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PDA’s in Education

PDAMD has an article by Greg Jeansonne, MS IV about getting PDA’s into the hands of the minions of Hygeia: “an excellent way to make handheld computers more useful in healthcare is to get more people to use them. That includes not only students, residents and fellows, but hospital staff as well.” Jeansonne discusses how to make volume purchases on campus. “As more and more people use PDAs, several key things will begin to happen.”

ZDnet has a report that it isn’t just students who are using PDA’s. The article by Pui-Wing Tam states “The education market is the newest battleground for handheld-device makers, and the stakes are huge.

1st HL7 International Affiliates Meeting

Klaus Veil Writes: “The 1st HL7 International Affiliates Meeting, August 24-25 in Dresden,
Germany, is shaping up quite well – heading towards 100 registrations with 2
1/2 weeks to go. This is the first meeting of the non-US Affiliates
(Australia, Canada, China, Germany, Finland, England, Holland, India, Japan,
Korea, New Zealand, Southern Africa, Switzerland and Taiwan) of the HL7
organisation. However, strong US participation at HL7 Board level has been
confirmed.”
Details can be found here.

“The content is very comprehensive with many HL7 Board members giving
presentations and tutorials on all aspects of HL7. It would be an excellent
opportunity for anyone wanting a fast-track training in all core HL7 topics
(incl. V3, RIM, XML, CCOW, etc.) with a decidedly European flavour a well as
a good overview over current European healthcare standards.”

Open Source Medical Software Goals

The benefits of the open source model in which the actual software parts to build the system are open to the customer to fix and extend holds the promise of overcoming the failures of the past and have been discussed in great detail on this site. They are: 1) Failures are not really failures since anyone can pick up ‘failed’ projects and continue engineering them until success is achieved 2) Intraoperability. 3) Ability to rapidly and cheaply change to meet evolving medical conditions. 4) Security.

Beyond This Horizon

The amount of activity in open source medical software has stepped up considerably over the last months. Several projects, among them FreePM, GNUmed, Freemed and TK_familypractice are moving forward at a good pace. Many are at the alpha stage, with planned beta’s in 2001. What is all this activity for, one may ask, particularly if new to open source medical software. Where is it all going? What is the problem to be solved? A vision of what is beyond the sunset for open source medical software is in order.

30 years is a long time in computing, yet that is how long efforts to computerize medicine have been in existence. A local survey of hospitals in Texas reveals that those efforts have largely failed. Few use clinical computing software beyond obtaining lab results. A ubiquitous, standard computing platform for all aspects of medicine does not currently exist. The usual commercial model of locking customers into a proprietary system that has failed for so many years to produce widespread, robust clinical software, continues to fail to produce a comprehensive, beneficial and economically feasible system.

Fine, but what are we missing by not having widespread open source medical software? Let’s look at what it could look like, beginning in medical school.

Guadalupe Cornelius Chen would get her white coat, stethoscope, fingerprint scan and wireless computer on her first day at school. After the initial speeches by the dean and faculty, she would report to her first class which would consist of a bare room with only a comfortable chair and a light. The lights dim and the walls become alight with images so that the student finds herself inside a convincing illusion of a hospital hallway. After fumbling with controls on her wireless computer she makes herself ‘walk’ through the simulated hallways of the hospital. She is greeted as ‘Dr. Chen’ and is shown to her first patient: a diabetic.

She is speechless at first. After time has elapsed, a kindly attending walks into the room and instructs her as to the proper questions to ask. The student then finds appropriate practice guidelines on her wireless computer based on real world, constantly gathered outcome data sponsored by the National Institute of health, which is easily accessible through an open source client that has been customized and extended for the simulator. The data has made it possible to tailor the treatment to the patient profile that Ms. Chen has gathered and are most likely to achieve success for this patient. The computer even suggests a few questions to ask that will greatly improve the chances of success for both diagnosis and treatment. This particular module was built by a consortium of medical schools and would have been very difficult or very limited if the clinical programs at its base had not been adaptable for this non-commercial purpose.

Dr. Chen slowly keys in the required documentation for the patient and moves on to the next patient. She ends the first patient encounter by ordering the proper medications electronically in a way that is virtually guaranteed to be error free and automatically chooses the most cost-efficient medication. The drug ordering module, open sourced years before, is constantly improved by government, insurance agencies and drug companies since it has been shown to drastically reduce errors and the price of delivering care.

Six months later, the student begins to see a few real patients, but she has ‘treated’ approximately 3000 simulated patients. Faculty have followed her progress through the simulator and have verified her progress with the real patients. She has ‘killed’ 50 and has been ‘sued’ 3 times. She is now achieving a sustained rate of treating 40 general practice patients a day with an error rate lower than any clinician today. Her ‘attending’ must intervene only a few times a day now. In six more months, she will be treating 50 simulated patients a day and will not be confined to a single specialty. This high rate of patient processing can be done because time wasters such as an illegible chart, hunting for the chart and associated paper work as well as redundant drug data ordering is gone. The work is still difficult, but her fine brain is working on problems worthy of it, diagnosis and treatment, not mechanics.

The patients Dr. Chen is seeing are cases that have been automatically built based upon actual local cases in the teaching hospital or clinic which the computer. The ability to extract these cases is possible because the University computer system is all open source and modular so that a data stream can be easily built from the University system and diverted to the simulator. It will be sanitized (by an open source module originally intended for researchers) for confidential data but still retaining locally important issues.

Dr. Chen only feels it necessary to call her ‘attending’ once a week now with the simulator giving her constant feedback on her performance. No useless lectures, no esoteric research topics, the entire time has been spent efficiently learning how to take care of patients using standard open source technology. She has even been able to build a few interesting cases herself that were accepted for inclusion in a national database.

During her past medical school year, medical knowledge, forms, practice parameters, managed care plans and government rules have been updated several thousand times. The extra effort to deal with these changes has been a light burden indeed for the student because her wireless computer has updated itself subtly so that she did not have to worry or care about these details. Those details were left to over a thousand system designers from various open source foundations, patient advocacy groups, insurance companies and government agencies that have updated the open software base in response to changing conditions. Dr. Chen is left to focus on the patient and establish a relationship with each one. Fraud can only be accomplished with great and deliberate effort since mere clerical errors are quite rare, having been designed out of the system.

In the next three months, the simulator trains her in managing her own appointments, billing and staff with well tested open source software sponsored by Franklin-Covey. Initially, 3 of her simulated workers quit in disgust at her incompetent, overbearing manner. The remaining staff coaches her in how to be a team player and she eventually acquires and trains more staff who express high satisfaction with her as a boss. Her final three months prior to entering a real hospital is spent negotiating contracts, making executive decisions about the day to day operations of a hospital and clinic. No exam is required, as her examinations were always inherent in the system.

Her actual contact with real patients has accelerated so that at the end of her second year she is functioning as a physician and only has to have her work given a cursory check by her attending since software safeguards for treatment error are always in place. She could also spend time in the simulator and get refreshed on subjects she had difficulty with. Her wireless computer has been a great help and she now has a sizable database of real and simulated cases that she can continue to measure her skills against and refer to for the rest of her life. The computer has noted her weak areas and she was able to reduce her error rate and improve the outcome of her patients quickly once she had seen a sufficient number of patients.

Many of her real attendings lamented the days in which they had an entourage of students staring at their shoes, but they also noted that the volume of patients the hospital was able to see had expanded tenfold as well as achieving a tremendous reduction of errors.

Dr. Chen graduated with honors, but the difference between the valedictorian and the bottom of the class was slight. Even the poorest physician in the group was more than adequate. Gone was the hit or miss teaching methods and critical people that made a medical teaching program collapse like a house of cards if key faculty left. Medical training for Dr. Chen is considered too important to be left to such fragile methods. Below standard physicians usually leave the profession since high error rates in a well trained physician could only be achieved by impairment, distraction or sabotage, quickly noticed by valid statistics securely and confidentially accessible by State boards.

Even with physicians impaired by circumstances such as residency, the system is a great help since it makes errors difficult to make. Particularly errors based on lack of information.

Dr. Chen moved onto private practice where she found the same system in place that she was trained on in medical school. Her faithful wireless computer and its now large database of treated cases went with her so that she was fully productive in a few days. She achieved in a few weeks a level of effectiveness in treating her patients that formerly clinicians achieved after years. In addition, all the power tools required to run her practice: appointment scheduling, billing, pharmacy ordering use the same interface she learned in medical school. A fact that enables her to take on other physicians patients with ease since they use the same standard system. The only difference is which drug company logo adorns her generally free system…

The above vignette of Dr. Chen’s life is the goal of open source medical software. Most of the above systems are either currently unavailable, or poorly intergrated and without intraoperability since there is a disincentive to do so. Furthermore, many of the above systems will not be possible with closed source because necessary additions or changes to base software in order to run derivative software (the patient simulator) could not be accomplished. Dr. Chen’s future life is the goal of open source medical software.

Alliance of Medical Internet Professionals Organization Inspired by Open Source Success

The Alliance of Medical Internet Professionals is an Internet-based organization formed to connect Medical Internet Professionals globally. The objective is to improve the quality of healthcare to people around the world. The organization endeavours to discover innovative methods for applying Internet technology in the practice of medicine.

The AMIP Home page states that the organization “was inspired by successes in the “Open Source” computer community, most notably the Linux community. We aim to apply their example to the medical community by stimulating sharing of ideas and expertise to improve communication, collaboration, and cooperation among medical professionals to solve the complex problems facing medicine.”

Software Patent ‘Hall of Shame’

Horst Herb, leader of the GNUmed project spotted a February announcement of the award of patent #5833599 to Multum Information Services for ‘Providing Patient-Specific Drug Information’. Dr. Herb was quick to note its implications ‘a patent suitable for a health IT hall of shame…proprietarization of commonwealth knowledge at its worst!’ Tim Cook of the Free Practice Management project has stronger words:

‘This is absurd. I read through the patent and see no ‘uniqueness’ at all. They are simply applying search algorithms to databases. There is a reference to AI and they use an off the shelf expert system from Neuron Data, Inc. The only proprietary part I see (IANAL) is the compilation of drug information in the knowledge base. Whoopee! Our ‘civil servants’ are incompetent to perform their jobs.’


What remains to be seen is if the patent is enforceable. Jim Intriglia of www.jimintriglia.com writes: It is one thing to hold a patent, quite another to defend it or even collect on it.

Mumps Compiler Version 2.0

The MUMPS (M) programming language has long been used in health-care. Its history and other details can be found here. Version 2.0 of a compiler to translate Mumps (M) to C is now available. Translations such as this make it easy for programs written in MUMPS to run on any computer. It implements
a substantial sub-set of the 1995 Mumps (M)
standard. This compiler includes support for limited indirection (“@” level
only at present), B-Tree based global arrays,
SQL (PostgreSQL) and extensions. In addition, it has code to facilitate development of web server-side applications. Details, download and documentation can be found here.

GNUMed Alpha Server Possible in October 2000

Dr. Herb Horst of the GNUmed project has set out a tentative timetable for the availability of GNUMed “Provided people keep their promises…” The available schedule follows, highlights are Alpha releases in mid-October 2000 for server, December for client. Beta release in February 2001. “…looking for more developers to join, especially SQL wizards…” Note for US readers, the dates are written in Aussie DdMmYYYY format.

10.08.2000 alpha test SQL meta file: most entities and relations defined,
script to create an empty GNUMed database plus fully functional tables with
ICD-9/10 and other codes, some drug info, zip codes etc.

01.10.2000 alpha test server / API: working transaction server and most
logic on Interbase server functional. API for clients defined. From here
onwards it should be possible to write already functional clients

01.12.2000 first GUI client in alpha preview available: From here onwards
the system is theoretically functional. Design studies (executable ones)
exist already today but do not connect to the database yet.

01.02.2001 first beta test version (client and server)
Whooo-hooo. I hope we can make it until then.

The GNUMed project is looking for more developers to join, especially SQL wizards. The more people help, the earlier we can release. Looks as if funding will be available in the near future.