptococcus pneumoniae may include: Chloramphenicol, Vancomycin, and defined minimum inhibitory concentration (MIC) for pencillin, cefotaxime, ceftriaxone,
7. Susceptibility for S. agalactiae may include: Ampicillin and Gentamicin.
Upon defining any organism susceptibilities, the clinician may define one or more mitigating factors based upon etiology, as represented by blocks 410 and 412 in Figure 20B. The mitigating factors may be specific to whether the organism is identified or whether the empiric therapy is to be used for an unknown organism. For example, for an identified organism the clinician may provide information related to abnormal kidney function, Antimicrobial resistance, current or recent treatment failure, and the like. Similarly, if the organism is unknown, the clinician may define information and data related to Abnormal kidney function, Recurrence/relapse, Age, HIV status, Alcoholism, Concurrent debilitating disease, Concurrent impaired cellular immunity, recent neurosurgery, recent head trauma, presence of V-P shunt, suspected MDR tuberculosis, and the like.
Following the data collection, system 200, and more specifically, decision-support module 210 generates a recommendation for treatment of the patient, by analyzing: (i) patient's drug allergies; (ii) patient's genetic variations with regard to drug metabolizing
enzymes or genetic predisposition to diseases; (iii) genetic variations in the patient's ability to metabolize specific drugs; (iv) drug-drug interactions; (v) dosing requirements based on height, weight, age, sex, and the like; (vi) price; (vii) probability of success for curing the disease; (viii) monographs; (ix) antibiograms or antimicrobial-susceptibility patterns; and (x) formulae of the drug. Additionally, recommendations may include analyzing the need for a referral, additional tests, microbial susceptibility or genetic predisposition to the disease or medical condition, pharmacogenomic data, family history, behavioral and lifestyle changes, and patient education related to the medical condition or avoiding the medical condition. In this manner, system 200 may optionally evaluate the patient's long term risk for contracting or their predisposition or susceptibility to various medical conditions. Thus, decision-supported patient data or a decision supported progress note is created.
The above-recited process to generate the decision-supported patient data and the decision-supported progress note may use one or more statements and rules, as illustrated in Figures 21-24. Such statements and rules, stored in knowledge module 226, are used by inference module 232 to make the decision-supported recommendation for treatment of the medical condition. As illustrated, Table 13 contains a plurality of rules that are directed to the general decision-supporting process of determining a medical treatment for a medical condition of Meningitis. Tables 14-16 (Figures 22-24) contain a number of rules specific to certain information collected by system 200; specifically, optionally sequentially activated rules associated with the duration of treatment, mitigating factors, and caveats. The statements and rules contained in Figures 21-24 are specific to the diagnosis and treatment of Meningitis; however one skilled in the art may appreciate that various other rules may be appropriate.
The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. For example, embodiments of the present invention are also disclosed in copending United States Patent Application entitled "Systems and Methods for Communicating Between a Decision-Support System and One or More Mobile Information Devices", filed September 21, 2000, which is incorporated herein in its entirety by reference. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes
that come within the meaning and range of equivalency of the claims are to be embraced within their scope.
What is claimed is: