SYSTEMS AND METHODS FOR EVALUATION OF SCOLIOSIS AND KYPHOSIS
Devices and systems for characterizing a condition of spinal deformities are contemplated. Mobile devices that incorporate inclinometers or accelerometers (e.g., a smart phone) are held securely in a supporting structure that renders it useful to characterize spinal deformities such as scoliosis and/or kyphosis. Supporting structures can include features that secure the mobile device (for example, chamfered surfaces, high friction surfaces, pliant projections, straps, hook and loop enclosures, tensioning devices, detents, etc.) in an upper portion and a lower portion that includes at least one, but preferably two or more rollers, and an interposing centrally placed notch dimensioned to permit the assembled device (supporting structure and mobile device) to span the width of a typical human spinal column. At least one roller includes an encoder (e.g., optical, mechanical, and/or magnetic encoders) that provide data related to their rotation or translation, thereby providing a measure of distance travelled as the device rolls, as well as direction. Such a support device can include additional features, such as additional sensors that are accessible by the mobile device, a centrally placed guide (such as a projected LED laser, illuminated filament, flexible bristle, etc.) that can be used to keep the assembled device in alignment during use, and supplementary battery power for the mobile device.
This application is a continuation of U.S. patent application Ser. No. 16/339,630, filed Apr. 4, 2019, which was nationalized from International Patent Application No. PCT/US2017/055433, filed Oct. 5, 2017, which claims priority to United States. Provisional Patent Application Ser. No. 62/404578, filed Oct. 5, 2016, United States. Provisional Patent Application Serial No. 62/514599, filed Jun2, 2017.
FIELD OF THE INVENTIONThe field of the invention is diagnostic devices and methods for use in orthopedics, particularly for conditions related to the spine.
BACKGROUNDThe background description includes information that may be useful in understanding the present invention. It is not an admission that any of the information provided herein is prior art or relevant to the presently claimed invention, or that any publication specifically or implicitly referenced is prior art.
Scoliosis is a deformity of the spine in which portions of the spinal column are displaced laterally. Similarly, kyphosis is a deformity of the spine in which portions of the spinal column are displaced anteriorly and dorsally to produce a curved or “humped” back. These deformities have a variety of causes and can appear at any stage of life. If such deformities reach dangerous magnitudes or are progressing, surgical intervention can be used to halt progression and correct or reduce the deformity. Alternatively, bracing treatments, which attempt to reduce or arrest any additional progression, are commonly used in skeletally immature patients who are mildly or moderately affected. In many instances a patient with mild symptoms may simply be monitored to observe if any progression occurs.
Over the last decade, a number of new less invasive surgical interventions have been proposed that seek to stop scoliotic and kyphotic progression without the need for spinal fusion. Such early surgical interventions are, however, only justifiable if significant curvature progression is anticipated. An important variable governing the incremental treatment of such conditions is an accurate progressive history of the spinal curvature. Thus, early detection methods that serve to identify scoliotic curves and kyphosis may greatly assist clinical prognosis and, consequently, improve treatment avenues. Such early detection methods will particularly help in reducing the number of patients presenting to a health professional for the first time with large curves for which a more aggressive treatment is required, considering that early detection at a milder stage could have been treated with a less invasive methods.
Typically the curvature of the spine produced by scoliosis is measured using a scoliometer, a specialized goniometer configured for this purpose. This measuring device spans the spine and is used by placing it over the spine on an individual who is bending forward at a 90° angle. The device provides an indication of the degree of left-to-right tilt as it is moved along the spinal column, which in turn provides a measure of the deformity. Proper use of such a device requires considerable training, as the patient must be positioned properly and the device held vertically throughout measurement. In addition results have to be read and entered manually. As a result reproducibility and accurate tracking of a patient over time are challenging.
Attempts have been made to automate at least portions of this process. In some instances mobile devices (such as smart phones) have been used, as these devices typically include accelerometers that can provide accurate tilt or incline measurements and allow it to act as an inclinometer. For example, U.S. Pat. No. 9,157,738 (to Labelle et al) discusses a device that supports a smart phone and incorporates a lower edge with a “cutout” that accommodates the normal dorsal projection of the vertebrae. All publications herein are incorporated by reference to the same extent as if each individual publication or patent application were specifically and individually indicated to be incorporated by reference. Where a definition or use of a term in an incorporated reference is inconsistent or contrary to the definition of that term provided herein, the definition of that term provided herein applies and the definition of that term in the reference does not apply. The smart phone's inclinometer provides a numeric readout of the degree of left-right tilt of the smart phone as the device is moved along the patient's spine. International Patent Application No. WO 2013/126352 (to Franko and Lev) describes a very similar device that is used in conjunction with an app that is run on the smart phone during the patient evaluation and provides a display that mimics the appearance of the traditional scoliometer. Neither device, however, includes measures to insure that they are being used properly. As such they provide, at best, a marginal improvement over traditional instruments. In addition, neither of these devices is useful in the characterization of kyphosis.
Thus, there is still a need for a device that provides simple, accurate, and reproducible measurement of scoliosis and/or kyphosis.
SUMMARY OF THE INVENTIONThe following description includes information that may be useful in understanding the present invention. It is not an admission that any of the information provided herein is prior art or relevant to the presently claimed invention, or that any publication specifically or implicitly referenced is prior art.
The inventive subject matter provides devices, systems and methods in which a mobile device that incorporates an inclinometer (for example, a smart phone equipped with an accelerometer) is held within a supporting structure that renders it useful to characterize spinal deformities such as scoliosis and/or kyphosis. Such a supporting structure can include features that secure the mobile device (for example, chamfered surfaces, high friction surfaces, pliant projections, straps, hook and loop enclosures, tensioning devices, detents, etc.) in an upper portion and a lower portion that includes at least one, but preferably two or more rollers or wheels and an interposing, centrally placed cutout or notch dimensioned to permit the assembled device span a typical spinal column. Such rollers or wheels can include encoders (for example, optical, mechanical, and/or magnetic encoders) that provide data related to their rotation, thereby providing a measure of distance travelled as the device rolls. Such a support device can include additional features, such as additional sensors that are accessible by the mobile device, a centrally placed guide (such as a projected LED laser, illuminated filament, flexible bristle, etc) that can be used to keep the assembled device in alignment during use, and supplementary battery power for the mobile device.
In use the assembled device is placed over the spinal column of a subject with the notch over the dorsal vertebral prominences and rolled along all or part of the length of the spinal column, with the accelerometer (e.g., 3 axis, 6 axis, 9 axis, etc) or other sensor (e.g., inclinometer, goniometer, etc.) of the mobile device providing data related to its deviation from a selected reference plane during this process. Measurements can be obtained from a subject in either or both of upright and bent forward (e.g., 90°, 45°, etc) positions, and can also be obtained during transition between these positions. Scoliosis can be determined by substantial (e.g. >10°) deviations from the horizontal plane when measurements are made with the subject bending forward at an approximately 90° angle from the waist. Kyphosis can be determined by substantial (e.g., >30° deviations from an expected angle relative to the vertical plane and/or abnormally sudden changes in the expected angle relative to the vertical plane while standing straight or in transition between standing and bent-forward positions.
The mobile device can include a program or application (e.g. an app) that records data from the accelerometer and/or other sensors (either provided by the mobile device or incorporated into the supporting structure). Such a program or application can display such data for manual recording or, in a preferred embodiment, provide such data to a database. In some embodiments the program or function can include a logic function that processes the data to provide a preliminary diagnosis and/or refer the subject to a medical professional for treatment. It should be appreciated that such processing occurs local to the mobile device (e.g., using mobile device CPU, memory, etc). Alternatively such logic functions can be performed using a separate and distinct CPU that is in communication with the database, for example a cloud based server, laptop device, tablet, etc. In some embodiments the mobile device's program or application can provide additional features, such as displaying information that provides instruction on use of the assembled device and/or providing feedback to a user regarding proper use of the assembled device.
Various objects, features, aspects and advantages of the inventive subject matter will become more apparent from the following detailed description of preferred embodiments, along with the accompanying drawing figures in which like numerals represent like components.
It should be noted that any language directed to a computer should be read to include any suitable combination of computing devices, including servers, interfaces, systems, databases, agents, peers, engines, controllers, or other types of computing devices operating individually or collectively. One should appreciate the computing devices comprise a processor configured to execute software instructions stored on a tangible, non-transitory computer readable storage medium (e.g., hard drive, solid state drive, RAM, flash, ROM, etc.). The software instructions preferably configure the computing device to provide the roles, responsibilities, or other functionality as discussed below with respect to the disclosed apparatus. In especially preferred embodiments, the various servers, systems, databases, or interfaces exchange data using standardized protocols or algorithms, possibly based on HTTP, HTTPS, AES, public-private key exchanges, web service APIs, known financial transaction protocols, or other electronic information exchanging methods. Data exchanges preferably are conducted over a packet-switched network, the Internet, LAN, WAN, VPN, or other type of packet switched network.
One should appreciate that the disclosed techniques provide many advantageous technical effects including providing inexpensive, yet accurate and reproducible, methods for early determination of spinal deformities. This in turn permits early and less invasive treatment of such conditions. It should also be appreciated that the low cost and portability of such a testing device permits wide adoption and supports the development of telemedicine applications.
The following discussion provides many example embodiments of the inventive subject matter. Although each embodiment represents a single combination of inventive elements, the inventive subject matter is considered to include all possible combinations of the disclosed elements. Thus if one embodiment comprises elements A, B, and C, and a second embodiment comprises elements B and D, then the inventive subject matter is also considered to include other remaining combinations of A, B, C, or D, even if not explicitly disclosed
The inventive subject matter contemplates devices, systems, and methods for assessing the condition of a spinal deformity. In some embodiments, a supporting structure for a spinal deformity testing device includes an upper portion for securing a computing device (e.g., smart phone, tablet, smart watch, etc), a lower portion with first and second sides opposed to one another, and a lower surface coupled to the first and second sides. Rotatably coupled to the lower surface are one or more rollers (preferably four), with at least a first roller positioned at or near the first side, and a notch interposed between the first and second sides. At least the first roller has an encoder, which preferably provides data related to the distance moved, direction, rolling path, speed, acceleration, relative elevation, or relative rotation (e.g., pivot) of the testing device as it is used.
In embodiments with more than one roller, it is preferred the rollers be evenly divided and positioned between the first and second sides (e.g., two rollers toward the first side, and two rollers toward the second side; one roller toward the first side, and one roller toward the second side, etc). It is contemplated for multi-roller embodiments that each roller has a fixed position on the support structure, and that the relative position of each roller to the other rollers (e.g., distance, angle, elevation, etc) are known and recorded in a computer memory of the support structure or the attached computing device (e.g., smartphone). In multi-roller embodiments with articulating rollers (e.g., caster-wheels, etc), calibration of the relative distance, angle, or elevation with respect to each other wheel is contemplated before using the testing device.
Preferred rollers include wheels (thin, thick, treaded, smooth, etc), though other rolling apparatus are contemplated (e.g., balls, bearings, drums, combinations, etc). It should be appreciated that the type of roller apparatus employed can provide added benefits. For example, where minimal device footprint or contact between the device and a subject (e.g., patient) is desired, thin wheels without tread (e.g., smooth) can be used. Wider wheels or drums can be employed when more contact with a subject is desired, for example where the rollers include massaging textures (e.g., tread, bumps, ridges, other patterns, etc) that relax the muscles around a patient's spine while using the testing device, favorably leading to a more accurate reading of the spine or a more relaxed, pliable subject. Similarly, it should be appreciated the rollers incorporate heating or cooling elements, to further relax or calm the subject. Such calming/relaxing features may be helpful when applying the testing device to irritable or tense patients (e.g., elderly, children, etc) or when applying the device to domestic or wild animals (e.g., Equidae (horses, etc.), Suidae (pigs, etc.), Bovidae (cattle, etc.), cats, dogs, etc). In the case of ball rollers (e.g., ball-in-socket), it should be appreciated that balls enable multidirectional rolling, and thus provide larger range of motion and increased maneuverability for devices that incorporate balls.
It is contemplated that sensors can be incorporated in testing devices and methods of the inventive subject matter. For example, sensors (e.g., accelerometer, gyroscope, magnetometer, camera, heat sensor, infrared sensor, pressure sensor, electro-optical sensor, X-ray sensor, acoustic sensor, inclinometer, goniometer, scoliometer, etc.) can be incorporated into the support structures described above, can be part of a computing device (e.g., smartphone, etc.), or can be added (e.g., physically coupled, communicatively coupled, etc) to the support structure or the computing device (e.g., via USB port, Bluetooth, etc). It should be for embodiments of the inventive subject matter designed to use sensor-rich smart phones, fewer sensors are needed in the support structure, thus reducing maintenance and cost of such support structures.
It is contemplated that the support structures and computing devices of the inventive subject matter are communicatively coupled (e.g., communication link). For example, a smartphone can have a wired communication link with the support structure (e.g., USB cable, etc) a wireless communication link (e.g., a wireless protocol, a Wi-Fi transmitter, a Wi-Fi receiver, a Bluetooth transmitter, a Bluetooth receiver, a ZigBee transmitter, a near field transmitter, a near field receiver, a radio frequency transmitter, a radio frequency receiver, an infrared transmitter, an infrared receiver, etc), or both.
The inventive subject matter further includes methods for characterizing a condition of a spinal deformity in a subject (e.g., person, animal, models, mechanical devices, etc). While the subject is in a first position (e.g., prone, standing, bent at 90°, tense, relaxed, etc), a testing device as described above is placed at a first starting position along the subject's spine (e.g., near the gluteal cleft), such that the notch of the testing device is centered on the spine. The testing device is then moved (e.g., pushed, rolled, etc) along the spine on the first roller. While moving the testing device along the spine, a first dataset is collected related to a distance traveled by the encoder associated with the first roller and at least one (preferably both) of (1) data related to a first lateral tilt of the testing device (or spine) or (2) data related to a first forward tilt of the testing device (or spine). While the subject is in a second position (e.g., prone, standing, bent at 90°, tense, relaxed, etc) that is different than the first position, the testing device is placed at a second starting position along the subject's spine (e.g., near the gluteal cleft), such that the notch of the testing device is centered on the spine. The testing device is then moved (e.g., pushed, rolled, etc) along the spine on the first roller. While moving the testing device along the spine, a second dataset is collected related to a distance traveled by the encoder of the first roller and at least one (preferably both) of (1) data related to a second lateral tilt of the testing device (or spine) or (2) data related to a second forward tilt of the testing device (or spine).
While the first and second datasets collected include data related to first and second distances traveled by the encoder, it should be appreciated additional data can be collected. For example, it is contemplated that the movement (e.g., direction, speed, acceleration, elevation) of the device is collected by encoders associated with rollers of the device. Viewed from another perspective, the device tracks its path of movement along the spine of the patient, such that the subject's spine is mapped in three dimensions and can be rendered in various 3D models.
At least part (preferably all) of the first and second datasets (e.g., data related to the first and second distance traveled and at least one (preferably both) of (1) the first and second lateral tilt or (2) the first and second forward tilt, other combinations, etc) are provided to a database. At least some (preferably all) of the data thus provided (e.g., the first or second lateral tilt, the first or second forward tilt, combinations, etc) is compared to a first stored value to determine the condition of the spinal deformity. A report related to the condition of the spinal deformity is generated, wherein the condition is one of (1) presence of a scoliosis deformity, (2) presence of a kyphosis deformity, or (3) absence of a scoliosis or kyphosis deformity in the subject. It is contemplated that presence of a scoliosis deformity is determined when either (preferably both) of the first or second lateral tilt exceeds a threshold (e.g., 5°, 7°, 8°, 9°, 10°, 11°, 12°, 13°, 14°, 15°, 20°, 25°, 30°), preferably 10°. In some embodiments, the lateral tilt of the subject's spine is measured again (e.g., third, fourth, fifth lateral tilt, etc), and a scoliosis deformity is determined when the average of the lateral tilts measured (e.g., first, second, third, fourth, fifth, etc) exceeds a threshold. It is contemplated that the lateral tilt of the subject's spine can be measured periodically (3/day, 2/day, 1/day, 4/week, 3/week, 2/week, 1/week, 4/month, 3/month, 2/month, 1/month, etc). In such embodiments, it is contemplated the data analyzed can be limited to the most recent measurements/readings be analyzed (e.g., prior week, prior 3 days, prior 2 days, last 5 readings, last 4 readings, last 3 readings, last 2 readings, etc), or weights be applied to at least some of the measurements/readings (e.g., higher weight for last 3 readings, last 2 readings, last reading, lower weights for oldest 5 readings, oldest 3 readings, oldest reading, etc).
In a similar fashion, presence of a kyphosis deformity is determined when either (preferably both) of the first or second forward tilt exceeds a threshold (e.g., 20°, 25°, 27°, 28°, 29°, 30°, 31°, 32°, 33°, 34°, 35°, 40°, 45°, 50°), preferably 30°. It is contemplated the forward tilt of the spine can be measured further, the measurements/readings can be averaged, or the measurements/readings can be weighted as described above. In preferred embodiments, at least some (preferably all) of the lateral tilt measurements and the forward tilt measurements are used by the mobile device (or cloud server) to construct a model (e.g., digital) of the subject's spine. In preferred embodiments, a digital image of the subject's back (e.g., dorsal view) is acquired and used in part to determine the condition of the spinal deformity or to construct a model of the spine.
In some embodiments the testing device instructs the subject to seek medical attention when the report indicates a scoliosis deformity or a kyphosis deformity. The device can also transmit the report to a medical professional. Reports generated by the device can further include or rely upon a relationship between the first distance traveled and at least one of the first lateral tilt or the first forward tilt, preferably both. Further, the reports can include or rely upon a relationship between the second distance traveled and at least one of the second lateral tilt or the second forward tilt, preferably both. In preferred embodiments, the report incorporates all, or at least some, of the datasets collected by the device for a specific subject over a specified time period.
One embodiment of the inventive concept is shown in
Such rollers can include encoding features (such as optical, mechanical, and/or magnetic encoders, not pictured) that provide quantitative information regarding the rotation of the wheel or roller, and thereby provide a measure of distance travelled by device 100. This in turn provides a clinician with the location of the deformity along the spinal column. Such encoders can also provide information related to the speed and/or acceleration of the assembled device when in use. Such data can be used to monitor use of device 100 and insure that it is being used appropriately (for example, by providing an alarm or other warning when speed and/or acceleration fall outside of predetermined limits). Centrally placed between wheels 115 and 116 along lower portion 114 is notch 117, which is shaped to permit easy passage of a typical spinal prominence during use. Notch 117 has an arcuate shape, and it is contemplated such notches typically have a height of from about 0.5 cm to about 2.5 cm. Device 100 further has guide feature 118 centrally placed immediately above notch 117. Guide feature 118 can be seen as a raised arrow shape, but can also or alternatively include a laser diode or similar device (for example, a device that provides an orienting and/or guiding optical or visual effect), which projects a beam of light downwards towards the spine during use, and aids in positioning of device 100.
It should be appreciated that providing positional information in association with lateral and/or forward tilt in devices and methods of the inventive concept provides substantial benefits not realized in the prior art. For example, association of distance traveled along the spine with a degree of lateral and/or forward tilt can provide a clinician with information related to the position of a spinal deformity, and complements traditional photographic and radiographic information. In addition, speed and/or acceleration data collected during use can be utilized to verify proper utilization of the assembled device and to insure the integrity of the gathered data. For example, speed data indicating that the assembled device is being moved along the spine too quickly (e.g. when data related to the rate of roller or wheel rotation exceeds a predetermined value) can trigger an alarm or warning to the user (e.g. a prompt to repeat the measurement). Alternatively, software running on the mobile device can refuse to enter data from an assembled device until it used properly. To aid in this, such software can display a speed indication while the assembled device is in use.
As noted above, lower portion 114 of supporting structure 110 can include additional sensors, circuitry, and/or a battery. Suitable additional sensors include a high resolution accelerometer, a temperature sensor, an infrared sensor, pressure sensor, and/or a camera. Such sensors can be used to replace, supplement, and/or calibrate sensors provided on mobile device 120. For example, an accelerometer on lower portion 114 of supporting structure 110 can be used to verify or correct (e.g. through calibration) an accelerometer of mobile device 120. This advantageously permits the use of a variety of mobile devices from different manufacturers, which may utilize accelerometers and/or other sensors with different ranges and/or degrees of sensitivity.
Alternatively or in combination, sensors of supporting structure 110 can be used to verify data collected by sensors of mobile device 120. As shown support structure 110 can also include cable 130 that interfaces with a data and/or power port of mobile device 120. It should be appreciated, however, that other mechanisms (e.g. WiFi, Bluetooth, near field transmission) can be used to transfer data between supporting structure 110 and mobile device 120.
Both
In another embodiment, depicted in
While the embodiments shown in
Similarly,
As noted above, embodiments of the inventive concept can include software (such as programs or applications) that are configured to run on the mobile device and serve to assist a user in performance of the test and/or recording of the results. An example of a flow diagram for such software is shown in
At the completion of the first portion of the test the subject is instructed to assume the next test position (in this instance, standing) and the process is repeated. In preferred embodiments, when testing is taken of a subject in a standing position, the device is placed at the at the base of the subject's neck (e.g., T1 of thoracic vertebrae, etc) and moved downward along the subject's spine toward the gluteal cleft (see, e.g.,
As noted above, embodiments of the inventive concept can include software that applies logic to data gathered as shown in
An additional example flow chart for such processes is depicted in
As shown in
As shown in
Device 1100 further includes printed circuit board 1150, which includes circuitry required to communicate with and record data from encoders (not pictured) in wheels 1110a-b and 1120a-b, as well as relay such data to mobile device 1130 (e.g., memory, microcontroller unit, CPU, etc). In preferred embodiments, printed circuit board (PCB) 1150 further includes a motion sensor (e.g., accelerometer, inclinometer, scoliometer, etc.), an LED (e.g., to provide a guide light for applying the device to a patient), or a wireless communication transmitter or receiver (e.g., Bluetooth, NFC, etc, to provide communication with mobile device 1130). The sensors integrated in such PCBs (e.g., motion sensor, etc) can complement or replace the function of a motion sensor of mobile phone 1130 used in device 1100. Such sensors (e.g., motion sensor) can serve to standardize performance of device 1100 across different models of mobile devices, which potentially use a disparate assortment of internal hardware and software with disparate performance, in an effort to improve or ensure adequate precision.
Testing or scanning of a subject can be performed with the subject in a bent-forward position (i.e. at approximately 90° position (as shown in
During use of device 1210, a green indicator on the display indicates that testing should continue, whereas a red indicator on the display indicates that at least a portion of the test needs to be repeated. At the completion of the first portion of the test the subject is instructed to assume the next test position (in this instance, standing, e.g.,
As noted above, the Cobb angle is a commonly used clinical parameter used to diagnose scoliosis and characterize it progress and/or response to treatment. In prior art practice this figure is determined from X-ray images taken while the subject is standing. A typical prior art method for determining Cobb angle is shown in
In some embodiments of the inventive concept, data obtained from an assembled testing device (e.g.,
Kyphosis, an exaggerated curve of the thoracic spine (also known as “dowager's hump,” compare
As noted above, embodiments of the inventive concept can include software (such as programs or applications) that are configured to run on the mobile device and serve to assist a user in performance of the test and/or recording of the results. In some embodiments the software can provide a user interface that assists in performing an assessment using the assembled testing device. Such an interface can, for example, provide virtual controls for various device functions, result storage and access to stored results, modification of device setting, progress and/or status of an examination performed by the device, and/or summaries of scan results. It is contemplated that mobile applications of the inventive subject matter can be installed on mobile devices (e.g., smartphone), for example by installing the applications from a third party source (e.g., iPhone Appstore, Google Play, etc) or as a direct install from supporting structures of the inventive subject matter.
Scanning state 1700b is accessible while the device is used to scan the spinal column of a patient, and has elements largely similar to displays 700a-b and 800a-b of
Results state 1700c is accessible to the user once a scan is completed, or if a scan history is selected by the user. The user interface of results state 1700c includes map 1720, spinal features 1722, and result summary 1724. As depicted, map 1720 depicts a model of the patient's spine with anomalies indicated where detected. It is contemplated that the model can be two dimensional, three dimensional, or four dimensional, and can be manipulated (rotated, turned, selected, zoom in/out, etc) by the user. Spinal features 1722 displays relevant data from the scan of the patient's spine. For example, as depicted spinal features 1722 indicates the total length of the spine as scanned, as well as the lateral tilt angles of the spine that surpass a threshold indicative of scoliosis (e.g., 0°-5° normal, 5°-10° moderate, >10° serious, etc), along with the location of the angle along the spine (e.g., at 18.1 cm from base, at 27.1 cm from base, etc). It should be appreciated that spinal features 1722 can include as many types of feature and related information as detected for a spine (e.g., lateral tilt angle, forward tilt angle, spinal length, location along spine, etc; more than 2, 3, 5, 7, or 10 features, etc). Result summary 1724 presents summary information to the user that describes the scan. For example, result summary 1724 as depicted presents an anonymized patient identification (e.g., S3D_1111_170419_142508), the date the spinal scan was taken (e.g., hour, month, day, year, etc), as well as a conclusion reached based on analysis of the spinal scan data (e.g., moderate threshold exceeded, serious threshold exceeded, normal, etc).
Additional thresholds for lateral tilt angles to identify scoliosis can be entered by a user, or autopopulated based on data (e.g., experimental, clinical, demographic, patient specific, etc) by devices of the inventive subject matter, proprietary servers, or third-party databases. For example, normal ranges can be 0°-1°, 0°-3°, 0°-5°, 0°-7°, 0°-10°, 0°-12°, 1°-3°, 1°-5°, 1°-7°, 1°-10°, 1°-12°, 3°-5°, 3°-7°, 3°-10°, 3°-12°, 5°-7°, 5°-10°, 5°-12°, 7°-10°, 7°-12°, 10°-12°, etc. Likewise, moderate ranges can be 3°-56°, 3°-7°, 3°-10°, 3°-12°, 3°-15°, 3°-17°, 5°-7°, 5°-10°, 5°-12°, 5°-15°, 7°-10°, 7°-12°, 7°-15°, 7°-17°, 10°-12°, 10°-15°, 10°-17°, 12°-15°, 12°-17°, 15°-17°, etc. Further, severe ranges can be 7°-10, 7°-12°, 7°-15°, 7°-17°, 7°-20°, 7°-22°, 7°-25°, 10°-12°, 10°-15°, 10°-17°, 10°-20°, 10°-22°, 10°-25°, 12°-15°, 12°-17°, 12°-20°, 12°-22°, 12°-25°, 15°-17°, 15°-20°, 15°-22°, 15°-25°, 17°-20°, 17°-22°, 17°-25°, 20°-22°, 20-25°, 22°-25°, etc.
Similarly, additional thresholds for forward tilt angles to identify kyphosis can be entered by a user, or autopopulated based on data (e.g., experimental, clinical, demographic, patient specific, etc) by devices of the inventive subject matter, proprietary servers, or third-party databases. For example, normal ranges can be 0°-11°, 0°-13°, 0°-15°, 0°-17°, 0°-20°, 0°-22°, 0°-23°, 0°-25°, 0°-27°, 0°-30°, 0°-32°, 10°-13°, 10°-15°, 10°-17°, 10°-20°, 10°-22°, 10°-23°, 10°-25°, 10°-27°, 10°-30°, 10°-32°, 13°-15°, 13°-17°, 13°-20°, 13°-22°, 13°-23°, 13°-25°, 13°-27°, 13°-30°, 13°-32°, 15°-17°, 15°-20°, 15°-22°, 15°-23°, 15°-25°, 15°-27°, 15°-30°, 15°-32°, 17°-20°, 17°-22°, 17°-23°, 17°-25°, 17°-27°, 17°-30°, 17°-32°, 20°-22°, 20°-23°, 20°-25°, 20°-27°, 20°-30°, 20°-32°, 23°-25°, 23°-27°, 23°-30°, 23°-32°, 25°-27°, 25°-30°, 25°-32°, 27°-30°, 27°-32°, 30°-32°, etc. Likewise, moderate ranges can be 10°-13°, 10°-15°, 10°-17°, 10°-20°, 10°-22°, 10°-23°, 10°-25°, 10°-27°, 10°-30°, 10°-32°, 10°-33°, 10°-35°, 10°-37°, 10°-40°, 13°-15°, 13°-17°, 13°-20°, 13°-22°, 13°-23°, 13°-25°, 13°-27°, 13°-30°, 13°-32°, 13°-33°, 13°-35°, 13°-37°, 13°-40°, 15°-17°, 15°-20°, 15°-22°, 15°-23°, 15°-25°, 15°-27°, 15°-30°, 15°-32°, 15°-33°, 15°-35°, 15°-37°, 15°-40°, 17°-20°, 15°-22°, 17°-23°, 17°-25°, 17°-27°, 17°-30°, 17°-32°, 17-33°, 17-35°, 17°-37, 17°-40°, 20-22°, 20°-23°, 20°-25°, 20°-27°, 20°-30°, 20°-32°, 23°-25°, 23°-27°, 23°-30°, 23°-32°, 20°-33°, 20°-35°, 20°-37°, 20°-40°, 25°-27°, 25°-30°, 25°-32°, 25°-33°, 25°-35°, 25°-37, 25°-40°, 27°-30°, 27°-32°, 27°-33, 27°-35°, 27°-37°, 27°-40°, 30°-32°, 40°, 35°-37°, 35°-40°, 37°-40°, etc. Further, severe ranges can be 17°-20°, 17°-22°, 17°-23°, 17°-25°, 17°-27°, 17°-30°, 17°-32°, 17°-33°, 17°-35°, 17°-37°, 17°-40°, 17°-42°, 17°-43°, 17°-45°, 17°-47°, 17°-50°, 17°-52°, 17°-53°, 17°-55°, 17°-57°, 17°-60°, 20°-22°, 20°-23°, 20°-25°, 20°-27°, 20°-30°, 20°-32°, 23°-25°, 23°-27°, 23°-30°, 23°-32°, 20°-33°, 20°-35°, 20°-37°, 20°-40°, 20°-42°, 20°-43°, 20°-45°, 20°-47°, 20°-50°, 20°-52°, 20°-53°, 20°-55°, 20°-57°, 20°-60°, 25°-27°, 25°-30°, 25°-32°, 25°-33°, 25°-35°, 25°-37°, 25°-40°, 25°-42°, 25°-43°, 25°-45°, 25°-47°, 25°-50°, 25°-52°, 25°-53°, 25°-55°, 25°-57°, 25°-60°, 27°-30°, 27°-32°, 27°-33°, 27°-35°, 27°-37°, 27°-40°, 27°-42°, 27°-43°, 27°-45°, 27°-47°, 27°-50°, 27°-52°, 27°-53°, 27°-55°, 27°-57°, 27°-60°, 30°-32°, 30°-33°, 30°-35°, 30°-37°, 30°-40°, 30°-42°, 30°-43°, 30°-45°, 30°-47°, 30°-50°, 30°-52°, 30°-53°, 30°-55°, 30°-57°, 30°-60°, 32°-33°, 32°-35°, 32°-37°, 32°-40°, 32°-42°, 32°-43°, 32°-45°, 32°-47°, 32°-50°, 32°-52°, 32°-53°, 32°-55°, 32°-57°, 32°-60°, 33°-35°, 33°-37°, 33°-40°, 33°-42°, 33°-43°, 33°-45°, 33°-47°, 33°-50°, 33°-52°, 33°-53°, 33°-55°, 33°-57°, 33°-60°, 35°-37°, 35°-40°, 35°-42°, 35°-43°, 35°-45°, 35°-47°, 35°-50°, 35°-52°, 35°-53°, 35°-55°, 35°-57°, 35°-60°, 37°-40°, 37°-42°, 37°-43°, 37°-45°, 37°-47°, 37°-50°, 37°-52°, 37°-53°, 37°-55°, 37°-57°, 37°-60°, 40°-42°, 40°-43°, 40°-45°, 40°-47°, 40°-50°, 40°-52°, 40°-53°, 40°-55°, 40°-57°, 40°-60°, 45°-60°, 50°-60°, 55°-60°, >60°, etc.
It should be appreciated that results state 1700c can further include additional information, such as identifying the user/operator of the device during the scan, identifying that the scan data or results are inconsistent with other scan data or results for a specific patient, or an indication that additional analysis is available or required. For example, results state 1700c can further instruct a user or a patient to seek medical attention or schedule an appointment with a medical professional (e.g., based on patient's medical insurance, selected from trusted healthcare providers, in-network providers, healthcare provider expertise, location of patient or device relative to healthcare provider, availability of healthcare provider, facilities required for treatment of patient, facilities available at healthcare provider, etc). Results state 1700c can also direct a user/patient to further comments made by a healthcare professional regarding the spine scan data, or whether the patient has completed the instructions issued by the mobile application.
It should also be appreciated that the results of scans that have diagnostic value (e.g., indicate scoliosis, kyphosis, other spinal deformity), or all scans, can be forwarded to relevant databases, for example databases maintained by healthcare providers for a particular subject, veterinary care providers, athletic organizations, academic organizations, etc. Similarly, mobile applications of the inventive subject can receive relevant subject related data from such third party databases (e.g., healthcare providers for a particular subject, veterinary care providers, athletic organizations, academic organizations, etc). It should also be appreciated that mobile applications of the inventive subject matter forward all collected and received data to proprietary cloud based servers, for further data analysis (e.g., big data analysis, identifying false positives, false negatives, refining algorithms for identifying spinal deformities, for identifying other spinal conditions). In such proprietary embodiments, it is contemplated such compilation of data and big data analysis can be made available to third parties as a subscription service.
In another embodiment of the inventive concept, differences in travel between the left wheel or roller and the right wheel or roller can be utilized by the testing device to evaluate images (such as photographs or radiographs) of a test subject. In such an embodiment the testing device can be centered over a portion of the image representing the spinal column and moved along its length. Lateral curvature of the spinal column represented in the image results in differential rates of movement between the left and right wheels or rollers. For example, an image displaying a spine that curves to the right would result in a left wheel or roller traveling a shorter distance than a right wheel or roller as the testing device is moved over that portion of the image. Such data can be gathered from encoders incorporated into the wheels or rollers (as described above). These differences can be used to calculate the Cobb angle typically used to characterize scoliotic deformation. In this way a testing device of the inventive concept can be used to derive clinically useful information from current and archived data when the patient is not immediately available. It should be appreciated that an application or program running on a mobile device incorporated into the assembled testing device can have a mode for testing live subjects and a separate mode for characterizing such stored data.
It should also be appreciated that use of balls (e.g., ball-in-socket) as rollers further allows the direction of the device to be mapped or recorded by the device. For example, while use of wheels requires detecting differences in speed, acceleration, and distance traveled between the wheels on the device in order to discern the movement of the device, tracking the roll of a ball allows the device to directly tell which direction the each ball (e.g., corner of the device) move at any given moment.
As noted above, many mobile devices (for example, smart phones, tablets, etc.) include sensors other than accelerometers that can be utilized in conjunction with a supporting structure to aid in assessing scoliosis and/or kyphosis. For example, magnetic field sensors can be used to aid in orientation of the testing device and/or in sensing the passage of magnetic encoders. Infrared sensors (such as proximity sensors) can be used to determine that the testing device is being utilized on an actual test subject, thereby improving the quality of the testing database by preventing the submission of falsified data. Similarly, spectral analysis of image data gathered as part of the testing procedure can be used to verify that the same subject identifier is not being utilized for multiple subjects, or that the same test subject does not appear under different identifications.
It should also be appreciated that while the devices, systems, and methods of the inventive subject matter are presumed useful to detect spinal disorders in patients (e.g., people), it is also contemplated that the inventive subject matter can be used to characterize the condition of spinal deformities in animals (e.g., vertebrates), as well as used on model or dummy devices to train provide training or instruction to health care workers. It should also be appreciated that the inventive subject matter can also be applied to detect anomalies in mechanical structures (e.g., tension in couplings, buckling, mechanical fatigue in rods, etc) or robotic limbs/appendages (e.g., robotic arm, etc). In such embodiments, it is anticipated that forward tilting, lateral tilting, and traveled path tolerances will be informed based on the mechanical properties the material or structure that is evaluated.
Although described above in terms of incorporating a mobile device, in some embodiments of the inventive concept the supporting structure can include a display that permits direct use of the supporting structure to carry out the above described analytical functions. In such embodiments the supporting structure can include an internal CPU and/or provide communications capability with an external CPU. Such an external CPU can include a CPU of a mobile device in communication with but not coupled to the supporting structure, a laptop computer, a tablet computer, a wearable computer, a desktop computer, and/or a computer at a physically separate location. Communication with such an external CPU can be provided by a wired connection (e.g. USB or Firewire cable) or a wireless connection. Suitable wireless connections and/or protocols include WiFi, Bluetooth, infrared, radio, and microwave communications. In some embodiments communication with such an external CPU can be provided over the internet, for example using a commercial ISP or wireless service provider.
It should be apparent to those skilled in the art that many more modifications besides those already described are possible without departing from the inventive concepts herein. The inventive subject matter, therefore, is not to be restricted except in the spirit of the appended claims. Moreover, in interpreting both the specification and the claims, all terms should be interpreted in the broadest possible manner consistent with the context. In particular, the terms “comprises” and “comprising” should be interpreted as referring to elements, components, or steps in a non-exclusive manner, indicating that the referenced elements, components, or steps may be present, or utilized, or combined with other elements, components, or steps that are not expressly referenced. Where the specification claims refers to at least one of something selected from the group consisting of A, B, C . . . and N, the text should be interpreted as requiring only one element from the group, not A plus N, or B plus N, etc.
Claims
1. A supporting structure for a testing device, comprising:
- an upper portion configured to secure a mobile device comprising a CPU; and
- a lower portion having a first side and a second side opposed to one another and a lower surface coupled to both the first side and the second side, wherein the lower surface comprises a first roller positioned at or near the first side, a second roller positioned at or near the second side, and a notch interposed between the first roller and the second roller; and
- a first encoder coupled to either the first roller or the second roller and that is configured to communicatively couple to the CPU.
2. The supporting structure of claim 1, wherein the first roller is coupled to the first encoder and the second roller is coupled to a second encoder that is configured to communicatively couple to the CPU.
3. The supporting structure of claim 1, further comprising a sensor configured to communicatively couple to the mobile device, wherein the sensor is selected from the group consisting of an accelerometer, a gyroscope, a magnetometer, a camera, a heat sensor, an infrared sensor, and a pressure sensor.
4. The supporting structure of claim 1, wherein the first encoder is configured to provide data related to the distance moved, speed, or acceleration of the supporting structure when the supporting structure is rolled on the first roller.
5. The supporting structure of claim 17, wherein either of the first roller or the second roller comprises a plurality of wheels.
6. The supporting structure of claim 1, comprising a hinge joining the upper portion to the lower portion.
7. The supporting structure of claim 1, further comprising an alignment feature positioned centrally along the notch.
8. The supporting structure of claim 7, wherein the alignment feature comprises an illuminating device oriented to project a beam through a central portion of the notch along a line perpendicular to the plane of the lower surface.
9. A testing device for determination of a spinal deformity in a subject, comprising:
- a mobile device comprising an accelerometer and a CPU; and
- a supporting structure comprising an upper portion configured to secure the mobile device, a lower portion having a first side and a second side opposed to one another and a lower surface coupled to both the first side and the second side, wherein the lower surface comprises a first roller positioned at or near the first side, a second roller positioned at or near the second side, and a notch interposed between the first roller and the second roller; and
- a first encoder coupled to either the first roller or the second roller and that is communicatively coupled to the CPU.
10. The testing device of claim 9, wherein the first roller is coupled to the first encoder, and the second roller is coupled to a second encoder that is communicatively coupled to the CPU.
11. The testing device of claim 9, wherein the supporting structure comprises a sensor that is communicatively coupled to the CPU.
12. The testing device of claim 11, wherein the sensor is selected from the list consisting of an accelerometer, a gyroscope, a magnetometer, a camera, a heat sensor, an infrared sensor, and a pressure sensor.
13. The testing device of claim 9, comprising a communication link configured to provide communication between the supporting structure and the mobile device.
14. The testing device of claim 13, wherein the communication link is selected from the group consisting of a cable and a wireless communication methodology, wherein the wireless communication methodology comprises one of a wireless protocol, a WiFi transmitter, a WiFi receiver, a Bluetooth transmitter, a Bluetooth receiver, a ZigBee transmitter, a near field transmitter, a near field receiver, a radio frequency transmitter, a radio frequency receiver, an infrared transmitter, or an infrared receiver.
15. The testing device of claim 9, wherein the first encoder is configured to provide data related to the distance moved by the supporting structure when the supporting structure is rolled on the first roller.
16. The testing device of claim 9, wherein either of the first roller or the second roller comprises a plurality of wheels.
17. The testing device of claim 9, comprising a hinge joining the upper portion to the lower portion.
18. The testing device of claim 17, wherein the hinge comprises at least one stop.
19. The testing device of claim 17, wherein the hinge is configured to secure the top portion at a first position relative to the lower portion and at a second position relative to the lower portion, wherein the first position and the second position are normal to one another.
20. The testing device of claim 9, comprising an alignment feature positioned centrally along the notch.
21. The testing device of claim 20, wherein the alignment feature is an illuminating device oriented to project a beam through a central portion of the notch along a line perpendicular to the plane of the lower surface.
Type: Application
Filed: Jul 28, 2021
Publication Date: Nov 18, 2021
Inventors: Yuk Lun TSANG (Kowloon), Lut Hey CHU (Kowloon), Johnson Yiu-Nam LAU (Houston, TX)
Application Number: 17/387,112