Patent Application
20140159912
This invention relates to mobile communication devices, or more specifically, to mobile communication devices capable of collecting and monitoring external signals.
Nowadays in their versatility, smart telephones resemble a Swiss Army Knife—a multi-function and multi-purpose device. Most wireless communication devices (cellular or mobile telephones, e.g.) incorporate additional non-communication features, such as imaging (photo and video), personal planners, games, navigation, etc. There are numerous inventions that attempt to include additional features for measurement and/or monitoring external signals such as temperature and air pressure. Especially of interest for practical applications are medical uses of smartphones for the purpose of patient monitoring, self-diagnostic and treatment. Certain medical monitoring detectors can be imbedded directly into a smartphone and be an integral part of such. An example is a non-contact infrared medical thermometer being part of a smart phone as taught by the U.S. Pat. No. 8,275,413 issued to Fraden et al., that is incorporated herein as a reference. Yet, many other biomedical signs, for example, arterial blood pressure, EKG, blood glucose and others, require more intimate interfaces between the sensors and patient. In other words, these vital signs can't be measured remotely and require a direct physical contact with the patient body surface. Incorporating the specialized sensors on or inside a smartphone is impractical as it would impair other functions of the phone, making it large and expensive. Thus, as currently known in the art, a mobile communication device (smartphone, e.g.) serves only as an information link between a stand-alone medical monitor and external devices, either local or remote. An example of such an approach is the U.S. Patent Publication No. 2007/0073173 A1 issued to Lam et al., being incorporated herein as a reference. This publication teaches a wrist blood pressure monitor that via a cable is connected to an external computer or cell phone for transmission of the collected information. Thus, a mobile phone is not part of the data acquisition process and functions independently of such process as a mere communication channel.
Any stand-alone medical monitor can send its output signals via a mobile communication device (cell phone, e.g.). Clearly, this is well known in the art. What is not known is combined system where one component can't function without the other. Further, it makes a practical sense to interface a cell phone only with portable medical monitors that can be carried by or worn on the patient body. Otherwise advantages of a handheld smartphone (small size, versatility, multiple purposes, etc.) become irrelevant. Modern progress in electronics and packaging resulted in a significant size and weight reduction of many medical devices. Examples are the wrist blood pressure monitors, glucometers, audiometers, body impedance meters, and many others. Even mass spectrometers for the chemical analysis of bodily fluids have been produced by using MEMS processes. These vital signs are of interest for the patient monitoring.
In several practical applications, such as sport medicine, clinical monitoring of moving patients, elderly care and several others, it is desirable for patients to carry vital sign monitors on their bodies and collect medical data with little or no interferences with other personal activities. Many of these patients conduct active way of life and usually carry with them a mobile phone. Therefore, it is desirable to achieve a synergy between the smartphone and a portable medical data acquisition system. For a better efficiency, synergy should go beyond a mere data communication by a phone and preferably make a smartphone an integral part of the monitor.
Use of a mobile phone for transmitting data from the monitoring system comprising an implantable sensor device is taught by the U.S. Pat. No. 8,265,556 issued to Tekin, et al. Also, a mobile phone can be used for controlling functionality of medical devices as exemplified by U.S. Pat. No. 8,015,972 issued to Pirzada. A near-range wireless communication between medical devices is known in art as exemplified by the U.S. Pat. No. 7,565,132 issued to Orbach. These patents are incorporated herein as references.
Small medical monitors are known in art. An example is a wrist blood pressure monitor that is fabricated in form of a bracelet and being totally self-contained. This device is exemplified by the U.S. Pat. Nos. 5,640,964 issued to Archibald et al. and No. 7083573 issued to Yamakoshi et al., such patents being incorporated herein as references. A wearable patient monitoring system is exemplified by the U.S. Patent Publication No. 2009/0204013 A1 issued to Mühlsteff et al., such publications being incorporated herein as a reference. A cuffless wrist blood pressure monitor operating with a simple cell phone to transmit medical information via Internet is disclosed in US 2005/0228300 A1 issued to Jaime et al. The disclosure being incorporated herein as a reference.
Thus, it is an object of the present invention to provide a wearable device that combines functions of a smartphone and medical data acquisition system.
It is another object of the present invention to make a small wrist bracelet containing medical sensors and being controlled by a personal mobile communication device;
Further and additional objects are apparent from the following discussion of the present invention and the preferred embodiments.
A device wearable on the outside of the patient body or body part, for example such device is a bracelet containing medical sensors and actuators. The wearable device comprises a module for a near-range wireless link with a mobile communication device (smartphone or tablet, e.g.). Main function of the bracelet is to collect and condition medical data and then transmit them wirelessly to a smartphone. The smartphone stores and uses a pre-loaded software app capable of controlling the wearable sensors and actuators in the bracelet and to process, analyze and output medical data, such as arterial blood pressure, heart rate, blood oxygenation, and others received from the bracelet. The app is capable of presenting the result of the data processing on the smartphone output means, such as a display.
Refer to
With respect to functionality, functions of the bracelet 1 and phone 2 are clearly separated in order to optimize their respective sizes, complexity and enhance efficiency. The bracelet functions are generally should be limited to data acquisition and transmission. Thus the bracelet (sensing device) is one part of the combined system of a bracelet+phone. The bracelet collects medical signals, conditions and sends them to the processing part of the system which is situated in a smartphone 2 and controlled by the app. As a result, bracelet 1 doesn't need a complex processor, signal processing software, display, speaker or other human interface components that normally would be required in a stand-alone monitor. These functions are shifted to the smartphone 2 that already has such component shared with other phone functions. The bracelet 1 may need some kind of patient signaling components, for example, the indicating lights 22 to signal the bracelet operating conditions. Examples of the conditions are power on/off, wrong placement on a wrist, closed/open latch 6, etc. Naturally, besides the indicating lights 22, other types of a feedback may be employed, for example a beeper.
Air pressure inside the bladder 13 is controlled by the air pump 14 and air valve 17 and measured by the air pressure sensor 16. All these components are interconnected by the pneumatic tubing 15. These components are typical for any conventional arterial blood pressure monitor known in the art and not described here in detail. It is important to note that bladder 13 generally circumferences wrist 9 to compress its internal artery 10 on a command from the controller 18. The compressing air pressure should vary between somewhat below the diastolic pressure (DIA) and above the systolic pressure (SYS). A maximum air pressure must not exceed 350 mmHg which may require an addition of a safety valve (not shown) attached to the tubing 15. The pressure-related components are interfaced with the controller 18 that turns on and off the drivers (not shown) for pump 14 and valve 17. It also monitors air pressure via the pressure sensor 16 and converts pressure signal to a digital format. The results of monitoring are fed to the near-range wireless communications module 19 that transmits and receives radio signal 7.
The bracelet components are powered by a primary or rechargeable battery 20. The controller 18 takes the BP and other vital signs either on its own timing or on command received from the smartphone 2 via the module 19. Generally, information transmitted by module 19 contains only conditioned signals from the sensors and not the actually computed diastolic and systolic pressure numbers. These are preferably computed by the phone 2 microprocessor an accordance with the installed app. This allows future modifications and updates of the phone app without changing hardware or software of the bracelet 1.
To better illustrate a mutual disposition of the components,
Bladder 13 may be inflated by pump 14 to compress arteries 10 against the supporting bones 30 inside the wrist 9, causing a restriction of the blood flow inside the arteries. The blood flow restriction results in mechanical arterial oscillations that are detected by the pressure sensor 17 and will be interpreted by an app in a smartphone 2 to compute the arterial blood pressure according to one of the algorithms known in the art. Various electrical and mechanical components are positioned inside the front and back shells 28 and 27, respectively. This is illustrated by the battery 20 and an electronic module 24 that contains most of the components embraced by the dotted line in
Besides the arterial blood pressure, other vital signs can be monitored by the system of a bracelet 1 and phone 2. For example, heart rate and its variations can be directly derived from the fast changing component of the pressure signal received from the pressure sensor 16. Other vital signs may be obtained by an additional medical detector 21 (see
Operation of the devices according to the present invention can be outlined as follows. The patient snaps on the bracelet 1 on her wrist and latches it for a comfortable wearing by a latch 6 or Velcro tape 29. Indicating light 22 shows that the bracelet is in a correctly secured position and power is turned on. The bracelet 1 establishes a wireless communication with the smartphone 2 that initiates the monitoring application (app) that was pre-loaded into the phone 2 memory. After a routine self-check, the phone 2 sends a wireless command to controller 18 to take a blood pressure. The pump is inflated, then deflated according to one of a predetermined algorithms will known in the art. The output signals from the pressure sensor 16 are digitized and transmitted to the phone 2 where the app computes the systolic, diastolic and mean pressures and also calculated a heart rate, RR-interval variability and other cardiac parameters.
An important feature of this invention is that the smartphone 2 can in real time provide via its output means (display and/or speaker) a biofeedback information to the patient in accordance with the monitored biomedical signals and pre-defined algorithm programmed into the app. For example, if the device is used in fitness, the HR and BP numbers can provide guidance to the strength and duration of the exercise procedure.
While the invention has been particularly shown and described with reference to a number of preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.
