A. Field of the Invention
This invention relates to the field of computerized techniques for enhancing the scope and performance of medical, dental, and orthodontic practices from the business aspects as well as the care planning and delivery aspects concerning human patients. More particularly, the invention is directed to an interactive workstation and associated computerized techniques for facilitating practice benchmarking, clinical benchmarking, care planning, and providing other services for the benefit of the practitioner and the patient.
B. Description of Related Art
In recent years, computer-based approaches have been proposed for aiding orthodontists in their practice. However, these approaches are limited to diagnosis and treatment planning of craniofacial structures, including the straightening of teeth. See Andreiko, U.S. Pat. No. 6,015,289; Snow, U.S. Pat. No. 6,068,482; Kopelmann et al., U.S. Pat. No. 6,099,314; Doyle, et al., U.S. Pat. No. 5,879,158; Wu et al., U.S. Pat. No. 5,338,198, and Chisti et al., U.S. Pat. Nos. 5,975,893 and 6,227,850, the contents of each of which is incorporated by reference herein. Also see imaging and diagnostic software and other related products marketed by Dolphin Imaging, 6641 Independence Avenue, Canoga Park, Calif. 91303-2944. A method for generation of a 3D model of the dentition from an in-vivo scan of the patient, and interactive computer-based treatment planning for orthodontic patients, is described in published PCT patent application of OraMetrix, Inc., the assignee of this invention, publication no. WO 01/80761, the contents of which are incorporated by reference herein. Other background references related to capturing three dimensional models of dentition and associated craniofacial structures include S. M. Yamany and A. A. Farag, “A System for Human Jaw Modeling Using Intra-Oral Images” in Proc. IEEE Eng. Med. Biol. Soc. (EMBS) Conf., Vol. 20, Hong Kong, October 1998, pp. 563-566; and M. Yamany, A. A. Farag, David Tasman, A. G. Farman, “A 3-D Reconstruction System for the Human Jaw Using a Sequence of Optical Images,” IEEE Transactions on Medical Imaging, Vol. 19, No. 5, May 2000, pp. 538-547. The contents of these references are incorporated by reference herein.
The technical literature further includes a body of literature describing the creation of 3D models of faces from photographs, and computerized facial animation and morphable modeling of faces. See, e.g., Pighin et al., Synthesizing Realistic Facial Expression from Photographs, Computer Graphics Proceedings SIGGRAPH '98, pp. 78-94 (1998); Pighin et al., Realistic Facial Animation Using Image-based 3D Morphing, Technical Report no. UW-CSE-97-01-03, University of Washington (May 9, 1997); and Blantz et al., A Morphable Model for The Synthesis of 3D Faces, Computer Graphics Proceedings SIGGRAPH '99 (August, 1999). The contents of these references are incorporated by reference herein.
Computerized tools for orthodontic modeling and treatment planning are marketed by companies such as Align Technology, Inc., 881 Main Avenue, Santa Clara, Calif. 95050; Ormco Corporation, 1717 West Collins, Orange, Calif. 92867; and Cadent Inc., 640 Gotham Parkway, Carlstadt, N.J. 07072-2405. However, they are all specialized for their respective products; and thus limited in functionalities.
The art has lacked a truly interactive, integrated and unified system which facilitates practice and clinical benchmarking, and unifying other functionalities of a practice such as for planning of care for medical and dental human patients.
A principal benefit of the invention is that it provides a workstation that integrates practice benchmarking, clinical benchmarking, treatment planning, and other functions for delivering care to a patient in the same system; thus eliminating the need for more expensive and less efficient multiple workstations wherein each workstation is dedicated to performing one specific function or a limited sub-set of functions necessary in a practitioner's practice.
In a first embodiment of the invention, the unified workstation facilitates benchmarking practitioner's practice from a business perspective. The workstation maintains a central repository of a practice benchmarking database comprising contemporary performance data from industry standard practices, including, for example, data from superior performing practices, data from educational institutions, data from care institutions, etc. The evaluation of the practice is performed by comparing certain performance metrics for the practice of interest against those of the comparable industry standards; analyzing the differences; reporting the results, and, when the differences indicate inferior performance by the practice of interest in one or more areas, identifying appropriate corrective actions.
In another embodiment of the invention, the unified workstation facilitates selection of an initial treatment plan with the help of a clinical benchmarking database. The method relies upon the use of the clinical benchmarking database, which is created by storing the clinical treatment history of individual patients coupled with a variety of other types of information, such as demographic information concerning patients, practitioners, practice-staff, diagnosis and therapeutics information, the results of patient survey regarding satisfaction with treatment, pain experienced during treatment, reference literature, workflow processes, instrumentation information, etc. Patient diagnosis and characteristics are compared with those in the clinical benchmarking database, and a selection is made of one or more suitable reference treatments. The results are then presented to the practitioner. The practitioner discusses the treatment options with the patient, and, in concurrence with the patient, selects the one that most satisfies the patient needs and constraints, such as the importance the patient places on esthetics in relation to the associated treatment expenditure, patient's insurance coverage, and other similar factors.
In yet another embodiment of the invention, the unified workstation facilitates periodic, ongoing evaluation of a patient's actual, monitored progress in response to the prescribed treatment with the help of the clinical benchmarking database comprising clinical treatment histories and characteristics of a large number of patients. From the database, a reference patient and associated treatment plan that come closest to the patient of interest are chosen. Then, the patient's progress at the particular point in time in the treatment course, e.g. individual tooth movement, is compared against the progress for the reference patient at a comparable elapsed time in the reference patient's treatment, and the results given to the practitioner. In the instances where the actual response matches the expected response, the knowledge so gained could be added to the clinical benchmarking database. Furthermore, if the patient's progress is found to be lagging significantly behind that of the selected reference patient, a root cause analysis is performed to identify the source of the problem. The source of the problem could be either the prescribed treatment or the patient behavior. If the treatment is found lacking, appropriate corrective actions are suggested to the practitioner. On the other hand, if it is determined that the patient might not be adhering to the prescribed treatment regimen, then patient counseling is recommended to the practitioner.
This is a closed-loop approach wherein the actual response to the treatment is utilized in deciding the future course of action. In particular embodiments, the invention can be used to predict the treatment response, such as the tooth-movement behavior. This predicted tooth movement behavior can be used for calendar management for facilitating scheduling of patient's future visits to the practitioner's clinic, and sending out reminders. Moreover, the clinical benchmarking knowledge database supports the use of intelligent queries of the database to seek information regarding practice-related issues, using known database query langagues. In the current practice, orthodontists largely rely upon trial and error methods and intuition, and function in a reactive rather than a proactive manner, to make corrective adjustments, which approach may not be the most efficient for delivering care to the patients. A major benefit of the innovative approach proposed herein is that it facilitates consistent and far more effective, evidence based care that closely matches the patient needs, than the traditional hit-and-miss anecdotal care that heavily relies upon experience for success. In turn, this approach leads to much faster, and cost-effective acquisition of the target disposition of the patient, when compared to the traditional approach. Yet another benefit is that the unified workstation facilitates increased productivity from the practitioner and the practitioner's staff, enabling reduction of cost in the delivery of the patient care. Another aspect of this invention is that it enables the practitioner to develop benchmarks personalized to individual patients.
In yet another embodiment of the invention, the unified workstation is used to offer orthodontic clinical benchmarking as a service for initial treatment planning as well as for planning adjustments during the course of the treatment. In varying aspects such a service can be used by the entire care delivery and care consuming enterprise including practitioners, manufacturers and suppliers of appliances, patients, etc.
In yet another embodiment of the invention, the unified workstation offers application specific databases (clinical knowledge database), application specific computerized modeling and simulation tools, and interfaces for accessing other resources in order to facilitate and enable a variety of functionalities and services. These functions and services could include, for example, intelligent queries of the database, seeking information from reference treatments, accessing reference information, meta-analysis of patient studies, etc. These functions would also preferably include software developing a comprehensive treatment plan that is tailored to satisfy patient-specific needs, such as diagnosis, therapeutics planning, and care monitoring and management. Additionally, the software provides the ability to identifying a reference patient in the clinical benchmarking knowledge database that matches, at least approximately, the orthodontic condition of the patient. The software further provides a function of obtaining and using data comprising the condition of the patient during the course of treatment (such as scan data from a scan of the patient's dentition during the course of treatment) and thereby monitoring the progress of the patient in response to the treatment and comparing the monitored progress to an expected progress for the patient. Once the treatment is in progress, the workstation thus provides the capability of periodically monitoring the actual patient response to the treatment, comparing it against the predicted performance, and evaluating the differences between the actual response and the expected response, and in the event that the actual response is unsatisfactory. In preferred embodiments, the software may assist the practitioner or user of the workstation in the performing of a root cause analysis to identify the source of the problem and taking appropriate corrective actions such as adjusting the treatment or counseling the patient.
Other functions or features may be provided in the software, such as:
Automatically generating a template by which a practitioner would enter information in order to query the clinical benchmarking knowledge database, as part of generation of an initial treatment plan;
during the course of the functionalities described above, consulting with other specialists as necessary;
during the course of the functionalities described above, consulting with other tertiary care facilities as necessary;
during the course of the functionalities described above, consulting with resources of manufacturers and suppliers of applicable products as necessary;
during the course of the functionalities described above, consulting with resources of applicable laboratories as necessary;
during the course of the functionalities described above, consulting with archived library resources or research centers as necessary;
conducting the process of functionalities described above, coupled with one or more of the other functionalities mentioned in a closed-loop manner such that the patient care is delivered in the best possible manner in accordance with the patient needs; and creating and updating a comprehensive repository of patient-treatment history knowledge base that might be useful in developing industry standards, the clinical benchmarking knowledge base, and new, more effective products;
bidding by manufacturers, suppliers, and labs for the practitioner's business;
demand aggregation and discount purchasing by individual practitioners or groups of practitioners;
demand aggregation and discount purchasing of care by groups of patients;
medical, dental, and orthodontic referral services;
knowledge base service or a smart service wherein a practitioner selects one or more variables the practitioner would like to track. When the selected variables in actuality approach or cross the desired thresholds, the system would facilitate issuance of warnings, and would identify appropriate corrective actions or options, and/or provide links to other information or knowledge bases which may further suggest corrective actions and options.
computerized, interactive education and training services;
Board Certification facilitation service wherein the regulatory Board is provided with an access, as the practitioner's request, to the practitioner's case records for aiding in the practitioner's professional certification process;
insurance information services;
financial services; etc.
In yet another embodiment of the invention, the unified workstation facilitates a variety of scenarios for assisting in the treatment planning, both during the initial treatment selection phase, and, if necessary, during the midcourse adjustment phase as follows:
(a) The modeling and simulation steps during the treatment planning phase are all completely performed at the unified workstation by utilizing the software resident within the unified workstation system. Such software could be obtained from one or more entities such as appliance manufacturers.
(b) Alternately, the unified workstation simply obtains the results from treatment modeling and simulation done at various entities sites. This could be done by accessing the sites via the Internet links.
(c) A combination of the scenarios (a) and (b) above where complete treatment modeling and simulation related to some of the entities is done at the unified workstation with the resident software, and combined with the treatment modeling and simulation results obtained from the remaining entities.
(d) In conjunction with the scenario (a), (b) or (c), the evaluation and selection or recommendation for selection of the treatment course is done at the unified workstation utilizing software tools that optimize treatment plans in accordance with the patient needs.
(e) The treatment plan in (d) above might be such that only one type of appliances, e.g. fixed of removable, is used during the entire course of the treatment. Alternatively, the treatment plan could be one in which an all-dental approach is taken, restorative devices are used, or prosthetic devices are used.
(f) On the other hand, the treatment plan in (d) above might be such that it is a hybrid plan requiring the use of different types of appliances during the course of the treatment. In the hybrid orthodontic treatment plan, a variety of scenarios is possible. In one type of hybrid treatment plan, different types of appliances might be used at different times during the course of the treatment, e.g., brackets and wires used initially and transparent removable aligning shells used later on. In another type of hybrid treatment plan, different types of appliances might be used simultaneously, for example in different portions of the mouth, for example brackets and wires could be used for certain teeth and transparent removable aligning shells uses for a different set of teeth. A hybrid treatment plan may be chosen right from the beginning, or it may be introduced dynamically at any stage during the treatment course.
Thus, in the broader aspects, we have invented an interactive, unified workstation that not only unifies in a single system multitude of functionalities pertaining to a practitioner's practice that would otherwise require disjointed, more expensive, and less efficient individual workstations dedicated to a specific, limited task or a sub-set of tasks, but also provides additional novel and comprehensive functionalities that would revolutionize the medical, dental, and orthodontic practices and vastly improve the delivery of care to patients in a manner that truly satisfies their needs. The invention is directed towards benchmarking for a practitioner's business practice, as well as for clinical aspects of initial and ongoing treatment planning, towards enabling a variety of novel functionalities and services and integrating overall patient care planning functions, including planning for hybrid treatment.
Presently preferred embodiments of the invention are described below in reference to the appended drawings, wherein like reference numerals refer to like elements in the various views, and in which:
Overview
The computer 20 at the clinics 10, and device 21 are connected to the Internet in known fashion so as to be able to communicate and share files with computers at other remote locations.
The environment shown in
Furthermore, while the computer 24 is shown at a service provider site, it is possible to export the software and databases described herein to a computer situated virtually anywhere, such as in one of the clinics or at the appliance manufacturer, and these features could be executed at such locations. Hence, while the description set forth herein will describe the invention in the context of the particular environment of
These services can include providing practice evaluation from a business point of view, clinical evaluation of patients and recommendations for patient treatment, treatment plan adjustment, and root cause analysis where the course of treatment departs from the expected course of treatment. The service provider 22, in some embodiments of the invention, may also provide treatment planning and appliance design services for practitioners at remotely located clinics.
The environment of
Similarly, clinics 27 of specialists, such as endodontists, periodontists, maxillofacial surgeons, prosthodontists, restorative dentists, etc., are also connected via the unified workstation and the Internet to the clinics.
Other entities 28, such as electronic archived library resources, tertiary care facilities, research centers etc. are also connected to the Internet and available as resources to the clinics through the unified workstation 24. Other entities 28 might very include a regulatory Board that periodically certifies the practitioners under its jurisdiction. The service provider 22, in an embodiment of the invention, at a practitioner's request can provide access to appropriate regulatory Board for obtaining information necessary for re-certification of the practitioner. In yet another embodiment of the invention, the service provider 22 can facilitate knowledge-base based smart service. Upon invoking the smart service, a practitioner selects one or more variables the practitioner would like to track, for example the practitioner's monthly income, or the average time between clinic visits of a patient, etc. When the selected variables in actuality approach or cross the desired thresholds (which may be based on then prevailing industry standards), the service would facilitate issuance of warnings, would enable root cause analysis, and would identify appropriate corrective actions or options, and/or provide links to other information or knowledge bases which may further aid in identifying suitable corrective actions. Another feature of this invention is demand aggregation by one or more practitioners or groups of patients for more cost effective purchasing of treatment appliances, supplies, and services. The service provider facilitates archival services as well as knowledge based smart services. A practitioner can use such services to aid in the life-long learning process.
The service provider 22 can offer yet additional services through the unified workstation 24. Such services can include computerized, interactive education and training services, insurance information services, financial services, etc.
The details as to the construction and organization of the workstation are not particularly important. The computer will typically take the form of an Apple or IBM compatible computer and a Windows-based operating system using by a Pentium or similar processor and will have static and dynamic memory devices, either local, on attached peripheral devices, or on a network server connected to the workstation, that contain the database and software features described herein.
In another embodiment, other entities 28 include patient groups that are connected to the unified workstation 24 through the Internet. Through this interface patients can gain access to practitioner referral services. Additionally the patient groups can aggregate their needs and utilize the unified workstation 24 to make bulk purchasing at discounted prices and gain access to variety of bidding services involving manufacturers and practitioners.
In the embodiment of
Representative forms of the databases 32 and 34 are described in more detail herein. The treatment planning software may take the form described in published PCT application of OraMetrix, no. WO 01/80761, the patents of Chisti et al., or Doyle et al., cited previously. The nature of the treatment planning software is not considered important. The descriptions of the treatment planning software of each of the referenced patents and published applications is incorporated by reference herein.
The diagnosis information 40 typically includes audio, video, images, text, and data records comprising clinical examination records comprising 2D images, 3D images, CAT scan, MRI, physical model, photographs, digital data from direct scanning of a patient or from scanning of a model representing the patient, ultra-sonic images, X-rays, etc; medical health history; dental health history; and radio graphic examination records. The therapeutic information 42 includes treatment planning and delivery information comprising care plans, delivery means, and delivery schedule for the treatment. The care enterprise information 44 includes care monitoring and management information comprising information on laboratories, manufacturers, and suppliers for testing and delivery of treatment means; information on the practitioner and the practitioner's assistants, and the information on patients and guardians of patients. The information further includes the product information and the supplies information. The laboratories are for example AOA, Great Lakes, etc. Communication records 46 comprise communication between the practitioner and the patient, between the practitioner and another practitioner, between the practitioner and the lab, between the practitioner and the manufacturer, between the practitioner and the supplier, etc. The communication referred to here is a two-way communication between the user of the information and the provider of the information. Elements 38-54 combine to create an extensive knowledge base for the practitioner. This knowledge base is used by the practitioner to mine data and information to facilitate delivery of much improved and more efficient care to patients.
Although not shown in
With the above overview in mind and with reference to
Step 62 may be accomplished for example by the practitioner sending a file from the clinic to the service provider containing various performance metrics of the practitioners' practice and evaluating those metrics by comparison to the industry standards in the database 32.
The method further includes the step 64 of analyzing, via the computer software instructions, the difference, if any, between each of the performance metrics for the practitioner's practice and the industry standard practices. For example, the software may determine that in three of eleven different categories the practitioners' practice is at or below industry standards. It should be noted that the processing could be done locally locally at the workstation, ort his analysis could be done on a remote computer by a service provider providing performance benchmarking as a service for the practitioner (e.g., for a fee).
The method further includes a step 66 of providing the results of the step of analyzing to the practitioner, for example in the form of a report including graphs, tables etc.
After the results are reported to the practitioner, the method includes a step 68 of determining whether the performance is unsatisfactory. A human may perform the method step 68, for example by a subjective analysis of the report. On the other hand, the step 68 could be performed automatically. For example, if the practice in any one category is below industry standard the results may be deemed “unsatisfactory.”
When the results are unacceptable to the practitioner, the method continues by identifying one or more corrective actions to more closely align the practitioner's practice with the industry standard practices. This step 70 may be performed with the aid of computer software instructions. For example, the computer software may determine at step 66 that the practitioner is averaging an unduly high number of visits per patient during the course of treatment and the instructions may determine that the number of patient visits could be reduced by changing treatment modalities for treating patients. Alternatively, the software could determine that the per-patient net fee income is ten percent below the industry average and propose corrective action of reducing costs in one or more areas, such as by using a different choice of appliance design, supplier, or other solution.
If the step 68 indicates that the practitioner's practice is performing satisfactorily, then at step 72 a positive result is indicated and no need for corrective action is necessarily required.
The method shown in
Revenue from the practice, such as the net fee collected over a period of time, either on a per-patient or per-practice basis, field 74. The net fee collected may exclude selling costs and bad debt.
Capital requirements, field 76. This field may include maintenance and operating costs.
Space requirements, including clinical and office space, field 78;
Number of office visits required by a patient, field 80;
Actual patient chair time in the office, field 82. Numerous other possible fields 84 are contemplated in the database, including:
assistant and administrative time, including time spent by chair side assistants, lab personnel and assistants, and administration personnel including schedulers, devoted per patient;
practitioner's time devoted per patient;
total time elapsed per patient from initial visit to the final visit;
cost of consumables, which may include both procuring and storing costs;
cost of training and certification, etc., to maintain proficiency for the practitioner and the practitioner's staff;
patient and other demographic factors including pricing elasticity, estimated patient population, etc.;
typical cost of treatment per patient per visit, and overall cost for the complete treatment; and
practitioner's practice workflow.
Referring now to
One parameter that can be measured to determine adherence to the benchmark is the distance of the tooth movement vs. time; and compared against the value predicted by the benchmark or previous case history. The major benefit is that it aids in achieving the orthodontic treatment results faster and in an effective manner. Another benefit is that the method offers a procedure to gather data related to patient treatment that can be used to develop and enhance benchmark treatment, which when successful is used in enhancing the standards guide to practitioners. In other words evidence based patient care protocol can be developed with such information. Data gathered in this manner are used to develop new, more efficient products. Such data can also be used to explain to the patient the available treatment alternatives, and assist the patient in selecting the most efficient and the best quality care that would satisfy the patient overall needs. In particular embodiments, the invention can be used to predict the treatment response such as the tooth-movement behavior; and to schedule future patient visits. In the current practice, orthodontists largely rely upon trial and error methods and intuition, in a reactive rather than a proactive manner, to make corrective adjustments which may not be the most efficient.
The method of solving the problem relies upon the use of a large knowledge base created by storing the clinical treatment history of individual patients. Such a database categorizes patients according to sex, age, race, risk factors such as physiological, biological, psychosocial, financial, etc. and other parameters deemed important from the view point of the orthodontic treatment.
The method of
The method continues with a step 92 of obtaining a diagnosis of a given patient. The diagnosis and other patient information may be stored in a patient database (see
The method further includes the step 94 of obtaining, from the practitioner, an identification of parameters or characteristics deemed important concerning the patient. These parameters or characteristics may include, for example, cost, treatment time, appliance preferences, frequency of visits, type of results, etc.
The method further includes the step 96 of finding a match in the clinical benchmarking knowledge database 34 by comparing the diagnosis from step 92 and the parameters or characteristics from step 94 for the patient with the entries in the clinical benchmarking knowledge database 34. In other words, at step 96 the software looks for a patient record in the database 34 that closely matches the patient's diagnosis and any patient parameters that are provided, such as the 3D configuration of the teeth in the malocclusion and the appliance type(s). This step may be performed by algorithms that perform a comparison of 3D tooth geometries of the present patient and the stored data of 3D tooth geometry prior to treatment from the reference patients in the database to find a “match” for the present patient, and look for similar appliance type. One or more patients with the closest geometry found are chosen as candidate references. Other criteria are then applied to the candidate references, for example length of time taken to realize the desired repositioning of the teeth, for selecting a preferred reference as a match.
Alternately, from step 96 and through link 106, the method continues at step 104 where the matches are ranked.
The method further includes the step 98 of devising an initial treatment plan for the orthodontic patient with the aid of the match from the clinical benchmarking knowledge database. The initial treatment plan may consist of tooth movement steps, appliance designs, stages of treatment, any extractions, or some combination of these features to treat the patient. The initial treatment plan may use as a guidepost the treatment plan of the reference patient in the database as a starting point, with modifications and departures from the treatment plan taken to account for individual tooth anatomy of the patient now under treatment. The treatment plan may be created interactively using interactive treatment planning software described above.
The method further includes the step 100 of charging the practitioner for the service of having access the patient database and providing the initial treatment plan 98. Thus, a business model can arise out of the furnishing of services including the software that obtains the patient information, compares it to a database of clinical benchmarks for patients and providing a treatment plan. The charges assessed could be developed or negotiated in any suitable manner, such as per-patient fee; an annual fee based on the expected or actual number of patients per year, etc. In one possible embodiment, a supplier of orthodontic apparatus could provide the services described in
It should be noted that step 100 is optional. The method shown in
The method further includes the step 102 of recording the recommendations (the initial treatment plan), any changes to the treatment plan made by the practitioner, the reference patient information from the database 34, and any charges, in memory in the computer 24. This data could be stored as a fields in the patient database of
The patient records also contain a field 122 containing patient specific characteristics, such as age, sex, race, diagnosis, prior tooth extraction, patient preferences regarding cost, appliance type, treatment time, insurance coverage, credit history, financial history, risk factors, etc.
As will be appreciated from
An alternative embodiment of the invention provides a unified workstation system for aiding in facilitating care of an orthodontic patient. The workstation may be for example the workstation 24 of
The memory in the workstation further stores a patient database for the current patient. A patient database 38 is shown in
Optional fields included in the patient database include a medical history field 140, a dental history field 142, a field 148 indicating a ranking of patient-specific characteristics in order of patient preference, such as cost, treatment time, appliance type, frequency of visits, etc. Other fields include a field 110 storing the patient's initial treatment plan, a field 150 containing updated treatment plans, a field 152 containing 3D scans, 3D teeth geometry, tooth movement and disposition from monitoring scans obtained during the course of treatment, a field 154 containing benchmarks for treatment progress, a field 156 containing other image data, such as X-ray, photographs, MRI scans, CT scans, etc. In one possible embodiment, all of the image data including photographs of patients face could be combined into a composite three-dimensional virtual model and stored in a field 158. A method of creating a complete three-dimensional virtual patient from a plurality of images from different imaging devices is described in U.S. Pat. No. 6,512,994, and the patent application filed May 2, 2003 of Rohit Sachdeva, Ser. No. 10/429,123, now issued as U.S. Pat. No. 7,234,937, entitled UNIFIED WORKSTATION FOR VIRTUAL CRANIOFACIAL DIAGNOSIS, TREATMENT PLANNING AND THERAPEUTICS, the contents of both of which are incorporated by reference herein.
The workstation 24 also includes a set of software instructions operating on the patient database 38 of
It may be the case that multiple matching case histories are found, particularly if the patient database is large and has a diverse set of cases. Some ranking of the cases from the case history could be performed. For example, the workstation may include software instructions that arrange the identified matches from the reference clinical treatment histories in a sequential order by (1) comparing the patient's patient-specific characteristics (field 122,
In one possible embodiment, after treatment commences the patient is periodically imaged or scanned during the course of treatment to monitor progress. The patient database 38 is updated with a set of 2D or 3D images of the patient's treatment response when a milestone in the treatment of the patient is completed. A number of milestones could be set for a given patient, and these scans could be obtained at each milestone. The resulting 3D data from a scan of the patient at each milestone is stored in the patient database, such as in field 152.
In another possible embodiment, the workstation includes a set of software instructions for evaluating the patient's progress in response to the treatment by measuring the distance of movement of the patient's tooth or teeth versus elapsed treatment time (alternatively, quality of tooth movement versus quantity of tooth movement), and comparing the results against the data for the same elapsed time period for a selected clinical benchmark treatment. For example, the software would take the position of a given tooth, compare its position in three-dimensional space at the first milestone with the position of the tooth at the initiation of treatment, and determine how far the tooth has moved. Here, treatment response could be measured in terms of total displacement of the center of the tooth, and rotation movement of the tooth. Calculation of rotation of the tooth could be achieved by constructing a vector from the center of the tooth through the center of crown, and comparing the orientation of the vector at the initial situation with the vector orientation at the milestone to determine rotation and tilting of the tooth. Then, given the total movement (including rotation) and the time elapsed from initiation of treatment to the first milestone, tooth movement per day can be quantified.
This workstation could also include instructions in software that would take this objective measure of tooth movement and compared it with the tooth movement per day in the reference case history to gain some assessment of how well the treatment of the patient is progressing. For example, if the patient's tooth movement is less than 50% of that of the reference patient, progress may be deemed unsatisfactory. Consequently, the workstation may assist in the user performing a root cause analysis to determine the source of the undesirable tooth movement. Various types of root cause analysis are contemplate, both automated and human, are described below. Thus, whenever the patient's progress in response to the treatment is found to be unsatisfactory, the software assists a user in performing a root cause analysis for the problem and for identifying one or more appropriate corrective actions.
As another embodiment, the workstation may also include a software tool for predicting the tooth-movement behavior of the patient under the treatment. For example, given the patient's current tooth positions and the choice of appliance, based on the reference case history it may be predicted that the patient's tooth movement will match that of the reference patient. This prediction of tooth movement can be integrated with another software tool that assists in scheduling said patient's future visits to the practitioner, based on the predicting of tooth-movement behavior. For example, the tooth movement prediction software may predict that the patient will be in condition for placement of finishing wire in 7 weeks, based on the current tooth positions and the reference case history. This information is passed to a scheduling software program which then (1) schedules the patient to come in for a finishing wire in 7 weeks time, and (2) optionally issues any appropriate reminders.
As another alternative, a software tool is provided in the workstation for developing benchmarks personalized to the patient. For example, the patient may have a benchmark for filling in a gap between teeth due to an extraction that is closed in a first stage of treatment, after which the remaining teeth are moved slightly to finish positions. This first benchmark, closing the gap, may be identified in the patient database 38 (in field 154) and the benchmark quantified in terms of tooth position, in three dimensions. This tooth position could be simulated by interactive orthodontic treatment planning using virtual tooth models.
As another alternative embodiment, the workstation may include a software tool that gathers data related to the patient's treatment, such as for example, the benchmarks, initial tooth geometry, final tooth positions, patient characteristics, etc., and transfers this information and incorporates the information into the clinical benchmarking knowledge database 34 of
As yet another alternative, an artificial intelligence tool could be used for facilitating planning a selection of the treatment for the patient.
In yet another alternative, the knowledge base service is a smart service wherein a practitioner selects one or more variables the practitioner would like to track. When the selected variables in actuality approach or cross the desired standards based thresholds, the system would facilitate issuance of warnings, and would identify appropriate corrective-action options, and/or provide links to other information or knowledge bases which may further offer suggested corrective actions. Another feature of this invention is demand aggregation by one or more practitioners or groups of patients for more cost effective purchasing of treatment appliances, supplies, and services. The workstation facilitates archival services as well as knowledge based smart services.
Referring back to
From the above discussion, it will be appreciated that we have described a method for providing a service for facilitating care of a patient, the method comprising the steps of:
The method may optionally further includes the step of keeping a record of the treatment recommendations and the charge assessed to the practitioner.
In one possible embodiment of the method, the parameters or characteristics of importance to the patient, field 122, are associated with a relative importance ranking of the parameters. The method then uses a ranking of the matches into a preferred order list by taking into account the relative importance ranking of the parameters of importance to the patient. Additionally, the method includes the step of delivering treatment recommendations for the matches back to the practitioner taking into account the preferred order list. For example, the treatment recommendations may list the treatments for the patient in order according to their fit with the preferences of the patient.
The workstation preferably employs features that can be used during the course of treatment to monitor progress and provide suggestions for corrective action in the event that the treatment is not progressing as anticipated.
As the method of
If there is a match between the monitored response and the expected response, no adjustments are made to the treatment plan 184. However, when the monitored response does not substantially match the expected response, the method continues with step 186 of performing a root cause analysis for inadequate response. There are two possible outcomes from the root cause analysis. One is that there is a need for treatment adjustment, based upon results of the analysis pertaining to the initial diagnosis and the appliance utilized and the underlying premise. This phase of the root cause analysis involves examining the patient's biological response which may have been adverse, anatomical factors and associated constraints and characteristics, interference, ankylosis, bone density, lip pressure, etc. These factors are assigned weights to arrive at an aggregate weight; and probabilistic analysis is then applied to ascertain the future course of the treatment that is most likely to succeed. At the conclusion of this phase of the root cause analysis, step 188 is performed of adjusting the initial treatment plan and improving the predictions for response to the future treatment. The patient records (in the patient database 38) are updated to reflect the adjustment to the treatment plan as shown in step 172. Alternatively, the root cause analysis may indicate a lack of substantial adherence or non-compliance from the patient to the initial treatment plan. Then, step 192 of counseling the patient is performed, and the patient records are updated in step 172.
In yet another alternative embodiment, we have conceived of a unified workstation system for facilitating care of an orthodontic patient. The workstation includes a general purpose computer system 24 having a processor, memory and a user interface; and a database 38 containing information for facilitating care of a patient stored in the memory and accessible through the user interface. The information in the database 38 includes diagnosis information (field 111,
The workstation preferably also includes therapeutics information comprising treatment and delivery plans information, which may take a variety of forms including interactive treatment planning software.
The workstation also preferably includes care enterprise information comprising care monitoring and care management information, including information on laboratories, manufacturers, and suppliers for orthodontic treatment apparatus; information on the practitioner and the practitioner's assistants; and insurance coverage information for the patient. This care enterprise information may include links to the websites of the appliance manufacturers, their product catalogs and price sheets, etc.
The workstation also preferably includes records stored in memory of communications between the practitioner and patient (memoranda, letter, email, notes regarding patient visits, etc,) communications between the practitioner and one or more other practitioners, and communications between the practitioner and one or more laboratories, appliance manufacturers, and suppliers.
The workstation also includes a set of software tools enabling said practitioner to access the database 38 and use said database to facilitate the delivery and management of the care of the patient, such as by using the database 38 and the interactive treatment planning software to design a treatment plan and monitor progress of treatment.
The information and the software tools may include instructions aiding the practitioner in making a selection of a treatment plan that satisfies the patient's objectives including cost, duration, and esthetics.
In a preferred embodiment, the software tools comprise instructions designed to aid the practitioner in (a) monitoring and tracking the patient's progress in response to a treatment plan, and (b) in making adjustments to the treatment plan. The workstation may also include the clinical knowledge database in one possible embodiment of the invention, in which case the monitoring and adjustment of the treatment may be in reference to a benchmark case history from the clinical benchmark knowledge database.
As noted above, the instructions in the software may predict the course of treatment based on the clinical reference and use that prediction to assist in scheduling patient visits and sending out reminders for the visits to the patient.
In one possible embodiment, the software tools facilitate orthodontic treatment in which the treatment comprises using the same type of orthodontic appliances at different stages of treatment. Alternatively, the software tools may facilitate orthodontic treatment in which the treatment comprises using different types of orthodontic appliances at different stages of said treatment. For example, the patient may use aligning shells during an initial stage of treatment and finish the treatment with brackets and wires.
Just one practitioner may use the patient database and/or the clinical knowledge database, or, alternatively, the databases may be shared by more than orthodontic practices. In one application, the unified workstation is placed on an enterprise's intranet; while in another it is accessed over the Internet.
In other embodiments the clinical knowledge database could be maintained by a service provider and accessed by means of a subscription of the service provider.
In a preferred embodiment, the workstation provides links to the manufacturers and suppliers of orthodontic equipment and devices. The unified workstation may also facilitate supply chain management between the practitioner and the suppliers, such as by implementing commercially available supply chain management software. The information comprising the patient's therapeutic plan is exchanged with software tools of the suppliers in order to manage the supply of orthodontic devices to the practitioner.
Alternatively, the unified workstation further facilitates bidding services wherein a plurality of suppliers of orthodontic treatment apparatus submit bids to secure the practitioner's business pertaining to the patient's treatment plan. The bidding services may also be extended to the practitioners and to the patients.
As another possible embodiment of the invention, a product benchmarking service may be provided by the workstation, in which practitioners query the workstation for in formation, comparison data, reviews and other types of information regarding dental, orthodontic, prosthodontic and other types of products. In this embodiment, the workstation includes a database of this type of product information and provides and interface such as a query screen or prompts that allow the user to either directly or remotely access the product database.
In yet another embodiment of the invention, the orthodontic treatment prescribed to a patient is a hybrid treatment requiring different types of appliances, such as fixed appliances comprising brackets and arch wires from, for example, Ormco Corporation or OraMetrix, Inc. and removable appliances from, for example, Align Technology, Inc. at different periods of time during the course of the treatment. In a variant embodiment of the invention, the hybrid treatment comprises using different types of appliances during the same as well as different periods of time as appropriate to impart the most optimal treatment to the patient considering patient needs.
Although not specifically shown as a step in any of the figures for the sake of simplicity, it is to be understood that in all of the embodiments of the invention discussed herein, the unified workstation is designed such that all communications, transactions, database entries and access to patient health care information are secured for preserving confidentiality and privacy in accordance with the applicable state, federal, and other regulations and requirements. Security and privacy are achieved through the latest technology commercially available such as the use of passwords, encryption, etc.
While presently preferred embodiments have been described with particularity, departure from the details of the presently preferred embodiments may occur yet fall within the scope of the invention. This true scope is to be determined by reference to the claims.
This application is divisional application of prior application Ser. No. 10/429,074, filed May 2, 2003, pending, which is related to patent application filed on May 2, 2003, entitled “UNIFIED WORKSTATION FOR VIRTUAL CRANIOFACIAL DIAGNOSIS, TREATMENT PLANNING AND THERAPEUTICS”, Rohit Sachdeva et al, inventors, Ser. No. 10/429,123, now issued as U.S. Pat. No. 7,234,937, the entire contents of which are incorporated by reference herein; and to a patent application filed on May 2, 2003, inventors Rohit Sachdeva et al., entitled METHOD AND SYSTEM FOR INTEGRATED ORTHODONTIC TREATMENT PLANNING USING UNIFIED WORKSTATION, Ser. No. 10/428,461, now issued as U.S. Pat. No. 7,717,708, the entire contents of which are incorporated by reference herein. The instant application is also related to application Ser. No. 12/052,420, filed Mar. 20, 2008, pending, which is another divisional application of prior application Ser. No. 10/429,074, filed May 2, 2003, pending, the entire contents of which are incorporated by reference herein.
Number | Date | Country | |
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Parent | 10429074 | May 2003 | US |
Child | 13097038 | US |