This invention relates to respiratory therapy devices and more particularly to devices and methods encouraging patients to properly utilize incentive spirometers.
A commonly recommended technique for post-operative care utilizes incentive spirometers to exercise the lungs to enhance respiration capabilities of patients. As noted by many including Weinstein et al. in U.S. Pat. No. 6,238,353, it is often difficult to monitor actual usage of an incentive spirometer by a patient. Patient forgetfulness is a major concern. Poor incentive spirometer compliance can lead to various clinical problems such as atelectasis, pneumonia or other costly postoperative pulmonary complications in patients.
It is therefore desirable to encourage actual and effective use of incentive spirometers without interfering with the accuracy of the manner in which the device is utilized.
An object of the present invention is to remind a patient to engage in successive sessions utilizing a device such as an incentive spirometer.
Another object of the present invention is to ensure that a patient achieves sufficient inspiratory target volumes during each session.
This invention features a method for configuring and/or utilizing an incentive spirometer to interact with a user during a series of sessions, the incentive spirometer having a piston that is movable within a chamber by user inhalation. The method includes mounting a sensor to detect movement of the piston, generating a perceptible prompt to a user to encourage use of the incentive spirometer at preselected intervals relative to the series of sessions, and deactivating the perceptible prompt only after the sensor detects that the piston has at least reached a preselected threshold.
In one embodiment, the perceptible prompt includes an audible sound. In another embodiment, the perceptible prompt includes a visual signal, such as a blinking light. In some embodiments, the perceptible prompt includes a tactile signal, such as a vibratory sensation. In certain embodiments, the perceptible prompt include a combination signals. In another embodiment, generating the perceptible prompt includes activating a prompt on a remote device (such as a mobile device capable of being carried by the user and/or a clinician or other health care professional), and/or reading data output and/or recording data output. In a number of embodiments, the method further includes storing detected piston movement in a storage medium as retrievable data. In some embodiments, the sensor is removably mounted to the incentive spirometer such as being integrated into a removable clamp. In certain embodiments, the perceptible prompt is deactivated only after the user breathes to sufficient inspiratory target volume into the incentive spirometer. In certain embodiments, the system further includes an opaque housing that covers at least a portion of the incentive spirometer housing. In some embodiments, the sensor is capable of detecting optical radiation transmitted through the housing of the incentive spirometer, and the opaque housing is secured to a support base and is positioned to shield at least a portion of environmental optical radiation surrounding the incentive spirometer housing.
This invention also features a system to enhance compliance for a user of an incentive spirometer having a piston that is movable within a chamber by user inhalation. The system includes a sensor mountable on the incentive spirometer to detect movement of the piston, and an alarm device for generating a perceptible prompt to the user to encourage use of the incentive spirometer. The system further includes a processor capable of periodically activating the alarm device and then deactivating the alarm device only after the sensor detects that the piston has at least reached a preselected threshold.
In what follows, preferred embodiments of the invention are explained in more detail with reference to the drawings, in which:
This invention may be accomplished by a system and method for configuring and/or utilizing an incentive spirometer to interact with a user during a series of sessions, the incentive spirometer having a piston that is movable within a chamber by user inhalation. The method includes mounting a sensor to detect movement of the piston, generating a perceptible prompt to a user to encourage use of the incentive spirometer at preselected intervals relative to the series of sessions, and deactivating the perceptible prompt only after the sensor detects that the piston has at least reached a preselected threshold.
In one construction, a system according to the present invention includes a sensor mountable on the incentive spirometer to detect movement of the piston, and an alarm device for generating a perceptible prompt, such as an audible sound, to the user to remind and encourage use of the incentive spirometer. The system further includes a processor capable of periodically activating the alarm device, such as when a session should be commenced, and then deactivating the alarm device only after the sensor detects that the piston has at least reached a preselected threshold inspiratory volume, such as after the user inhales with sufficient inspiratory target volume from the device during that session, and successfully inhales one or more times to a predetermined volume.
In preferred constructions, the patient reminder alarm only turns off when the patient utilizes the incentive spirometer as prescribed by a healthcare professional. In certain constructions, the system includes an opaque housing that covers at least a portion of the incentive spirometer housing, as discussed in more detail below in relation to
System 10,
Sensor 12 senses movement of a piston P within a chamber C on an incentive spirometer 20 when a user inhales through mouth piece MP and flexible tubing T into chamber C defined by housing H of the incentive spirometer 20; the inhaled breath displaces a piston P within chamber C. In some constructions, the incentive spirometer 20 has an indicator I which provides inspiratory flow feedback to a patient or other user during inhalation. In one construction, signal 40 represents a modulated infrared signal utilized to detect movement of piston P as described below. A conventional marker M on housing H can be manually adjusted to visually indicate a desired minimum movement level for the piston P. Signal 42 represents wireless communication between system 10 and a computing device such as Bluetooth Low Energy transmission to and from a laptop LP. The laptop LP or other computing device typically executes data collection instructions as desired by a healthcare professional.
Sessions for a user to utilize the incentive spirometer 20 and the timing for sampling periods/wake-up rate for data acquisition from sensor 12 typically are set by a healthcare professional at a selected rate such as once an hour. In some constructions, adjustment of parameters in system 10 and/or laptop LP require a password, a special key or a special tool so that only a healthcare professional or an authorized person can make such adjustments.
At the start of a session, alarm device 16 begins beeping or generates another type of perceptible prompt to the user. In certain constructions, the alarm device 16 communicates with a smart phone, a tablet or other mobile device of a user to produce a vibration or other tactile sensation, a sound as an auditory prompt, and/or a visible message or visual cue to induce the user to begin the session. In another construction, the vibratory or tactile prompt is integrated into the device attached to the incentive spirometer.
In one construction, time-stamped data is stored in a storage medium such as a flash drive until required for upload. The processor 14 and/or laptop LP typically are maintained in “sleep mode” when possible to reduce power consumption.
In one construction, circuit 100 represents the architecture of components within a clamp system 200 according to the present invention,
A light source 210 directs optical radiation 211 through the tube and a photo sensor 212 identifies disruption of the optical radiation 211 when the piston passes between the light source 210 and the detector 212. In some constructions, one or more of the gripping surfaces 220, 222 and 224 are formed from an optically opaque material, such as a high-friction rubber compound, which also serves to block extraneous light from interfering with readings by detector 212. One or more of a power source, a microcontroller, a control unit and an alarm device, such as components 120, 130, 140 and 150 of
In some constructions according to the present invention, a microcontroller takes the voltage inputs of a sensor for incentive spirometer piston movement and then outputs a signal and records all events, as well as silences an alarm once compliance has been achieved. Flow chart 300,
For incentive spirometers having chamber walls that are transparent to infrared (IR) light, the piston could be detected as it travels past the sensor. Given this signal state and history, the embedded computer can determine approximate placement of the piston along its travel axis. IR light emitters were considered due to wide availability and inexpensive cost of IR-specific sensors. To test chamber transparency to IR and to measure the effect of IR reflected back by piston movement, an IS chamber was placed within apparatus 600,
Hardware components of a typical system according to the present invention include selection of an incentive spirometer, a mechanical mount for detection equipment, an optical emitter, detection system interface electronics, embedded acquisition and recording microcontroller computer, network interface for logging data transfer, beeper for patient audio notification, mode configuration pushbutton, mode configuration LED indicator, power supply, data logging transfer and storage computer. Two modules of system software are utilized: software for an embedded acquisition computer and software for data download computer such as a laptop computer.
The embedded acquisition and recording microcontroller computer was considered—configuring it with a beeper (reminder alarm), an LED, and a button. This enables configuration of certain aspects of the device with the button, receive information via LED blink patterns, and use the beeper to indicate state to the clinician, patient, or other. For system 10,
Operation of one construction according to the present invention is shown in flow chart 350,
After correct bytes are received, arrow 418, the system enters “commandMode” and waits for the correct command, step 420. If incorrect bytes are received, arrow 422, then an error message is sent, step 424. When a good command is received, arrow 426, the command is dispatched, step 428. For example, “add Timer Command”, arrow 430, leads to an attempt to modify Timer table, step 432. If successful, arrow 434, the operation returns to step 420. If the attempt fails, arrow 436, then an error message is sent, step 438, and the operation then returns to step 420.
Similarly, a “modSampleTimoutCmd”, arrow 440, attempts to modify the sample Timeout, step 442. Failure, arrow 444, leads to generation of an error message, step 438, and the operation returns to step 420. A “runCmd”, arrow 450, leads to run mode, step 452. A “1stCmd”, arrow 454, leads to transmission of all settings and state, step 456; once complete, arrow 458, the operation returns to step 420. An “uploadCmd”, arrow 460, causes transmission of all results, step 462 and, once complete, arrow 464, operation returns to step 420. By comparison, a “resetCmd”, arrow 470, clears the device to its initial reset state, step 472, and the operation returns to step 406.
In diagram 500,
If incentive spirometer threshold is sensed, arrow 518, then it is determined if “spiroSense” is pending, step 520. If no, arrow 522, the operation returns to runMode, step 502; if yes, arrow 524, the operation proceeds to attempt log, step 510. From step 506, if incentive spirometer threshold is sensed, arrow 530, log result is attempted, step 532; if successful, arrow 534, the operation returns to runMode, step 502; if it fails, arrow 536, the operation proceeds to step 516 and stops.
To ensure patients were able to hear the alarm, a buzzer 642,
The apparatus represented by circuit design 100,
Opaque housing 602 defines a plurality of view ports which are open in this construction and, in other constructions, can have optically transparent or translucent plates to enable viewing of a device such as an incentive spirometer IS. Graduation marks 605 on the incentive spirometer IS are visible through port 606,
A conduit 628,
The workstation 670,
When the device is put into testing mode, and the reminder alarm sounds or generates other perceptible indicia of alarm, the device indicates via the perceptible prompt that the patient should use the incentive spirometer. Immediately as the reminder alarms, a patient can: (1) do nothing and allow to the prompt to timeout; (2) push a snooze button, which will silence the alarm, or (3) use the incentive spirometer, which will also silence the indicator alarm if the patient hits or surpasses the IR light threshold. The system keeps track of what time each timer starts, and what time a snooze or inspiratory event happens. The system records all inspiratory events, both following and independent of timers. The system logs this data.
Although specific features of the present invention are shown in some drawings and not in others, this is for convenience only, as each feature may be combined with any or all of the other features in accordance with the invention. While there have been shown, described, and pointed out fundamental novel features of the invention as applied to a preferred embodiment thereof, it will be understood that various omissions, substitutions, and changes in the form and details of the devices illustrated, and in their operation, may be made by those skilled in the art without departing from the spirit and scope of the invention. For example, it is expressly intended that all combinations of those elements and/or steps that perform substantially the same function, in substantially the same way, to achieve the same results be within the scope of the invention. Substitutions of elements from one described embodiment to another are also fully intended and contemplated. It is also to be understood that the drawings are not necessarily drawn to scale, but that they are merely conceptual in nature.
It is the intention, therefore, to be limited only as indicated by the scope of the claims appended hereto. Other embodiments will occur to those skilled in the art and are within the following claims.
This application claims priority to U.S. Provisional Application No. 62/335,100 filed on 12 May 2016. The entire contents of the above-mentioned application is incorporated herein by reference.
Number | Date | Country | |
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62335100 | May 2016 | US |