Patent Application
20140228721
1. Field of the Invention
This disclosure relates generally to methods and devices for the treatment of hypertension. More specifically, methods and devices which treat hypertension using devices disposed extra corporally.
2. Description of the Related Art
Hypertension, or high blood pressure, affects millions of people every day and is a serious health hazard. Hypertension is associated with an elevated risk for heart attack, heart failure, arterial aneurysms, kidney failure and stroke. There are many factors that may affect blood pressure, such as: salt intake, obesity, occupation, alcohol intake, smoking, pregnancy, stimulant intake, sleep apnea, genetic susceptibility, decreased kidney perfusion, arterial hardening and medication(s). Many times people are unaware that they suffer from hypertension until it is discovered during a medical check-up with their health care practitioner (HCP), or worse, it is discovered when they are hospitalized for a hypertension related condition such as a heart attack or stroke.
Blood pressure is controlled by a complex system within the body, one component of this system is known as the arterial baroreflex (ABR). The baroreflex is the fastest autonomic reflex responding to changes in blood pressure. The baroreceptor nerve endings are embedded in vessels throughout the circulatory system and encode both mean pressure and rate of change of pressure as a frequency. Centers in the brainstem process spikes in the frequency information, integrating it with other information and providing a signal to the sinoatrial (SA) pacemaking node of the heart via efferent fibers in the vagus nerve. When blood pressure becomes too high, the resulting vagal nerve signal triggers the release of acetylecholine at the SA node of the heart, slowing the heart rate and thus lowering the blood pressure.
Concentrations of baroreceptors are located in the transverse aortic arch and the carotid sinuses of the left and right internal carotid arteries. The baroreceptors found within the aortic arch monitor the pressure of blood delivered to the systemic circuit, and the baroreceptors within the carotid arteries monitor the pressure of the blood being delivered to the brain.
As described above, the arterial baroreceptors are stretch receptors that are stimulated by distortion of the arterial wall when pressure changes. The baroreceptors can identify the changes in the average blood pressure or the rate of change in pressure with each arterial pulse. Action potentials triggered in the baroreceptor endings are then conducted to the brainstem where central terminations (synapses) transmit this information to neurons within the solitary nucleus. Reflex responses from such baroreceptor activity can trigger increases or decreases in the heart rate. Arterial baroreceptor (ABR) sensory endings are simple, splayed nerve endings that lie in the tunica adventitia of the artery. An increase in the mean arterial pressure increases depolarization of these sensory endings, which results in action potentials. These action potentials are conducted to the solitary nucleus in the central nervous system by axons and have a reflex effect on the cardiovascular system through autonomic neurons.
At normal resting blood pressures, baroreceptors discharge at approximately 1 out of every 3 heart beats. If blood pressure falls, the arteries retract in diameter and the baroreceptor firing rate decreases with the drop in blood pressure and the brain sends a signal to the heart to increase blood pressure by increasing heart rate. The brain also sends a signal to dilate the arteries and veins of the periphery. Signals from the carotid baroreceptors are sent via the glossopharyngeal nerve (cranial nerve IX). Signals from the aortic baroreceptors travel through the vagus nerve (cranial nerve X). Arterial baroreceptors inform reflexes about arterial blood pressure.
The arterial baroreflex system is a dynamic system that is capable of adapting to ever changing situations. The ABR is the reason why we do not pass out when moving from a seated to standing position. In this instance the ABR senses a change in blood pressure and accommodates the change by sending the appropriate signal to regulate blood pressure. The ABR system also performs an essential function to regulate blood pressure during exercise, wherein during exercise your heart rate increases as well as your blood pressure, however, at a certain point during exercise the ABR will intervene, allowing the heart rate to further increase but not allowing the blood pressure to further increase.
As stated above, hypertension currently affects a large and growing population. Currently treatments for hypertension range from prescribed lifestyle changes and the use of pharmaceutical products. Within the past couple of years, new surgical therapies are emerging. These surgical therapies either lead to the implantation of a device for stimulating a patient's carotid baroreceptor or to the disconnection of the nerves of the renal arteries.
If prescribed lifestyle changes do not address a patient's hypertension, their HCP will typically prescribe drug therapy to treat their hypertension. There are multiple classes of pharmaceutical products that can be utilized to treat hypertension. These include vasodilators to reduce the blood pressure and ease the workload of the heart, diuretics to reduce fluid overload, inhibitors and blocking agents of the body's neurohormonal responses, and other medicaments or medications. Many times, a HCP will prescribe one or more of these products to a patient to be taken in combination in order to lower their blood pressure. However, the use of pharmaceutical products is not without their risks. Many of these products carry warnings of potential side effects. Additionally, each patient may respond differently to the products, therefore multiple office visits may be required before the right dosage and type of pharmaceutical products are selected, which leads to greater health care costs. Further still there are a number of patients who either do not respond to medication, refuse to take medication, or over time the medication no longer provides a therapeutic effect. Recently, new clinical trial data has drawn correlations between the use of diuretic pharmaceutical products to treat high blood pressure and the incident or occurrence of diabetes within the patient.
For patients who do not respond to drug therapy, there are medical devices and treatments that can be utilized to treat high blood pressure. Some of these devices involve invasive surgical procedures including the implantation of a permanent medical device within a patient's artery to impart a force at a specific location within the artery which then may cause a lowering of blood pressure. However, these devices are relatively new or are still under development and have not been proven over a long period of time. Also, since the device is a permanent implant, there is always the possibility of complications during the implantation process or infections related to the implantation.
As described above, another type of invasive medical device is an electrical signal generating implant, where electrodes are placed adjacent to the carotid artery. With this process, the surgeon must be careful not to sever any of the nerves while implanting the device. If the nerves are severed, then the device will not function properly and may lead to long term health complications for the patient. However, even more troubling is that the patient has now permanently lost one of the body's key concentrations of baroreceptors for controlling blood pressure naturally, which may lead to complications later, which are currently unknown. Additionally, the implant device requires regular battery replacement, which to do so requires another invasive surgical procedure and also increased cost to the medical system and user.
Another type of invasive medical device and procedure being developed is the use of ablation catheter to denervate the carotid body, specifically the chemoreceptors of the carotid body. Similar to the device and procedure described above, this device permanently causes a disconnection between the chemoreceptors and the nervous system/brain. The long term effects are unknown, additionally, other nerves may be destroyed or disconnected during the procedure which may lead to other side effects.
Another type of invasive medical procedure to treat hypertension being developed is to use an ablation catheter placed within the renal artery, where a series of energy pulses are performed to ablate (sever) the nerves surrounding the artery, thereby effectively disconnecting the nerves of the kidney from the body. This procedure results in a permanent and non-reversible change to the patient's nervous system, this procedure is being referred to as renal nerve ablation or renal denervation. The long term effects of such a permanent treatment are unknown at this time as this approach is relatively new on the market. Recently published data has shown that not all patients respond to this surgical procedure, that is after the procedure, some of the patients show little to no changes in their blood pressure. This may be concerning as now these patients have had their renal arteries permanently disconnected from the nervous system leading to their kidneys, which may lead to long term effects which are unknown at this time. Additionally, the costs associated with an invasive medical procedure are not insignificant, only to prove that the procedure had no effect, thus, instead of potentially lowering the cost of treatment for these patients, the cost of treating their hypertension was significantly added to.
Additionally, the recently published data also shows that patients who respond to renal denervation may still remain hypertensive. Thus, the renal denervation procedure may not be a “cure,” instead it may be seen as an adjunctive therapy, as such these patients may remain on drug therapies or are recommended to remain on drug therapy after having undergone renal denervation.
Yet another invasive surgical approach to address hypertension is a combination of a device and a pharmaceutical product, wherein a catheter with a needle disposed near its distal end are placed within the renal artery. Once in position, a liquid pharmaceutical product is injected into the wall of the artery or into the area surrounding the wall of the artery, whereby the pharmaceutical product is designed to chemically ablate the renal nerves. Here again, this treatment procedure is considered to be a permanent alteration of the nerve traffic between the brain and kidney, whereby the nerves are permanently severed. Long term efficacy of the severing of the renal nerves is unknown. Additionally, long term effects of the procedure are also unknown.
Human skin acts as the protective barrier between our internal body systems and the outside world. Our skin in combination with our bodies nerves provides for the ability to perceive touch sensations and gives our brains a wealth of information about the environment around us, such as temperature, pain, and pressure. Without such a nervous system, we wouldn't be able to feel our feet hitting the floor when we walked, we wouldn't sense when something sharp cut us, and we wouldn't feel the warmth of the sun on our skin.
Human skin is composed of several layers. The very top layer is the epidermis and is the layer of skin you can see. In Latin, the prefix “epi-” means “upon” or “over,” thus the epidermis is the layer upon which the dermis is disposed (the dermis is the second layer of skin). The epidermis, made of dead skin cells, is waterproof and serves as a protective wrap for the underlying skin layers and the rest of the body. It contains melanin, which protects against the sun's harmful rays and also gives skin its color. When you are in the sun, the melanin builds up to increase its protective properties, which also causes the skin to darken. The epidermis also contains very sensitive cells called touch receptors that give the brain a variety of information about the environment the body is in.
The second layer of skin is the dermis. The dermis contains hair follicles, sweat glands, sebaceous (oil) glands, blood vessels, nerve endings, and a variety of touch receptors. The dermis' primary function is to sustain and support the epidermis by diffusing nutrients to it and replacing the skin cells that are shed off the upper layer of the epidermis. New cells are formed at the junction between the dermis and epidermis, and they slowly push their way towards the surface of the skin so that they can replace the dead skin cells that are shed. Oil and sweat glands eliminate waste produced at the dermis level of the skin by opening their pores at the surface of the epidermis and releasing the waste.
The bottom skin layer is the subcutaneous tissue which is composed of fat and connective tissue. The layer of fat acts as an insulator and helps regulate body temperature. It also acts as a cushion to protect underlying tissue from damage when you bump into things. The connective tissue keeps the skin attached to the muscles and tendons underneath.
Our sense of touch is controlled by a huge network of nerve endings and touch receptors disposed within the skin which is known as the somatosensory system. This system is responsible for all the sensations we feel; cold, hot, smooth, rough, pressure, tickle, itch, pain, vibrations, and more. Within the somatosensory system, there are four main types of receptors; mechanoreceptors, thermoreceptors, nociceptors, and proprioceptors.
It is important to understand how specialized receptors adapt to a change in stimulus (anything that touches the skin and causes sensations such as hot, cold, pressure, tickle, etc). A touch receptor is considered rapidly adapting if it responds to a change in stimulus very quickly. This means that it can sense right away when the skin is touching an object and when it stops touching that object. However, rapidly adapting receptors can't sense the continuation and duration of a stimulus touching the skin (how long the skin is touching an object). These receptors best sense vibrations occurring on or within the skin. A touch receptor is considered slowly adapting if it does not respond to a change in stimulus very quickly. These receptors are very good at sensing the continuous pressure of an object touching or indenting the skin but are not very good at sensing when the stimulus started or ended.
Mechanoreceptors are receptors which perceive sensations such as pressure, vibrations, and texture. There are four known types of mechanoreceptors whose only function is to perceive indentions and vibrations of the skin: Merkel's disks, Meissner's corpuscles, Ruffini's corpuscles, and Pacinian corpuscles.
The most sensitive mechanoreceptors, Merkel's disks and Meissner's corpuscles, are found in the very top layers of the dermis and epidermis and are generally found in non-hairy skin such as the palms, lips, tongue, soles of feet, fingertips, eyelids, and the face. Merkel's disks are slowly adapting receptors and Meissner's corpuscles are rapidly adapting receptors so your skin can perceive both when you are touching something and how long the object is touching the skin.
Located deeper in the dermis and along joints, tendons, and muscles are Ruffini's corpuscles and Pacinian corpuscles. These mechanoreceptors can feel sensations such as vibrations traveling down bones and tendons, rotational movement of limbs, and the stretching of skin.
Another type of receptors are thermoreceptors, as their name suggests, these receptors perceive sensations related to the temperature of objects the skin feels. They are found in the dermis layer of the skin. There are two basic categories of thermoreceptors: hot and cold receptors.
Cold receptors start to perceive cold sensations when the surface of the skin drops below 95° F. They are most stimulated when the surface of the skin is at 77° F. and are no longer stimulated when the surface of the skin drops below 41° F. This is why your feet or hands start to go numb when they are submerged in icy water for a long period of time.
Hot receptors start to perceive hot sensations when the surface of the skin rises above 86° F. and are most stimulated at 113° F. But beyond 113° F., pain receptors take over to avoid damage being done to the skin and underlying tissues.
Thermoreceptors are found all over the body, but cold receptors are found in greater density than heat receptors. The highest concentration of thermoreceptors can be found in the face and ears.
Another type of receptor are pain receptors, commonly know as nociceptors, “Noci-” in Latin means “injurious” or “hurt.” These receptors detect pain or stimuli that can or does cause damage to the skin and other tissues of the body. There are over three million pain receptors throughout the body, found in skin, muscles, bones, blood vessels, and some organs. They can detect pain that is caused by mechanical stimuli (cut or scrape), thermal stimuli (burn), or chemical stimuli (poison from an insect sting).
These receptors cause a feeling of sharp pain to encourage you to quickly move away from a harmful stimulus such as a broken piece of glass or a hot stove stop. They also have receptors that cause a dull pain in an area that has been injured to encourage you not to use or touch that limb or body part until the damaged area has healed. While it is never a pleasant experience to activate these receptors that cause pain, these receptors play an important part in keeping the body safe from serious injury or damage by sending these early warning signals to the brain.
Another receptor type are proprioceptors, the word “proprius” means “one's own” and is used in the name of these receptors because they sense the position of the different parts of the body in relation to each other and the surrounding environment. Proprioceptors are found in tendons, muscles, and joint capsules. This location in the body allows these special cells to detect changes in muscle length and muscle tension. Without proprioceptors, we would not be able to do fundamental things such as feeding or clothing ourselves.
While many receptors have specific functions to help us perceive different touch sensations, almost never are just one type active at any one time. When drinking from a freshly opened can of soda, your hand can perceive many different sensations just by holding it. Thermoreceptors are sensing that the can is much colder than the surrounding air, while the mechanoreceptors in your fingers are feeling the smoothness of the can and the small fluttering sensations inside the can caused by the carbon dioxide bubbles rising to the surface of the soda. Mechanoreceptors located deeper in your hand can sense that your hand is stretching around the can, that pressure is being exerted to hold the can, and that your hand is grasping the can. Proprioceptors are also sensing the hand stretching as well as how the hand and fingers are holding the can in relation to each other and the rest of the body.
None of the sensations described above and felt by the somatosensory system would make any difference if these sensations could not reach the brain. The nervous system of the body takes up this important task. Neurons, which are specialized nerve cells that are the smallest unit of the nervous system, receive and transmit messages with other neurons so that messages can be sent to and from the brain. This allows the brain to communicate with the body. When your hand touches an object, the mechanoreceptors in the skin are activated, and they start a chain of events by signaling to the nearest neuron that they touched something. This neuron then transmits this message to the next neuron which gets passed on to the next neuron and on it goes until the message is sent to the brain. Now the brain can process what your hand touched and send messages back to your hand via this same pathway to let the hand know if the brain wants more information about the object it is touching or if the hand should stop touching it.
Vibration experiments have been conducted to test the effects of vibration, the results of such an experiment were published in 1961 in the Journal of Physiol. (1961), 159 pp 391-409, entitled “Response of Pacinian Corpuscles to Sinousoidal Vibration, by M. Sato. In this experiment it was proven that vibrations can excite the nervous system similar to utilization of electrical stimulation.
Other experiments have shown that the 1st Node of Ranvier gaps can be excited by either mechanical transduction or acoustic stimulation. The 1st Node of Ranvier gaps are gaps formed between myelin sheaths between different cells.
In a 1967 publication entitled “The Relative Sensivity to Vibration of Muscle Receptors of the Cat,” M. C. Brown, I. Engberger and P. B. C. Matthews, Journal Physiol. (1967), 192 PP 773-800, the authors tested vibrations and concluded that vibratory effects persist as long as the vibration continues. Additionally, the authors cited another publication, 1966 Matthews, “Reflex excitation of the soleus muscle of the decerebrate cat caused by vibration applied to tendon” where vibration, was applied to a non-contracting muscle, provides a way of selectively activating nearly all of the nerve fibers from the primary endings to discharge repetitively. In contrast to electrical stimulation, vibration provides for a more likely activation.
Electrical stimulation will stimulate those nerves which are located in the close proximity to the electrical source, however, electrical stimulation will seek the lowest resistance pathway and is typically localized to the area of application. In contrast, vibrational stimulation carries the benefit of exciting afferent fibers at a distance from the location of the application of the vibration.
In 2000 a publication by Alfrey entitled “Characterizing the Afferent Limb of the Baroreflex” Rice University, Houston Tex., April 2000, UMI Microform 99-69-223. The author concluded that the baroreflex is the fastest autonomic reflex responding to changes in blood pressure. Baroreceptor nerve endings embedded in vessels throughout the circulatory system encode both mean pressure and rate of change of pressure as a frequency-modulated train of action potentials (spikes). Centers in the brainstem process the spike train information, integrating it with information from higher centers and providing a signal to the sinoatrial (SA) pacemaking node of the heart via efferent fibers in the vagus nerve. When blood pressure becomes too high, the resulting vagal signal triggers the release of acetylcholine at the SA node of the heart slowing heart rate and thus lowering blood pressure.
In another paper, published in 2004 by Syntichaki et al., entitled “Genetic Models of Mechanotransduction: The Nematode Caenorhabditis elegans” Physol Rev. 84: 1097-1153, 2004 10.1152/physrev.0043.2003, it was found that all vertebrates respond to similar mechanosensory stimuli, therefore it's likely that two humans would have similar response to the same wavelengths or frequencies.
It is further contemplated that the device and method(s) disclosed herein can be beneficial for other therapeutic uses such as for the treatment of sleep apnea and/or snoring.
Further still, in accordance with the present disclosure and treatment methods disclosed herein, a user or the therapy providing system described herein may additionally have a feeling of calmness or a soothing/warmth feeling during or after the use of the therapy providing device in accordance with the present disclosure.
Lastly, while there are number of different therapies available on the market and new therapies emerging, there are patient populations that cannot be treated through the use of the existing drugs or devices.
One such population is patients who develop high blood pressure during pregnancy. Health care practitioners are generally hesitant to prescribed pharmaceutical products in these situations as there may be unknown side effects to the mother and unborn child. Furthermore, many hypertensive pharmaceutical products have not been properly tested for use during pregnancy; therefore, there is much hesitancy on behalf of the prescribing physician to use such drug products due to potential untested side-effects as well as potential litigation arising from a side-effect. Pregnancy induced hypertension, gestational hypertension or preeclampsia may not be a permanent condition and may be resolve after delivery. Therefore, the use of permanent therapies, such as renal denervation, may not be warranted in this situation. Additionally, surgical procedures are not generally recommended during pregnancy.
There is yet another hypertensive population emerging in today's world is the hypertensive adolescent such as a child under 18 years of age. Over the past 30 years, the number of adolescent hypertensives has risen to a rate of over 3.7% diagnosed hypertensive and 3.4% diagnosed pre-hypertensive. Only 1 in 4 adolescents are currently diagnosed. Many of the currently available pharmaceutical products have not been tested on an adolescent population, therefore, as described above, many physicians are hesitant to prescribe drug therapies due to unknown side effects or long term effects they may have. Furthermore, the adolescent population poses yet another difficulty in that they are still developing and undergoing puberty and bone growth. Therefore, there is a need for a non-invasive, non-pharmaceutical solution to address this growing patient population.
Thus, it would be desirable to provide improved methods, devices and systems for artificial and selective activation of a patient's baroreflex or nervous system in order to achieve a variety of therapeutic objectives, including the control of hypertension, renal function, heart failure, and the treatment of other cardiovascular disorders. It would be particularly desirable if such methods and systems were non-invasive, reversible, safe and/or external to the patient.
In accordance with the present disclosure there is provided a device for treatment of hypertension, comprising, a housing, the housing have a proximal end and a distal end; and a driver assembly within the housing, the driver assembly electrically coupled to an energy source, the energy source disposed within the housing.
In accordance with the present disclosure there is provided a device for imparting energy to a patient, comprising, a housing, the housing having a proximal end, a distal end and defining a volume therebetween; a driver assembly is disposed within the volume of the housing; an energy source coupled to the driver assembly; and an electronics module coupled to the driver assembly and the energy source, wherein the electronics module controls the driver assembly.
In accordance with the present disclosure there is provided a device for treating hypertension, the device comprising, a housing, the housing having a proximal surface and a distal surface, wherein the housing further includes a mounting system, the mounting system including a first member and a second member, the first member associated with the housing and the second member configured to be received by tissue; and a driver assembly within the housing.
In accordance with the present disclosure this is provided a device for imparting energy to a patient, the device comprising: a housing, the housing having a first surface and a second surface, the surfaces defining a volume therebetween, wherein the housing further includes a mounting system, the mounting system including a first member and a second member, the first member associated with the housing and the second member configured to be received by tissue; a driver assembly disposed within the volume of the housing; an energy source coupled to the driver assembly; and an electronics module coupled to the driver assembly and the energy source.
In accordance with the present disclosure there is provided a method of providing therapy, the method comprising: applying a therapy applying device to a collar bone of a patient; and activating a driver assembly within the therapy applying device.
FIG. 5AA is a top view of a flexible arm in accordance with the present disclosure;
FIG. 5BB is a bottom view of the flexible arm of FIG. 5AA;
FIG. 5CC is a side view of the flexible arm of FIG. 5AA;
The following detailed description illustrates embodiments of the disclosure by way of example and not by way of limitation. The description clearly enables one skilled in the art to make and use the disclosure, describes several embodiments, adaptations, variations, alternatives, and uses of the disclosure, including what is presently believed to be the best mode of carrying out the disclosure.
This written description uses examples to disclose the disclosure, including the best mode, and also to enable any person skilled in the art to practice the disclosure, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the disclosure is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
In accordance with the present disclosure there is provided devices and methods for the treatment of hypertension. The device of the present disclosure is configured to be detachably attached to a user, wherein the device is aligned with a bone of the user's body. Once affixed to the patient, the device can be activated either: manually or remotely, through a wireless or wired connection, through the use of a software program running on a computing device or a software program running on a processor within the device. The activation may be timed to coincide with a patient's sleep pattern, such that therapy is provided by the device to the patient in the evening and again in the morning prior to the patient waking up. It is believed that providing therapy during a sleep cycle is beneficial to the present invention. Further still, the therapy providing device may “learn” the user's sleep cycle, and therefore automatically adjust the therapy start time as well as the duration of the therapy cycle or adjust/alter the pause time between the two or more therapy cycles when two or more therapy cycles are desired. Further still, the therapy providing device may be remotely activated by another person, for example a health care provider.
Additionally, the therapy providing device may be coupled to a wired or wireless remote, such as fitness tracking band (FITBIT, etc.) or a watch worn by the user, such that the band or watch may be utilized to activate the therapy providing device.
In accordance with embodiments of the present disclosure the device is detachably attached to a patient's tissue and is intended to engage a portion of the patient's skeletal frame, particularly the clavicle. It shall be understood that although the present disclosure is described in reference to the collar bone or clavicle, it shall be understood that this should not be limiting in any manner. As described above, in a preferred embodiment the methods and devices of the present disclosure utilize the clavicle. However, the methods and devices of the present disclosure may be utilized with other dermal bones such as the skull, jawbone, knee cap (patella) or non-dermal bones such as the wrist bone, ribs, scapula. Methods and devices of the present disclosure can also be used on any portion of the body such as on the thorax or any other portion of the body containing somatory sensors such as proprioceptors, nociceptors, mechanoreceptors or thermoreceptors. Dermal bones are unique in that dermal bone does not form from cartilage first and then calcify. Dermal bone is formed within the dermis and it grows by accretion only; that is, the outer portion of the bone is deposited by osteocytes. Dermal bones have been utilized to transmit sound for other devices such as in hearing aids.
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The housing 210 may be formed of multiple pieces which may then be assembled using known assembly methods such as glue, ultrasonic welding, heat welding, rotational welding, snap-fit construction, use of fasteners such as screws or pins, or the like. In accordance with the disclosure, the housing 210 may be formed of two pieces or multiple pieces, wherein one section of the housing 210 includes all sides except the second surface 215, thereby forming a shell into which the components can be disposed, then the second surface 215 could be attached to the other portion of the housing 210 to form the therapy providing device 200. The housing 210 may be constructed of biocompatible materials such as polymers, plastics, fabrics, ceramics, or metals. The housing 210 may be formed using manufacturing processes such as machining, injection molding, rotary molding, 3-d printing, vacuum forming, deep drawing or the like. In accordance with the disclosure, the materials utilized in construction of the housing 210 of the therapy providing device 200 shall be chosen such that the materials have good biocompatibility as it is intended that the therapy providing device 200 may be placed in skin contact during use, where in certain usages the skin contact may be for a prolonged time.
Further still, it is contemplated that the therapy providing device 200 may be wrapped or encased with a biocompatible membrane. An example of a suitable membrane is available from 3M and sold under the tradename of TEGADERM.
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In another aspect, the second component 217 may be embodied in the form of a flexible membrane in which an expandable foam material or other types of expandable materials may be injected into. In use, the therapy providing device would be placed on the user in a chosen location, the expandable material could then be injected into the flexible membrane while the therapy providing device is held against the user. As the foam expands and cures, the second component 217 would take the shape of the user's anatomy, thereby providing a customized fit. The foam in a cured state may be flexible or rigid. Alternatively, the second component, being fabricated as a flexible membrane may be filed with a biocompatible or non-biocompatible material, examples of such materials may be saline or silicone so that the second component 217 of the housing 210 readily conforms to the user's anatomy.
Lastly, it is further contemplated that the housing includes an enlarged or thickened surface that can be ground or machined away to conform to the patient's anatomy. Further still, a mold may be taken of the patient's anatomy, whereby a housing can then be manufactured from the mold taken from the user's anatomy, thereby customizing the fit of the therapy providing device to each user.
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It is further contemplated that the power switch 260 may be disposed adjacent to the second surface of the housing 215, wherein the second surface 215 may include a reduced thickness portion adjacent the power switch 260 as described above. It is additionally contemplated that the LED(s) 262 may also be disposed adjacent to the second surface of the housing, such that they can be viewed through the second surface of the housing. The viewing angle/ability of the LED(s) may be improved through the use of a light pipe or other light transmitting or carrying technologies. Additionally, it is contemplated that the LED(s) maybe disposed close to the exterior surface of the second surface of the housing such that the portion of the second surface of the housing adjacent to the LED(s) may be thinner. The power switch and LED(s) may be mounted on a separate circuit board disposed adjacent to the second surface of the housing, this separate circuit board would be in electrical communication with the circuit board(s) as described herein. A potential benefit of placing the power switch 260 adjacent to the second surface 215 is that the user can power the therapy providing device on, then place the therapy providing device onto a bandage disposed on their body. In this position, the power switch 260 being on the bottom of the device prevents the therapy providing device from being accidentally powered off due to inadvertent presses of the power switch.
It is further contemplated that the power switch may be controlled through a program either residing within memory of the therapy providing device 200 or the computing device 300 such that after the power switch has been pressed, further presses of the power switch will not alter the state of the program. For example a single press of the power switch will cause the therapy providing device to be powered on, such that thereafter the therapy providing device will run through a therapy cycle before automatically powering off. Further still, after powering the therapy providing device on, the therapy providing device may be powered off and/or reset by connecting the therapy providing device to the charging base or a recharging wire or pressing the power switch again or holding down the power switch for a determined amount of time.
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Although, it is described above that the present disclosure utilizes two circuit boards, this should not be considered limiting in any manner, it is contemplated that the electronic components of the present disclosure may be embodied on a single circuit board or on multiple circuit boards. As described herein, the circuit board or boards including any components connected thereto may be referred to as an electronics module 540. Further still, when embodied as a pair of therapy providing devices, the electronic components maybe fully contained within one of therapy providing devices or the electronic components can be disposed between the two devices. It is further contemplated that he device may include a charging port in place of the charging pins described herein. The charging port can be configured as a custom design or utilize off the shelf components such as USB, mini-USB, micro-USB designs.
FIGS. 5A-5CC illustrate additional housing embodiments for the therapy providing device 200 in accordance with the present invention wherein reference numbers are utilized to denote common structures between the various designs.
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Referring now to FIGS. 5AA, 5BB, and 5CC, there is shown an embodiment of a housing extension 219 in accordance with the present disclosure. As shown in FIG. 5AA-5CC, the housing extension 219 is configured to be received by a portion of the housing 210 and the second surface 215 (not shown), such that the housing extension 219 is retained between the two components. Alternatively, the housing extension 219 maybe integrally formed with either the housing 210 or the second surface 215 of the therapy providing device 200. As shown in FIGS. 5AA-5CC, the housing extension 219 is further configured to receive a fitting 229 within a portion of the arm, wherein the fitting can be a magnet 230 disposed within an optional magnet holder 231. Alternatively, the fitting 229 can be embodied as a snap, VELCRO, a metallic insert, glue or other detachable structures.
The housing extensions 219 in accordance with the present disclosure are designed and constructed of a material having a spring force K, wherein the spring force K may be linear or non-linear. In use, the spring force K of the arms in combination with the spring force K2 of the haptic 220′ or speaker voice coil 222 work together to ensure that the coil of the haptic 220′ is never fully compressed during use. A force is initially applied to the voice coil 222 of the haptic 220′, compressing the springs 223 of the haptic 220′ as the force increases in travel, the housing extensions 219 begin to flex thereby relieving the force on the voice coil 222 of the haptic 220′.
Further still, in accordance with the present disclosure, the housing extensions 219 of the therapy providing device 200 are housing extensions 219 are designed and may be constructed of a viscoelastic material. When the housing extensions 219 of the housing 210 are attached to the bandage, the extensions of the material will be deformed conforming to the anatomy of the patients collar bone and are designed to continue to conform and adapt to motion of the user and user's collarbones. The deformation of the housing extensions 219 will be highly dependent on the user's anatomy. Some user's might have very pronounced collar bones whereas other user's may have collar bones which are more in plane with their body contour. The housing extensions 219 provide a downward force to keep the voice coil 222 of the haptic speaker 220′ in contact with the user's skin disposed over their collar bone(s). It is preferred that the downward force provided by the housing extensions 219 should not exceed the spring force of the voice coil 222 of the haptic 220′ to avoid compressing the voice coil 222 to much such that the ability of the haptic 220′ to produce vibrations is diminished. The deformation of the housing extension 219 initially provides a downward force, which is configured to decrease over time due to the viscoelastic behavior of the material. The viscoelastic material of the housing extensions 219 is chosen to provide a downward force which will not exceed the compression force of the haptic exciter. Additionally, the material of the housing extensions 219 additionally is chosen such that the force applied to the user does not cause harm to the user. In a preferred embodiment, the viscoelastic material of which the housing extensions 219 provide a downward force between about 0.1 and 6 lbs, preferably between about 0.1 and 4 lbs and most preferably between about 0.25 and 2.5 lbs.
It is also contemplated that in accordance with the present disclosure, when a force is applied to the voice coil of the haptic 220′ or speaker, the springs 223 of the haptic 220′ initially compress and the struts 232 of the housing extension(s) 219 are lifted, as the force increases on the voice coil 222 of the haptic, a hysteresis occurs in the housing extensions 219, whereby the housing extensions 219 continue to extend thereby relieving the force on the struts 232/voice coil 222 of the haptic 220′ thereby permitting the voice coil 222 of the haptic 220′ to move independent of the applied force and preventing complete compression of the voice coil 222. Although the above embodiment of the housing arms 219 are described in accordance with a haptic 220′, it is contemplated that the housing arms 219 may be utilized in combination with any driver 220 as described within the present disclosure.
In yet another embodiment, it is contemplated that charging pins or charging pads may be disposed in the housing such that they extend beyond the second surface 215 of the housing. In this embodiment, the charging pins/pads may be symmetrically spaced about a centerline axis of the housing 210, such that, when placed onto a charging station, the orientation of the therapy providing device 200 is inconsequential as the charging pins/pads would align with the respective charging pins/pads of the charging station. If pins are utilized in the construction, it is preferred that the pins are spring-loaded retractable pins, such that when the therapy providing device is placed onto a bandage as described below the pins retract within the housing 210. Furthermore, the use of spring loaded pins ensures good electrical contact between the pins and the respective charging pads of the charging station or pads disposed on a bandage as described below with regard to
As shown in
In the event that the energy source 240 is embodied as a battery pack, the battery pack may be embodied in the form of a fabricated pack, where individual cells are soldered together, or alternatively, the battery pack could be arranged to utilize conventional battery sizes such as AAAA, AAA, AA, CR2032, LR44, 9-volt, A23 and the like.
It is further contemplated that the battery pack may be further divided into a primary battery pack and a backup battery pack. In use, the primary battery would be initially utilized, if the pack malfunctions or loses its charge or its charge is used, the backup battery pack would then be enabled to continue the therapy.
If the battery pack as described above is chosen to be a rechargeable, there is a need to provide a charging circuit within one of the circuit boards 500 or 550. The charging circuit may utilize either a physical connection to enable charging or may use a non-contact or inductive charging arrangement. If a physical connection is utilized, the plug may be a USB style plug, headphone style, spring loaded pins/contact pads or other types of plugs, such a plug can be integrated into the housing 210 and electrically connected to the battery through either circuit board. Alternatively, a plug may be directly mounted onto one of the circuit boards. It is further contemplated that the charging plug can also be utilized both for charging as well as communication between multiple therapy providing devices 200 and the computing device 300 as described above using a compatible cable. In an embodiment, the charging circuit would include “smart charging” technology, such that the circuitry would be capable of monitoring the charging current, battery temperature, battery life etc. to ensure that the battery is charged optimally as well as being properly charged and not overcharged. Alternatively, the charging station/base may include the “smart charging” circuitry or a portion of the circuitry as well.
As described above, the present disclosure may utilize pins or pads disposed on or coupled to the first circuit board to enable charging of the battery disposed within the device. It is further contemplated that a non-contact charging assembly could be utilized with the present disclosure. If a non-contact charging arrangement is selected, then the charging pins 265 and/or openings within the first surface of the housing 210 may not be necessary. Instead, the therapy providing device 200 would include a charging coil (not shown) disposed about the perimeter of the first circuit board 500. The use of a non-contact charging coil would further necessitate the inclusion of additional integrated circuits to enable and control the charging function. These additional circuits can be disposed on either of the two circuit boards. Suitable examples of a non-conductive or inductive charging would utilize an electromagnetic field to transfer energy between the charger and the battery pack. In this embodiment a charging station would be provided in which the therapy providing device 200 could be stored and charged simultaneously as will be described below. It is also contemplated that the storage/charging container may be a smart container that is it may contain a microprocessor and/or a wireless communication chipset. Thus, once the therapy device is removed from the storage container, the integrated wireless chipset within the storage container may cause the therapy device to power on. Suitable examples of components to enable non-contact charging are available from Wurth Electronics Inc, part numbers 760308201 wireless charging receiving coil and 760308101 wireless charging transmitting coil.
In accordance with the present disclosure, it is contemplated that the energy source 240 may be embodied in the form of an integrated generator, wherein the generator would be configured to create energy from movement of the therapy providing device 200, much like and automatic watch movement.
As described above, the therapy providing device 200 shown in
The second circuit board 550 may further include a communications chipset (555 not shown) such: Bluetooth, wifi, ZigBee, RFID, NFC, Ant+, infrared, 3G/4G, CDMA, TDMA or other known wireless communication protocols.
The first or second circuit board 500/550 may further include a clock circuit (556, not shown). The clock circuit generates and sets the timing of operations performing within the therapy providing device 200. The clock generator may be utilized to activate the therapy providing device 200, or may be utilized to record timed events, such as when the therapy providing device is on or off or in use.
Further still, either circuit board 500/550 may alternatively include an impedance sensor (557, not shown) or pair of impedance sensors, the impedance sensors in association with the processor 551 can be used to determine if the housing 210 and/or therapy providing device 200 is coupled to a user's skin or to a bandage 420 or if the housing is not coupled to the skin or bandage 420. If the housing 210 is coupled to a user's skin, then the impedance sensor would provide a signal to the processor 551 indicating such a condition, thereby the program stored in the memory of the processor or transmitted to the microprocessor could be initiated to conduct therapy according to the disclosure. If the impedance sensor is not coupled to the user's skin, then an open condition would occur, whereby the program would not be initiated and a visual signal may be generated through the program/processor to alert the user that the therapy providing device 200 is not placed properly and needs to be repositioned. As described below, the impedance sensors may be utilized in combination with features of the bandage to determine when the therapy providing device is coupled to a bandage, as such, the therapy providing device may then be energized, manually or automatically or in response to a program command as desired.
In yet another embodiment, the electronics module may include a microphone (558, not shown), whereby a test signal can be initiated and delivered by the driver assembly 220 or other audio/vibration device. The microphone would be utilized by the processor 551 to listen for a reflection of the test signal off of the user's clavicle, skin or other bone or structure to determine if the therapy providing device 200 has been placed properly. If the reflected sound matches that of one stored in memory, then the program can be run to provide therapy. If the reflected sound does not match the sound stored in memory, then an error message would be generated. The error message may be in the form of an audio signal or in the form of a visual signal such as a blinking light or a series of blinking lights. The microphone can also be utilized to record a a user's breath sounds or sounds emanating from the user's thorax. This may be utilized to determine if the user snores during sleeping or may be suffering from sleep apnea.
Additionally, the microphone 558 could be coupled with a blood pressure monitor, wherein the microphone 558 would listen for Korotkoff sounds, whereby the data generated from the blood pressure monitor and specifically the Korotkoff sounds captured by the microphone can be utilized to enable a closed loop control system or closed loop feedback system. It is contemplated, that the therapy provided by the therapy providing device 200 can be dynamically modified in response to the data received from the microphone coupled to the processor 551.
The circuit board 500 or 550 may further incorporate a pressure sensitive switch coupled to the processor 551. In use, the pressure sensitive switch would be in a normally open position or off position. When the therapy providing device 200 is placed on the user's skin, the pressure sensitive switch would be depressed, thereby turning the therapy providing device 200 on. The actuation of the switch can also be associated with the clock circuit to associate a time with the on/off state of the switch. These events can be written to the memory of the processor 551 or other memory storage location. The data can then be transmitted, wired or wirelessly, to a personal computer for analysis/storage. By tracking the actual on/off time of the therapy providing device, user compliance may be tracked by the user or by a third party such as a health care provider.
In yet another embodiment, the circuit board 500 or 550 may include an optical sensor, 559 (not shown) wherein the optical sensor 559 is utilized to detect whether the therapy providing device is affixed to a user's skin. In this embodiment, the optical sensor 559 can include a light sensor 560, whereby when the therapy providing device 200 is affixed to the user's skin the light is blocked to the sensor. In another embodiment, the optical sensor can be a reflective sensor 561, wherein the color of the light reflected back indicates whether the device is affixed to a user's skin or not. Further still, the optical sensor may be utilized to indicate if the therapy providing device is coupled to a bandage, whereby the therapy providing device may be prevented from being activated unless the optical sensor detects the presence of a bandage or a reflective sensor disposed on the bandage.
In another aspect of the present disclosure, the light sensor may be utilized to monitoring blood oxygen level, wherein data received from monitoring the user's blood oxygen level can be stored in memory or transmitted to another device such as a pulse-oximetry monitor or another computing device. Further still, the blood oxygen data may be utilized by a program of the therapy providing device to alter therapy provided to the user or otherwise control the therapy providing device 200. The light sensor may also be configured to respond to ambient light conditions. For example, the sensor may be configured to initiate the therapy providing device 200 when the sensor senses darkness or a programmed threshold of darkness and turn off the therapy providing device when sensing lightness.
In another aspect of the present disclosure, the light sensor may be used to measure alteration in blood-reflectance color, whereby the program controlling the therapy providing device may utilize this signal as a representation of heart rate or heartbeat. Accordingly the program controlling the therapy providing device 200 may use this data to determine blood pressure and accordingly provide therapy to the user based on the received data.
In another aspect of the disclosure, the therapy providing system 100 may be activated by disposing the two therapy providing devices 200 adjacent to each other. In this embodiment, magnets 340 disposed within the housings 210 may be utilized to activate a magnetic switch disposed within the housing 210 of each therapy providing device. In another aspect, one of the therapy providing devices may include one component of a RFID reader and the other therapy providing device includes the second component of the RFID system, such that when brought within proximity of each other the therapy providing devices may become activated. In another aspect, one therapy providing device may include an optical scanner and the other therapy providing device includes a barcode, QR code or other optically readable target to which the optical scanner would respond to.
It is further contemplated, that an accelerometer 670 (not shown) and/or compass 671 (not shown) and/or tilt sensor 672 (not shown) and/or GPS sensor 673 (not shown) can be incorporated into either of the circuit boards described above. The inclusion of such a sensor can be utilized to determine the position and/or orientation of the device. Additionally, the inclusion of such sensors along with a computer readable program can be utilized to track or monitor a user's sleep and sleep pattern. The user can then review this data on either the therapy providing device through the inclusion of a display (not shown) or series of LED lights incorporated into the housing 210 of the device. Alternatively, the sleep data may be transmitted to the computing device 300 or transmitted to a health care provider. Further still, the sleep data may be displayed on the charging base when the therapy providing device(s) 200 are coupled to the charging base. In use, as described below, a user would affix the housing 210 to their person using an adhesive patch, harness, specialized clothing article as will be described below. In this embodiment, the accelerometer/compass in communication with the processor 551 can be utilized to determine when to activate the therapy providing device or devices 200. If the signal coming back from the accelerometer/compass/tilt sensor indicates that a therapy providing device 200 is in a vertical position, then the program contained within the memory of the processor 551 or computing device 800 would not be initiated. Once the signal from the accelerometer/compass/tilt/GPS sensor indicates that the user is in a prone position, likely a sleep position, then the program contained within the memory can be run. Additionally, the clock timer can be associated with the accelerometer/compass/tilt/GPS sensor such that a user's sleep pattern can be stored in memory of the processor 551 or computing device 800. Data generated from such sensors could be stored in memory, of either the therapy providing device or the computing device to track usage of the device as well as the physical location of the devices. Such data could be transmitted to a third party using know wireless communication methods.
The circuit board(s) 500/550, program, the housing 210 or therapy providing device 200 may be provided with a unique identifier such as a serial number or patient information identifier so that the therapy providing device 200 may be tracked. Additionally, using the unique identifier it may be possible for a physician or a user to utilize a computer program, such as a website which when placed in communication with the therapy providing device, either wired or wirelessly, would allow continuous monitoring of usage of the device, such as date and time monitoring, duration of use, patient compliance and the like. The website could also provide information regarding hypertension and additionally be configured to communicate with other devices such as a scale to track the user's weight, a blood pressure monitor to track blood pressure measurements, a glucose meter, a heart rate monitor or other fitness tracking device such as FITBIT, JAWBONE UP, or BODYBUG. Each of these devices would be interfaced with the website such that data collected from these devices could be uploaded to the website where the data could be presented to the user or alternatively, the data could be shared with anyone that the user chooses to do so. For example, the user may desire to share the data with their health care provider, dietician or other individual(s). Further still, the user may choose to interface the data with a social media site such as Facebook.
In accordance with the disclosure, it is contemplated that one or both circuit boards along with the battery may be housed within a separate housing from the therapy providing device 200. In this embodiment, the circuit board(s) and battery would be coupled to the therapy providing device either through a cable connection or through a wireless connection. If a wireless connection is utilized, then the therapy providing device would include the necessary electronics disposed within its housing to facilitate the communication between the electronics module and the therapy providing device as well as a power source such as the battery.
Referring to
The driver assembly includes a portion which is configured to extend beyond the housing. The portion of the driver assembly which extends beyond the housing is configured to engage a user, a user's tissue or a user's skeletal frame, particularly the clavicle. The portion may extend beyond the housing between 0 mm and 1 mm, 0 mm and 1.5 mm, 0 mm and 1.75 mm, 0 mm and 2 mm, 0 mm and 2.1 mm, 0 mm and 2.2 mm, 0 mm and 2.3 mm 0 mm and 2.4 mm, 0 mm and 2.5 mm, 0 mm and 2.6 mm, 0 mm and 2.7 mm, 0 mm and 2.8 mm, 0 mm and 2.9 mm, 0 mm and 3.0 mm, 0 mm and 3.1 mm, 0 mm and 3.2 mm, 0 mm and 3.3 mm, 0 mm and 3.4 mm, 0 mm and 3.5 mm, 0 mm and 3.6 mm, 0 mm and 3.7 mm, 0 mm and 3.8 mm, 0 mm and 3.9 mm, 0 mm and 4.0 mm, 0 mm and 4.1 mm, 0 mm and 4.2 mm, 0 mm and 4.3 mm, 0 mm and 4.4 mm, 0 mm and 4.5 mm, 0 mm and 4.6 mm, 0 mm and 4.7 mm, 0 mm and 4.8 mm, 0 mm and 4.9 mm, 0 mm and 5 mm, 0 mm and 5.5 mm, 0 mm and 6 mm, 0 mm and 7 mm, 0 mm and 8 mm, 0 mm and 9 mm, 0 mm and 10 mm, 0 mm and 11 mm, 0 mm and 12 mm, 0 mm and 13 mm, 0 mm and 14 mm, 0 mm and 15 mm, 0 mm and 16 mm, 0 mm and 17 mm 0 mm and 18 mm, 0 mm and 19 mm and 0 mm and 20 mm, 0 mm and 30 mm, 0 mm and 40 mm, 0 mm and 50 mm. In a preferred embodiment the portion of the driver assembly extending beyond the housing is between about 0 mm and 5 mm and more preferably between 0 mm and 4 mm and most preferable between 0 mm and 3 mm.
It is further contemplated that the portion of the driver assembly which is configured to extend beyond the housing may be constructed of multiple pieces. In accordance with the disclosure, the projecting portion of the driver assembly may include a first portion affixed to the driver assembly and second portion, wherein the second portion is threadably attached to the first portion. The projection distance of the driver assembly beyond the housing can thereby by adjusted by screwing the second portion in/out of the first portion. In another example, the portion of the driver assembly projecting beyond the housing may comprise a first portion fixed to the driver assembly and a second portion, which is removable. The distance of the projection can be adjusted by changing the second portion, such that the second portion can be manufactured having multiple different heights. Lastly, it is contemplated that the housing may be configured such that the entire drive assembly can be moved within the housing, thereby allowing for adjustment of the height of the projecting portion of the driver assembly outside of the housing.
In yet another embodiment, the driver assembly 220 may be embodied as an electroactive polymer transducer 315 as shown in
It is further contemplated that the transducer 315 as described above may be further coupled to another assembly, wherein the other assembly would have an increased mass. Through use, the transducer would be activated by providing a voltage to the electrodes, thereby exciting the polymer, wherein the weighted assembly would be excited thereby delivering greater vibrational energy.
In accordance with another aspect of the present disclosure, the electroactive polymer transducer 315 can be formed to have a curved shape, or be attached to a housing having a curved shape, such that the housing or curved excited can be readily received by a user's anatomy, specifically the user's clavicle or collarbone.
The electroactive polymer transducer 315 of the present disclosure may be embodied in different geometric shapes. It is contemplated that the transducer 315 may be embodied in the form a circular shape, oblong shape, square, rectangular or other known geometric shapes. Further still, it is contemplated that the transducer may be formed with at least one bar-arm type of arrangement as shown in
Use of an electroactive polymer transducer as described above further includes a circuit driver 350, the circuit driver 350 may be incorporated into the first or second circuit boards 500/550 as described above. Alternatively, the circuit driver 350 as shown in
The circuit driver 350, may further include additional components such as an amplifier, a filter, a voltage step-up circuit, a charge controller, voltage step-down.
Further still it is contemplated that the driver assembly may be embodied as multiple elements, for example any combination of driver assemblies may be use, such as a combination of a haptic speaker and a piezo, a haptic speaker and an electro active polymer transducer, an electroactive polymer transducer and a piezo or multiples of the same driver type within the same housing. The examples provided herein should not be considered limiting in any manner. Alternatively, the driver assembly may be a vibrating motor or coin cell motor.
As described above and in accordance with the present disclosure, it is contemplated that two therapy providing devices 200 may be utilized together to provide therapy to a user, wherein the two therapy units may be interconnected with a physical connection. It is contemplated that one of the therapy devices may have a complete set of electronics disposed therein, wherein the complete set of electronics would include the communication, memory and other chipset(s) and associated circuitry. Wherein the other therapy providing module 200 could then include a simplified electronics module, wherein the simplified electronics module would not have the complete chipset of the complete electronics module. For example, the simplified electronics module would not need to have a battery charging circuit or other chips as well it may have less or no memory. By providing the other therapy providing device with a slimmed down electronics module a larger energy source may be fitted, through this arrangement the combined therapy providing devices 200 could be utilized for a longer time before the energy source would need to be replaced or recharged.
Further still, in an embodiment, the system may comprise at least two therapy providing devices 200, each therapy providing device having a housing 210. Wherein each of the housings includes a driver assembly, and one of the housings includes at least one circuit board and the other housing includes the energy source. The two housings are then coupled together through a cable connection. The cable may be permanently attached to each of the housings or may be detachably attached, wherein if detachably attached, locking connectors on the ends of the cables may be utilized to secure the cable ends to each of the therapy providing devices. By splitting the components between the two separate housings this allows for smaller sized housings. It is further contemplated that the cable connecting the two therapy providing devices may further include additional features such as a power switch, charging port or light emitting diodes to indicate device status. Additionally, the housing including the circuit board may additionally include a power source.
In another embodiment, it is contemplated that certain components of the therapy providing system as disclosed herein may be divided up into multiple housings. In an embodiment according to the present disclosure, the driver assembly 220 is disposed within a housing 210′ and the circuit board 500/550, energy source 240 are disposed in a second housing 210″. In this embodiment, two driver assemblies are configured to be coupled to the electronics in the second housing 210″. The driver assemblies may be coupled through a wired connection or through the use of a removable wired connection. For a removable wired connection, at least one wire extends from the housing 210″, the other end of the wire includes a connector, such as a snap connector, a magnetic power connector or magnetic connector (similar to APPLE's mag-safe power connector). The housing 210′ includes a similar connector as to the one on the end of the wire. In use, the user can dispose the housings 210′ onto their body as described herein in relation to the therapy providing system 100. The housing 210″ may be disposed onto a user's skin in a similar manner as described herein or alternatively, the user may wear a special clothing article, such as a pajama top, shirt, harness or other article capable of retaining the housing 210″. After disposing the housing 210″ onto their body, the user would then connect the free end of the wire to each housing 210′.
Referring now to
In accordance with the disclosure, the charging base 570 may be further embodied as another medical device or may incorporate other medical devices. It is contemplated that the base 570 may incorporate, or be incorporated into another medical device such as a pulse-oximetry meter, a blood pressure monitoring device, a glucose meter, an infusion pump, a glucose pump, sleep tracking device, temperature measuring device, or a sleep apnea device such as those offered by RESMED and RESPIRONICS, a thermostat such as the NEST, an internet access point. Presently, sleep apnea devices utilize a console which houses the electronics necessary to control a blower to deliver pressurized air to a patient interface. The patient interface may be embodied in the form of a full-face mask, nasal mask, oro-nasal mask, mouth mask, nasal prongs, or other suitable configurations know in the art. Also, any suitable headgear arrangements may be utilized to comfortably support the patient interface in a desired position. It is further contemplated that the charging base 570 may further include a medicine dispenser. For example, the charging base 570 may include a pill storage container in which the user can place medications which they take daily, the charging base 570 may be programmable to remind a user to take their medication on a daily basis, wherein such reminders can be embodied as a visual, audible or a visual/audio alarm. Alternatively, the reminder may be a text message or other electronic message. Additionally, the charging base can also monitor the compliance of the user, i.e., whether the user takes her medications or not and/or whether she charges/removes the therapy providing device from the charging base 570.
In yet another aspect of the present disclosure, referring now to
In yet another aspect of the present disclosure, the therapy providing device 200 may be incorporated into other devices which are configured to engage a patient's tissue and skeletal bones such as bone conduction hearing aids, one such example is being offered by Sonitus Medical under the tradename SOUNDBITE. Other such examples of devices into which the therapy providing device 200 of the present disclosure may be incorporated into also includes bone conducting headsets, such as those being developed and sold under the name AFTERSHOKZ and by PANASONIC. In this embodiment, the driver assembly and associated components, such as the electronics and energy source can be combined with the bone conducting headset assembly.
Referring now to
As shown in
In yet another embodiment, the thickness of the adhesive may be chosen so that a portion of the driver assembly couples with the adhesive to better enable the driver assembly to transmit vibrations to the user. Additionally, it is contemplated that over a period of time, the motion of the driver assembly may cause the adhesive to creep or otherwise become displaced such that a portion of the driver assembly becomes embedded within or surrounded by the adhesive
In yet another embodiment it is contemplated that the bandage of the present disclosure may be configured as a double sided adhesive member, where in the user would apply the double sided adhesive over the collar bone as described herein, they would then remove the backing off of the second side of the adhesive thereby exposing the adhesive. The therapy providing device 200 may be configured to then be directly adhered to the second side of the adhesive on the user's skin.
In another embodiment of the present disclosure, it is contemplated that the user may first apply an adhesive to their skin in the area of the collar bone. They would then apply either the therapy providing device 200 directly to this adhesive or apply a bandage onto the adhesive, wherein the bandage includes a fitting configured to engage a fitting of the therapy providing device as described herein.
It is further contemplated that the bandage may be left in place on the user's skin for a period of time of continuous wear, for example, 1 minute, 2 minutes, 3 minutes, 4 minutes, 5 minutes, 10 minutes, 12 minutes, 15 minutes, 20 minutes, 25 minutes, 30 minutes, 35 minutes, 40 minutes, 45 minutes, 50 minutes, 55 minutes, 1 hour, 1.25 hours, 1.5 hours, 1.75 hours, 2 hours, 2.25 hours, 2.5 hours, 2.75 hours, 3 hours, 3.25 hours, 3.5 hours, 3.75 hours, 4 hours, 5 hours, 5.25 hours, 5.5 hours, 5.75 hours, 6 hours, 6.25 hours, 6.5 hours, 6.75 hours, 7 hours, 7.25 hours, 7.5 hours, 7.75 hours, 8 hours, 8.25 hours, 8.5 hours, 8.75 hours, 9 hours, 9.25 hours, 9.5 hours, 9.75 hours, 10 hours, 10.25 hours, 10.5 hours, 10.75 hours, 11 hours, 11.25 hours, 11.5 hours, 11.75 hours, 12 hours, 12.25 hours, 12.5 hours, 12.75 hours, 13 hours, 13.25 hours, 13.5 hours, 13.75 hours, 14 hours, 14.25 hours, 14.5 hours, 14.75 hours, 15 hours, 15.25 hours, 15.5 hours, 15.75 hours, 16 hours, 16.25 hours, 16.5 hours, 16.75 hours, 17 hours, 17.25 hours, 17.5 hours, 18 hours, 18.25 hours, 18.5 hours, 18.75 hours, 19 hours, 19.25 hours, 19.5 hours, 19.75 hours, 20 hours, 20.25 hours, 20.50 hours, 20.75 hours, 21 hours, 21.25 hours, 21.5 hours, 21.75 hours, 22 hours, 22.25 hours, 22.5 hours, 22.75 hours, 23 hours, 23.25 hours, 23.75 hours, 1 day, 1.5 days, 2 days, 2.5 days, 3 days, 3.5 days, 4 days, 4.5 days, 5 days, 5.5 days, 6 days, 6.5 days, 7 days, 7.5 days, 1 week, 1.5 weeks, 2 weeks, 2.5 weeks, 3 weeks 3.5 weeks or longer. If the bandage is left in place, the bandage is constructed to be capable of being exposed to water, soap and the like when the user showers.
Alternatively, a bandage large enough to cover the entire housing of the therapy providing device 200 may be utilized. In this embodiment, the bandage would hang over the edge of the housing by a sufficient amount, such that when the therapy providing device 200 is placed against the tissue of the user, the bandage could be affixed to the tissue to hold the therapy providing device in a desired position. In this embodiment, the bandage may include an aperture, an opaque section or otherwise transparent section, such that when the bandage is placed over the therapy providing device 200, the button 260, LEDs 262 and charging pins/ports 265 on the top surface of the housing 210 of the therapy providing device 200 described above are visible and accessible if the housing includes such components. Such as bandage maybe constructed to further include a one-way membrane, wherein moisture under the bandage may be transported or migrate from the tissue surface through the bandage, however, the bandage would not allow fluid to pass from the outside to the therapy providing device 200 or the user's tissue.
Referring now to
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In another embodiment (not shown) the bandage may include an aperture formed therethrough, wherein the metallic member 292 would be disposed about the aperture. The aperture is sized to receive a portion of the therapy providing device 200 therein. It is further contemplated that the therapy providing device may include a second bandage or an enlarged surface similar in size to the bandage 400. The enlarged surface would contain magnets 290 as described above; therefore, when the therapy providing device 200 is disposed within the aperture of the bandage 400, the enlarged surface covers the bandage.
In further embodiments, the magnets and the metallic members may be interchanged, wherein the bandage contains the magnets and the housing may be a metallic member, a portion may be metallic or a portion may be magnetic. Additionally, instead of utilizing magnets and metallic members, other known detachable systems may be utilized, for example a hook and loop configuration or reusable adhesive surface or snaps or the like.
Referring now to
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As shown in
In accordance with the present disclosure, it may be desirable to choose a cover layer, which has elastic properties. The elastic properties of the cover layer may be beneficial in allowing the metallic insert/magnet a degree of movement within the aperture, such that when the bandage is disposed on a user and the therapy providing device is attached to the bandage, the elastic cover layer of the bandage provides some movement of the therapy providing device and the bandage. Additionally, the elasticity of the cover layer allows for the amount of force applied to the user by the therapy providing device to be controlled or adjusted based on material selection. Further still the cover layer may be formed such that it includes a portion of a hook and loop fastener, wherein the therapy providing device would include the second component of the hook and loop fastener, such that when brought together the two would become detachably attached.
In yet another embodiment not shown, the magnet member or metallic members 430 may be directly placed onto the glue later 1000 and then the cover layer 1003 can be directly placed over the top of the glue layer, thereby encapsulating the member 430. In this embodiment the bandage would be composed of only two layers, where the glue support layer 1002 would be eliminated.
In use, the user would place the bandage 420, 420′ and 420″ onto their skin, wherein the user can use the aperture 430, 431′, 431″ to properly align the bandage in the example where the therapy providing device is placed over the clavicle. The user can place the bandage, either substantially parallel, parallel, substantially perpendicular or perpendicular to the clavicle. The glue layer of the bandage 420, 420′ or 420″ may be a re-usable adhesive, such as that described above and commonly utilized on tens electrodes, wherein the glue layer allows for repositioning of the bandage. After placement of the bandage 420, 420′ or 420″, the therapy providing device, having a housing shown in
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It shall be understood that the various features of the multiple bandage embodiments maybe combined together into a single embodiment and that each bandage figure should not be considered limiting in any manner.
In another embodiment, not shown, it is contemplated that certain components/parts of the therapy providing system as described herein may be located in different locations. For example, it is contemplated that the bandage may be designed to include the energy source, thereby eliminating the need for an energy source to be disposed within the housing of the therapy providing device. By removing the battery from the housing, the housing could be reduced in size. In this embodiment, the bandage may be designed such that the glue layer may be removable and replaceable. As such, the bandage would further include necessary components to enable charging of the battery disposed within the bandage.
In another embodiment, not shown, the bandage may include at least one circuit board disposed within the bandage. As described above, by moving the circuit board from the housing to the bandage, the size of the housing can be reduced. Alternatively, the circuit board disposed within the bandage may be utilized to enable the therapy providing device to be powered on. It shall be understood that the bandage may be manufactured to include both the energy source as well as the circuit board or any combination thereof.
The bandages disclosed herein may be fabricated from die-cutting, stamping, cutting, laser cutting, water jet cutting or other known manufacturing methods.
The bandages shown and described herein may be constructed using a die cutting process. If the die cutting process is used, then the bandage may be manufactured according to the following process.
Step 1, apply a sheet of the glue support layer to the die;
Step 2, apply force to the die and glue support layer, to form the insert apertures for the insert as well as create alignment apertures in sheet of the glue support layer to enable further die cutting processes;
Optional step 3, align sheet of glue support layer onto a set of alignment pins using the alignment apertures onto a die to form additional apertures in glue support layer to aid in flexibility and breathability;
Step 4, apply force to the die and the glue support layer to form the additional apertures;
Step 5, remove the glue support layer from the die;
Step 6, apply the cover layer to the glue support layer sheet;
Step 7, align the glue support layer/cover layer sheet with a die using the alignment apertures to cut an aperture in foam and cover layer;
Step 8, apply force to the die and glue support/cover layer sheet to form the aperture, remove the support/cover layer sheet from the die;
Step 9, disposed metallic inserts/magnets within the insert apertures formed in Step 2;
Step 10, apply the glue layer to the glue support layer;
Step 11, position the cover/glue support and glue layer within a die using the alignment apertures;
Step 12 apply force to cut through all layers of the bandage and to cut the outer shape of bandage; and
Step 13 package the completed bandage.
In yet another aspect of the disclosure, as described herein the magnets, which may be positioned in the device housing, the bandage or both, may be utilized to control the function of the therapy providing device 200. In this example, at least one of the magnets can be used as a switch to control or complete a power circuit. The power circuit can be activated such as to power the therapy providing device 200 on, thereby initiating therapy. If the magnetic connection is broken or disrupted, then the therapy providing device would be powered off. In this embodiment, the magnets within the therapy providing device may be coupled together with a conductive element or conductively coupled to a circuit board. Additionally, the bandage can include a coupling between the magnets/metallic members. The coupling on the bandage may be a wire connected between the elements, or a metallic strip in which the magnets/metallic members are in contact with. Further still, the magnets/metallic members may be coupled together through the use of a conductive ink/paint, which is disposed on a layer of the bandage, thereby electrically coupling the magnets/metallic members. The connection between the magnet/metallic members could be measured to be a voltage, impedance, resistance, magnetic gauss or other measurable parameter. The program executed by the processor can utilize this measurement to power on/off the therapy providing device. It is further contemplated, that in addition to the above, the magnet/metallic member within the device or bandage may be manufactured with specific properties, such that the therapy providing device will only operate with original equipment manufacturing products, thereby preventing the therapy providing device 200 from being utilized with non-approved or counterfeit bandages. For example, the magnet may be manufactured with specific magnetic field properties, these properties would be compared to a programmed property, if the properties match, then the device would be allowed to be turned on, if the properties do not match, then the device would not be able to be powered on, whereby an error code may be displayed on the LEDs or spoken through the driver assembly. A benefit of utilizing the magnets to switch the device on/off is that the user does not have to activate any buttons on the device, additionally, the device can be simplified through the elimination of the button on the therapy providing device as described herein. Another benefit is the preservation of battery life of the device, as the device will be powered off as soon as the magnetic connection is broken. Additionally, if the therapy providing device is being utilized at night time during sleep and the device becomes dislodged from the user, the device will automatically power off, thus providing an additional safety feature.
It is further contemplated that a magnetic switch may be incorporated into the therapy providing device, wherein the switch would be moved to a closed or open position when the therapy providing device is brought into close proximity with a bandage containing a magnetic member, thereby allowing the therapy device to be powered on or to be automatically powered on. Further still, the magnetic switch may be utilized during charging of the therapy providing device. As described herein, a separate charging base may be provided, as previously described, to charge the energy source within the therapy providing device. It is contemplated that the charging station may include at least one magnet to align the therapy providing device with a portion of the charging station, wherein the magnetic switch may be activated by the magnet of the charging station, whereby the energy source of the therapy providing device can then be charged. Furthermore, as described above, the charging station may include at least two magnets, wherein the magnets are coupled to each other such that a signal can pass between them, the signal can be voltage, impedance, resistance and the like. As such, when the therapy providing device is placed onto the charging station, the energy source of the therapy providing device will only be charged after a program of the therapy providing device confirms a connection of the magnets of the charging station and the magnets of the therapy providing device. As used herein and throughout the application, it shall be understood that the magnets may be replaced with metallic members or other types of materials which may exhibit magnetic properties or may be attracted to magnets.
Further still, as shown in
Further still, it is contemplated, that the therapy providing device 200 and/or bandage may include a security feature, such as an optical scanner disposed within the therapy providing device, such that the optical scanner is configured to scan a QR code, bar code or other coded printed on the bandage or bandage packaging. As described above, this combination of a scanner and specific code can be utilized to control the activation of the therapy providing device 200. Additionally, the use of a security code/barcode can be combined with the magnetic activation of the therapy providing device 200 as described above to ensure that the bandage being utilized is an approved product that has been designed to be specifically utilized with the therapy providing device 200 and that the bandage is not a third-party un-approved product or a counterfeit product.
It is contemplated that other types of security systems can be utilized to achieve the same or similar functions. For example, the bandage may include a protrusion (not shown) that projects above the surface of the bandage, the protrusion would be received within an aperture of the second surface of the housing where it would activate a switch within the housing. Another example would be the use of an electronic circuit or chip disposed upon or within the bandage, the circuit or chip would interface with the therapy providing device, thereby completing a circuit to enable activation of the therapy providing device.
The bandage may further include a metallic magnetic strip, similar to a credit card, whereby the therapy providing device or base station 570 may include a strip reader. In use the bandage(s) would be passed through the strip reader in order to activate the therapy providing device. The strip may include embedded information such as a serial number, prescribed therapy information, patient information or may include a security code that is utilized to unlock the therapy providing device or base station. Additionally, information may be collected each time the bandage is swiped to provide information to a physician or payer/payor to determine usage of the therapy providing device(s).
Additionally, the bandage and therapy device may contain RFID components, wherein when brought together the therapy device would be activated. It is contemplated that the therapy providing device may be “coded” to work with specific bandages, similar to the manner in which glucose meters are “coded” to each package of test strips. In this embodiment, a “code bandage” would be provided, wherein the therapy providing device would include a reader to read the code bandage, such that the code bandage would cause a change in the program of the therapy providing device. The code bandage may include a bar code, QR code, RFID component, a computer chip, a series of raised protrusions or similar designs to transmit a code to the therapy providing device. In each of the embodiments above the therapy providing device 200 would include an appropriate reader. It may be preferred to provide a “code bandage” with each package of bandages to be utilized. Alternatively, the therapy providing device may be provided with a certain number of bandages in a package, whereby when the bandages are expended the therapy providing device will cease to turn on until a new package of bandages is purchased, wherein the new package of bandages includes a code bandage to re-activate the therapy providing device. As described above, the base station 570 may include a QR or barcode reader assembly, wherein prior to use of the therapy providing system 100 of the present disclosure, the user would scan the bandages and/or the therapy providing devices prior to use. The scanning process may be utilized to control the activation of the therapy providing device or control the activation of the therapy providing device.
In accordance with the disclosure, the bandage may include a temperature sensitive device, such that when the bandage is placed onto the user, the temperature sensitive device would provide a visual feedback of the user's temperature. The feedback may be in the form of a color display or a LED/LCD readout or show up as a graph or timeline chart. Additionally, it is contemplated that the therapy providing device 200 may include and optical reader, wherein the optical reader may be configured to “read” the temperature display. By reading the temperature off of the bandage, the therapy providing device 200 may be turned off if the temperature range read is outside of a pre-determined range. Such range may be between 85 and 105 degrees Fahrenheit. The reading of the temperature may also be utilize to determine if the user has a fever, such fever may be an indication of a medical problem such as a hypertensive crisis or Cushings Syndrome or other medical problem. Furthermore, by limiting operating window of the therapy providing device to a temperature range prevents the device from being activated until placed onto a user. For example, if the temperature range is 85 to 105 degrees Fahrenheit, then the device could not be activated when not disposed on the user, as such the user would not be able to “fake” therapy. This may be important in the case where insurance would be paying for usage of the therapy providing device.
It is further contemplated that the charging/base station 570 may include a bar code reader, RFID, Zigbee or other means which can be utilized to scan the code bandage. Additionally, it is contemplated that the base station 570 may be necessary to utilize the therapy providing device, wherein prior to use the therapy providing devices must be placed into/onto or nearby the base station in order to be activated. Additionally, it is contemplated that the bandages may also be placed in contact with, near or be scanned by the base station in order for the therapy providing devices to be activated. In another embodiment the computing device 300 may be incorporated into the base station 570, wherein the therapy cycle may be controlled by the base station 570.
In yet another embodiment, the therapy providing device may include at least one pressure sensor or flex sensor disposed adjacent the second surface of the housing, such that when the therapy providing device is coupled to a bandage on a user's skin, the pressure sensor or flex sensor would provide data indicating that the therapy providing device is placed onto a user's body. At this time, the therapy providing device may then be powered on to deliver therapy. The device may be powered on manually, automatically in response to the pressure sensor/flex sensor data or in response to a programmed parameter. The pressure/flex sensor(s) can provide an impedance/resistance data point which can be utilized by the program to determine the position of the therapy providing device. For example, the program could compare the resistance from the sensor against a look up table to determine if the therapy providing device is disposed on a user, disposed on the charging station and determine if the therapy device should be powered on or if charging should be enabled. Alternatively, the pressure sensor or flex sensor could be integrated into the bandage, whereby a conductive pad/pin arrangement would allow data from the pressure/flex sensor to be transferred to the therapy providing device.
As indicated above, the therapy providing device may be embodied in a kit form, wherein a pair of therapy providing devices would be provided along with a certain number of bandages. The bandages supplied may be for 1 week, 2 weeks, 3 weeks, 1 month, 2 months, 3 months, 4 months, 5 months, 6 months, 7 months, 8, months, 9, months, 10 months, 11 months or 1 year of therapy. As such it is contemplated that at least two bandages will be utilized for each therapy session, however, depending upon the schedule of therapy, up to four bandages may be utilized for each therapy session. As such, packages of bandages having a certain number of bandages can be provided depending upon the intended or prescribed therapy routine.
It is further contemplated that the metallic members/magnets as described herein can be replaced with other removable/detachable assemblies such as snap connectors, Velcro, twist-lock connectors or other similar connectors.
Referring now to
The support structure 600 further includes a ball and cup joint 660 at the distal ends 640 of the arms 630. The ball and cup joint 660 is arranged to hold the therapy providing device 200 and allows a user to align the therapy providing device 200 substantially parallel to a surface of the user at the desired location to insure that as much as possible of the therapy providing device 200 is in contact with the user. It is contemplated that other types of flexible joints may be utilized in place of a ball and cup joint, for example a living hinge assembly or the like.
The support structure 600 further includes a pad 650 connected to the arms 630. In accordance with embodiments of the present disclosure, the pad may contain the electronics module 320 and the power source.
The arms 630 of the support structure 600 can also be configured to include a spring force to push the therapy providing device 200 against the body. For example, the arms 630 of the support structure 600 depicted in
Referring now to
The support structures 600 and 700 can be made of an elastic material. The elasticity of the design provides for a spring or clamping force, such that the support structure and therapy providing devices remain in position during use.
The support structures described herein can be configured to fit snugly without being too compressive on the body, are straightforward to put on over the shoulders or around the torso, and can be worn underneath clothing without significantly altering the profile of the clothing.
Referring now to
As shown in
In accordance with the embodiment shown in
It is further contemplated that the support structure 800 in accordance with the present disclosure may include additional features. For example, a heating element may be incorporated into the support structure 800, whereby the heating element may be utilized by the user to address sore muscles or neck pain.
Referring now to
Referring now to
Referring now to
Referring now to
Referring now to
As shown in
Referring now to
Additionally, the clothing devices described above may further include an additional pocket or pockets to receive the computing device, or in embodiments wherein the electronics or energy source are separate from the therapy providing device, pockets or other retention means to retain these additional components.
The clothing devices may further include a structure formed therein or attached thereto (not shown) wherein the structure is configured to apply a downward force upon the therapy providing device(s). Structures similar to those shown in
In accordance with the present disclosure, the therapy providing device 200 may include addition features. One such additional feature can be the inclusion of a thermometer to track the user's temperature during use. Another additional feature can be the inclusion of a sleep sensor or sleep tracking program, wherein the therapy providing device can be utilized to track the user's sleep. For example, the sleep program may utilize the GPS/accelerometer of the therapy providing device to track movement during sleep, wherein the sleep program could further utilize the temperature data as well. Another aspect of the disclosure could be to utilize the therapy providing device to be further utilized to diagnose sleep apnea, wherein the therapy providing device could further include a microphone to enable audio recording of the user's breathing during sleep. Additionally, the microphone recording of the breathing can be combined with the accelerometer data or GPS/tilt data to correlate the breathing recordings to the specific user. Further still, the microphone could be utilized to turn the therapy providing device on/off. In this embodiment, the computer readable program maybe configured to respond to voice commands, such that a user could power the therapy providing device on/off with specific voice commands.
In yet another embodiment, the microphone, coupled with the processor can be utilized to detect specific sounds, which when detected will power the therapy providing device on/off. For example, the microphone may be configured to detect a user's heartbeat, thus, based on the detection of heart beat the therapy providing device may be powered on/off. The microphone could also be utilized to detect and determine a user's heart rate, as such, the device could be powered on/off based on a pre-set heart rate parameter. For example, if the user's heart rate is outside of a pre-set parameter, such as 180 BPM (beats per minute) the device may be powered off for safety.
Referring now to
In accordance with the present disclosure, the computing device 300 is configured to run a program 820. In accordance with the present disclosure, the program 820 is configured to communicate with the therapy device 200. The communication between the program 820, computing device 300 and the therapy device 200 may be conducted using Bluetooth, wifi, ZigBee, NFC, RFID, ANT+, 3G/4G, cellular connection or other known wireless communication protocols. Alternatively, the computing device may be coupled to at least one of the therapy devices through a cable connection.
In an alternative embodiment, the program 820 is stored on memory located within the memory of the therapy providing device 200. The program maybe initiated manually through the use of a physical button pressed by the user. Alternatively, the program 820 may be initiated automatically by a timer located within the therapy providing device 200. The timer may further utilize data inputs from an accelerometer/compass or tilt sensor to indicate when the user is in a prone position to initiate the program 820. Further still, the timer may receive input from an impedance sensor indicating whether the therapy providing device 200 is in proper placement on the users body. The program would then be initiated based on the inputs received. The device may be activated further by the light sensor. For example, when the light sensor detects darkness, the therapy providing device can be powered on either manually or automatically. Alternatively, the light sensor may detect the user's skin wherein the therapy providing device may be powered on, the therapy providing device may be powered on manually, automatically or in response to the computer readable program. either from the darkness against the skin. The device may be activated from the reduced light from the users surroundings, for example when the user is sleeping. Further still, the bandage may include a reflective portion, wherein the light sensor receives a reflectance from the reflective portion of the bandage to power the therapy providing device on/off.
In certain embodiments, the program 820 is pre-configured to deliver therapy using the therapy providing device through pre-programmed parameters. The HCP may adjust the therapy parameters within the program 820, such that the therapy provided to the user may be customized to the user. The customization of the therapy may be changes to the wavelength, amplitude, duration, start/stop times. The customization may be done by the HCP while providing services to the patient, for example, the HCP may apply the therapy providing device to the patient, initiate therapy and monitor the patient's response. Through this active monitoring, the HCP may change the parameters of the program to elicit a response in the patient. For example, it is contemplated that certain patients may have different bone densities; therefore the therapy provided by the device may need to be adjusted accordingly. It is further contemplated, that once programmed, the user cannot change the therapy parameters of the program, or alternatively, certain parameters or all parameters may be open to change by the end user or remotely. Alternatively, the HCP, after determining the best therapy parameters, can choose from multiple programs stored within memory of the therapy providing device. Further still, the HCP may be provided with a dedicated programming device, or may couple the device to a personal computer, smartphone, tablet or other internet enabled device, such that the HCP can utilize the dedicated programmer or download over a secure internet connection, programs to be uploaded into the therapy providing device.
Referring now to
At Box 830, the user activates the program on the computing device 800 or therapy providing device 200. Or the therapy providing device is automatically activated when placed on the user's body.
At Box 840, the program checks the time on the computing device 800 or internally from the clock circuit of the therapy providing device 200.
At Box 850, the program determines whether to turn the therapy providing device on based upon the time check in Box 840. If the time is before a pre-programmed time or a user set time, then the program returns to Box 840. If the time is after the pre-set time or user set time, then the program turns the therapy providing device on. In accordance with the disclosure, if the time is received from the computing device, a user may adjust the time of the computing device, for example if the computing device is moved from one time zone to another. Alternatively, the computing device may automatically update the time.
At Box 860, the therapy providing device 200 is provided with a signal generated by the program and transmitted from the computing device 800 through a selected transmission method. In alternative embodiments, the therapy providing device contains a processor and memory, wherein a program is retained within the memory of the therapy providing device. In this embodiment, the signal provided by the computing device 800, is a power on/off signal, wherein once powered on the program residing within the memory of the therapy providing device will begin to run.
At Box 870, the therapy device provides therapy to the patient. In the process of providing therapy, a signal is transmitted to the therapy device 200 by the computing device 800 through as directed by the program 820, or as described above, the program residing in the memory of the therapy providing device runs. In one embodiment, the therapy is applied for a set period of time. In alternative embodiments, the time duration of the therapy may be determined based upon data received from other sensors disposed upon the user or about the user. In yet another embodiment, the user may manually deactivate the therapy providing device/program.
At Box 880, the therapy is stopped. The therapy may be stopped based upon a time event, motion event, manually by the user, automatically by the program.
During each of the steps described above and shown in the flow diagram of
According to the disclosure, the program includes a non-transitory computer readable medium having computer executable program code embodied thereon, the computer executable program code configured to send appropriate signals to the circuit board(s) 500/550 to provide therapy in accordance with the methods of the present disclosure utilizing the therapy providing device 200 of the present disclosure.
In accordance with the present disclosure, methods of use of the present disclosure will be described below. The methods described shall be considered to be exemplary and should not be considered limiting in any manner.
In accordance with one embodiment of the present disclosure, the therapy device includes a driver assembly, wherein the driver assembly is embodied as a speaker as shown in
In accordance with embodiments of the present disclosure, the frequencies contemplated for use with the present disclosure range between 0 Hz to 20,000 Hz, 0 Hz and 10,000 Hz, 0 Hz and 5,000 Hz, 0 Hz and 2,500 Hz, 0 Hz and 1,750 Hz, 0 Hz and 875 Hz, 0 Hz and 435 Hz, 0 Hz and 200 Hz, 0 Hz and 150 Hz, 1 Hz and 150 Hz, 2 Hz and 150 Hz, 3 Hz and 150 Hz, 4 Hz and 150 Hz, 5 Hz and 150 Hz, 6 Hz and 150 Hz, 7 Hz and 150 Hz, 8 Hz and 150 Hz, 9 Hz and 150 Hz, 10 Hz and 150 Hz, 11 Hz and 150 Hz, 12 Hz and 150 Hz, 13 Hz and 150 Hz, 14 Hz and 150 Hz, 15 Hz and 150 Hz, 16 Hz and 150 Hz, 17 Hz and 150 Hz, 18 Hz and 150 Hz, 19 Hz and 150 Hz, 20 Hz and 150 Hz, 21 Hz and 150 Hz, 22 Hz and 150 Hz, 23 Hz and 150 Hz, 24 Hz and 150 Hz, 25 Hz and 150 Hz, 26 Hz and 150 Hz, 27 Hz and 150 Hz, 28 Hz and 150 Hz, 28 Hz and 150 Hz, 29 Hz and 150 Hz, 30 Hz and 150 Hz, 31 Hz and 150 Hz, 32 Hz and 150 Hz, 33 Hz and 150 Hz, 34 Hz and 150 Hz, 35 Hz and 150 Hz, 36 Hz and 150 Hz, 37 Hz and 150 Hz, 38 Hz and 150 Hz, 39 Hz and 150 Hz, 40 Hz and 150 Hz, 41 Hz and 150 Hz, 42 Hz and 150 Hz, 43 Hz and 150 Hz, 44 Hz and 150 Hz, 45 Hz and 150 Hz, 46 Hz and 150 Hz, 47 Hz and 150 Hz, 48 Hz and 150 Hz, 49 Hz and 150 Hz, 50 Hz and 150 Hz, 51 Hz and 150 Hz, 52 Hz and 150 Hz, 53 Hz and 150 Hz, 54 Hz and 150 Hz, 55 Hz and 150 Hz, 56 Hz and 150 Hz, 57 Hz and 150 Hz, 58 Hz and 150 Hz, 59 Hz and 150 Hz, 60 Hz and 150 Hz, 61 Hz and 150 Hz, 62 Hz and 150 Hz, 63 Hz and 150 Hz, 64 Hz and 150 Hz, 65 Hz and 150 Hz, 66 Hz and 150 Hz, 67 Hz and 150 Hz, 68 Hz and 150 Hz, 69 Hz and 150 Hz, 70 Hz and 150 Hz, 71 Hz and 150 Hz, 72 Hz and 150 Hz, 73 Hz and 150 Hz, 74 Hz and 150 Hz, 75 Hz and 150 Hz, 76 Hz and 150 Hz, 77 Hz and 150 Hz, 78 Hz and 150 Hz, 79 Hz and 150 Hz, 80 Hz and 150 Hz, 81 Hz and 150 Hz, 82 Hz and 150 Hz, 83 Hz and 150 Hz, 84 Hz and 150 Hz, 85 Hz and 150 Hz, 86 Hz and 150 Hz, 87 Hz and 150 Hz, 88 Hz and 150 Hz, 89 Hz and 150 Hz, 90 Hz and 150 Hz, 91 Hz and 150 Hz, 92 Hz and 150 Hz, 93 Hz and 150 Hz, 94 Hz and 150 Hz, 95 Hz and 150 Hz, 96 Hz and 150 Hz, 97 Hz and 150 Hz, 98 Hz and 150 Hz, 99 Hz and 150 Hz, 100 Hz and 150 Hz, 101 Hz and 150 Hz, 102 Hz and 150 Hz, 103 Hz and 150 Hz, 104 Hz and 150 Hz, 105 Hz and 150 Hz, 106 Hz and 150 Hz, 107 Hz and 150 Hz, 108 Hz and 150 Hz, 109 Hz and 150 Hz, 110 Hz and 150 Hz, 111 Hz and 150 Hz, 112 Hz and 150 Hz, 113 Hz and 150 Hz, 114 Hz and 150 Hz, 115 Hz and 150 Hz, 116 Hz and 150 Hz, 117 Hz and 150 Hz, 118 Hz and 150 Hz, 119 Hz and 150 Hz, 120 Hz and 150 Hz, 121 Hz and 150 Hz, 122 Hz and 150 Hz, 123 Hz and 150 Hz, 124 Hz and 150 Hz, 125 Hz and 150 Hz, 126 Hz and 150 Hz, 127 Hz and 150 Hz, 128 Hz and 150 Hz, 129 Hz and 150 Hz, 130 Hz and 150 Hz, 131 Hz and 150 Hz, 132 Hz and 150 Hz, 133 Hz and 150 Hz, 134 Hz and 150 Hz, 135 Hz and 150 Hz, 136 Hz and 150 Hz, 137 Hz and 150 Hz, 138 Hz and 150 Hz, 139 Hz and 150 Hz, 140 Hz and 150 Hz, 141 Hz and 150 Hz, 142 Hz and 150 Hz, 143 Hz and 150 Hz, 144 Hz and 150 Hz, 145 Hz and 150 Hz, 146 Hz and 150 Hz, 147 Hz and 150 Hz, 148 Hz and 150 Hz, 149 Hz and 150 Hz, 150 Hz and 150 Hz, 60 Hz and 100 Hz, 61 Hz and 100 Hz, 62 Hz and 100 Hz, 63 Hz and 100 Hz, 64 Hz and 100 Hz, 65 Hz and 100 Hz, 66 Hz and 100 Hz, 67 Hz and 100 Hz, 68 Hz and 100 Hz 69 Hz and 100 Hz, 70 Hz and 100 Hz, 60 Hz and 99 Hz, 61 Hz and 99 Hz, 62 Hz and 99 Hz, 63 Hz and 99 Hz, 64 Hz and 99 Hz, 65 Hz and 99 Hz, 66 Hz and 99 Hz 67 Hz and 99 Hz, 68 Hz and 99 Hz, 69 Hz and 99 Hz and 70 Hz and 99 Hz, and 61 Hz and 98 Hz, 62 Hz and 98 Hz, 63 Hz and 98 Hz, 64 Hz and 98 Hz, 65 Hz and 98 Hz, 66 Hz and 98 Hz, 67 Hz and 98 Hz, 68 Hz and 98 Hz, 69 Hz and 98 Hz and 70 Hz and 98 Hz.
In a preferred embodiment the signal causes the driver assembly to vibrate at a frequency or sweep through a range of frequencies between about 40 Hz and 150 Hz, more preferably between 50 Hz and 125 Hz, most preferably between about 60 Hz and 115 Hz. In accordance with the present disclosure, a therapeutic response has been achieved utilizing a frequency range between 65 Hz and 100 Hz.
It is further contemplated that these frequencies may be doubled and still achieve the therapeutic lowering of blood pressure in accordance with the present disclosure. It is further contemplated that these frequencies may be halved and still achieve the therapeutic lowering of blood pressure in accordance with the present disclosure.
In additional embodiment of the present disclosure, the driver assembly may vibrate or sweep or step or transition between frequencies of between: 60 Hz, 61 Hz, 62 Hz, 63 Hz, 64 Hz, 65 Hz, 66 Hz, 67 Hz, 68 Hz, 69 Hz, 70 Hz, 71 Hz, 72 Hz, 73 Hz, 74 Hz, 75 Hz, 76 Hz, 77 Hz, 78 Hz, 79 Hz, 80 Hz, 81 Hz, 82 Hz, 83 Hz, 84 Hz, 85 Hz, 86 Hz, 87 Hz, 88 Hz, 89 Hz, 90 Hz, 91 Hz, 92 Hz, 93 Hz, 94 Hz, 95 Hz, 96 Hz, 97 Hz, 98 Hz, 99 Hz and 100 Hz.
Referring now to
Other contemplated frequencies in accordance with the present disclosure are: from 65.4 Hz to 98 Hz on one therapy providing device and from 65.4 Hz to 98 Hz on the other device, such frequencies result in a Binaural frequency of zero between the devices. Another pair of frequencies are from 65.4 Hz to 96 Hz on one therapy providing device and from 65.4 Hz to 98 Hz on the other device, such frequencies result in a Binaural frequency of 1 to 2 Hz on between the devices. Another pair of frequencies are from 40 Hz to 98 Hz on one therapy providing device and from 40 Hz to 98 Hz on the other device, such frequencies result in a Binaural frequency of zero between the devices. Another pair of frequencies are from 40 Hz to 80 Hz on one therapy providing device and from 40 Hz to 80 Hz on the other device, such frequencies result in a Binaural frequency of zero between the devices. And lastly, another pair of frequencies are from 40 Hz to 79 Hz on one therapy providing device and from 41 Hz to 81 Hz on the other device, such frequencies result in a Binaural frequency of between 1 and 2 Hz between the devices.
Additionally it is contemplated that in use, wherein two therapy provided devices are utilized, the frequencies provided by each of the two therapy providing devices may have different slopes. Such that as the therapy providing device(s) transition through the frequencies, one of the device may move between the frequencies faster or slower than the other device.
It is further contemplated that multiple signals utilizing separate frequencies may be transmitted by the program to the speaker. For example, one signal may be transmitted at one frequency and a second signal at another frequency. The signals may be transmitted simultaneously, independently or in an alternating fashion. If at least two therapy providing devices 200 are utilized, then one therapy providing device 200 may receive a first signal and the other receives a second signal.
In one embodiment, at least two therapy providing devices 200 are utilized. In use a signal will be sent to one of the two therapy providing devices 200, causing the speaker to emit a signal having a chosen frequency or range of frequencies. The signal is transmitted to a first therapy providing device 200 for a pre-determined period of time. After such time, the signal is terminated. Upon termination of the first signal, a second signal is generated and transmitted to the other therapy providing device. This second signal causes the speaker to emit a signal having a chosen frequency or range or frequencies. The chosen frequency may be the same as that transmitted to the first therapy providing device or it may be at a different frequency. The second signal will be transmitted to the second therapy providing device for a pre-determined period of time. After such time, the signal is terminated. The program will continued to run, however, during this time no signal will be transmitted to either therapy providing device 200, thereby creating a pause between activation of the therapy providing devices 200. After the pre-determined time period of the pause has passed, the program will then enter a loop and repeat the process described above. This pattern of therapy will repeat for as long as the program has been instructed to do so.
In the embodiment where two therapy providing devices 200 are utilized, each of the devices deliver a waveform to the user's left and right clavicle. The waveform is transmitted from the speaker in each of the therapy providing devices to the user's clavicles. The waveform is transmitted through the clavicle on the left and right side, where both waves meet at the sternum to create a standing wave.
Further still, in accordance with the present disclosure, the amplitude of the signal can be adjusted to adjust the sound pressure generated by the driver assembly 220 of the therapy providing device 200. It is contemplated that the amplitude may be doubled or increased even more to deliver the therapy in accordance with the present disclosure. In accordance with the disclosure, the therapy providing device 200 may be configured to provide a sound pressure between: 0 to 150 decibels, 0 to 100 decibels, 0 to 99 decibels, 0 to 98 decibels, 0 to 97 decibels, 0 to 96 decibels, 0 to 95 decibels, 0 to 94 decibels, 0 to 93 decibels, 0 to 92 decibels, 0 to 91 decibels, 0 to 90 decibels, 0 to 89 decibels, 0 to 88 decibels, 0 to 87 decibels, 0 to 86 decibels, 0 to 85 decibels, 0 to 84 decibels, 0 to 83 decibels, 0 to 82 decibels, 0 to 81 decibels, 0 to 80 decibels, 0 to 79 decibels, 0 to 78 decibels, 0 to 77 decibels, 0 to 76 decibels, 0 to 75 decibels, 0 to 74 decibels, 0 to 73 decibels, 0 to 72 decibels, 0 to 71 decibels, 0 to 70 decibels, 0 to 69 decibels, 0 to 68 decibels, 0 to 67 decibels, 0 to 66 decibels, 0 to 65 decibels, 0 to 64 decibels, 0 to 63 decibels, 0 to 62 decibels, 0 to 61 decibels, 0 to 60 decibels, 0 to 59 decibels, 0 to 58 decibels, 0 to 57 decibels, 0 to 56 decibels, 0 to 55 decibels, 0 to 54 decibels, 0 to 53 decibels, 0 to 52 decibels, 0 to 51 decibels, 0 to 50 decibels, 0 to 49 decibels, 0 to 48 decibels, 0 to 47 decibels, 0 to 46 decibels, 0 to 45 decibels, 0 to 44 decibels, 0 to 43 decibels, 0 to 42 decibels, 0 to 41 decibels, 0 to 40 decibels, 0 to 39 decibels, 0 to 38 decibels, 0 to 37 decibels, 0 to 36 decibels, 0 to 35 decibels, 0 to 34 decibels, 0 to 33 decibels, 0 to 32 decibels, 0 to 31 decibels, 0 to 30 decibels, 0 to 29 decibels, 0 to 28 decibels, 0 to 27 decibels, 0 to 26 decibels, 0 to 25 decibels, 0 to 24 decibels, 0 to 23 decibels, 0 to 22 decibels, 0 to 21 decibels, 0 to 20 decibels, 0 to 19 decibels, 0 to 18 decibels, 0 to 17 decibels, 0 to 16 decibels, 0 to 15 decibels, 0 to 14 decibels, 0 to 13 decibels, 0 to 12 decibels, 0 to 11 decibels, 0 to 10 decibels, 0 to 9 decibels, 0 to 8 decibels, 0 to 7 decibels, 0 to 6 decibels, 0 to 5 decibels, 0 to 4 decibels, 0 to 3 decibels, 0 to 2 decibels, 0 to 1 decibels, 0 to 0.5 decibels, 0 to 0.25 decibels, 10 to 100 decibels, 20 to 100 decibels, 30 to 100 decibels, 40 to 100 decibels, 50 to 100 decibels, 60 to 100 decibels, 70 to 100 decibels, 80 to 100 decibels, 90 to 100 decibels, 10 to 75 decibels, 20 to 75 decibels, 30 to 75 decibels, 40 to 75 decibels, 50 to 75 decibels, 60 to 75 decibels, 70 to 75 decibels, 10 to 65 decibels, 20 to 65 decibels, 30 to 65 decibels, 40 to 65 decibels, 50 to 65 decibels and 60 to 65 decibels, 20 to 30 decibels, 30 to 40 decibels, 40 to 50 decibels, 50 to 60 decibels, 60 to 70 decibels, 70 to 75 decibels, 80 to 90 decibels, 50 to 75 decibels and 50 to 65 decibels.
Further still, in accordance with the present disclosure, the standing wave may be of half-octave, double octave, or reflective incidence. Thus the frequencies delivered at the collarbone may independently collide across the breastbone or sternum and create a new frequency which is of a different or same frequency as the generating waves.
In accordance with the present disclosure, the frequency selected for therapy may be held constant while the sound pressure level can be increased or decreased, alternatively, the sound pressure level may be held constant and the frequency varied. The measurement of a sound pressure level is related to the displacement of a portion of the driver 220. The portion of the driver 220 may be displaced between: 0 mm and 20 mm, 0 mm to 10 mm, 0 mm to 9 mm, 0 mm and 8 mm, 0 mm to 7 mm, 0 mm to 6 mm, 0 mm to 5 mm, 0 mm and 4 mm, 0 mm and 3 mm, 0 mm and 2 mm, 0 mm and 1 mm, 0 mm and 0.5 mm, 0 mm to 0.05 mm, 0 mm to 0.005 mm, 0 mm to 0.0005 mm, 0.5 mm to 0.05 mm, 0.5 mm to 0.005 mm, 0.05 mm to 0.005. If the driver 220 is selected to be the haptic speaker 220′, then the portion of the haptic speaker 220′ being displaced is the coil of the haptic speaker.
In accordance with the present disclosure, it is contemplated that each therapy providing device may be activated to provide therapy for a time period between about 1 second and 24 hours. In other embodiments, the therapy providing devices may be activated to provide therapy for a time period of between about 1 second and 12 hours, 1 second and 11 hours, 1 second and 10 hours, 1 second and 9 hours, 1 second and 8 hours, 1 second and 7 hours, 1 second and 6 hours, 1 second and 5 hours, 1 second and 4 hours, 1 second and 3 hours 1 second and 2 hours, and 1 second and 1 hour, 1 second and 45 minutes, 1 second and 30 minutes, 1 second and 20 minutes, 1 second and 15 minutes, 1 second and 10 minutes, 1 second and 5 minutes and 1 second and 1 minute.
The overall therapy process may be conducted for a time period between 1 second and 24 hours, 1 second and 23 hours, 1 second and 22 hours, 1 second and 21 hours, 1 second and 20 hours, 1 second and 19 hours, 1 second and 18 hours, 1 second and 17 hours, 1 second and 16 hours, 1 second and 15 hours, 1 second and 15 hours, 1 second and 14 hours, 1 second and 13 hours, 1 second and 12 hours, 1 second and 11 hours, 1 second and 10 hours, 1 second and 9 hours, 1 second and 8 hours, 1 second and 7 hours, 1 second and 6 hours, 1 second and 5 hours, 1 second and 4 hours, 1 second and 3 hours, 1 second and 2 hours, 1 second and 1 hour, 1 second and 45 minutes, 1 second and 30 minutes, 1 second and 15 minutes, 1 second and 10 minutes, 1 second and 5 minutes, 1 second and 1 minute.
In an alternative embodiment, instead of activating one therapy providing device 200 at a time to conduct the therapy, both therapy providing devices 200 may be activated at the same time.
In use, two therapy providing devices may be utilized, wherein the therapy providing devices would be disposed on the left and right clavicle. It is contemplated that the left and right therapy providing devices may be programmed or be configured to delivery different therapies. For example the left and right therapy providing devices may be configured to deliver different frequency ranges of therapy chosen from the ranges disclosed above. Additionally, the devices may be activated, programmed or configured to deliver therapy out of phase with each other. For example, the left therapy providing device may include a delay in the therapy, such that the delay in the therapy may cause a standing wave to be generated between the two devices.
It is further contemplated that a single therapy providing device may be disposed on the sternum to provide therapy as provided herein. Further still, two therapy providing devices maybe disposed on the sternum in order to provide the therapy as contemplated herein.
In accordance with the present disclosure, the therapy device may be factory programmed to utilize a certain frequency or range of frequencies to provide therapy. Alternatively, the frequencies may be selected and programmed or chosen from memory by a health care provider based upon a patient's response to a specific frequency or range of frequencies.
It is further contemplated that the computing device may be additionally in communication with other sensors, such as a blood pressure monitor, heart rate monitor, pulse oximetry monitor, electrocardiogram (EKG/ECG), or glucose sensor.
In one embodiment the computing device 800 would receive data from the blood pressure monitor, or other sensor, such that the user's blood pressure would be recorded before, during and after the application of therapy in accordance with the present disclosure. This data, along with the therapy data could be provided to the user and/or a health care provider. Based upon the data, the frequency or range of frequencies selected for therapy could be adjusted. The adjustments may be made automatically by the program, or by a health care provider or by the user themselves.
In another embodiment, the processor of the therapy providing device 200 may be in communication with other sensors, such as those described above, wherein the other sensors would be coupled in communication with the therapy providing device. The processor within the therapy providing device 200 can receive data from various other sensors, such as a blood pressure monitor. The data received from the blood pressure monitor may be utilized by the program within the memory of the electronics module to further control the therapy providing device 200.
The signals generated by the program and transmitted to the therapy providing device are preferably in the form of a sine wave. However, other wave forms may be utilized, such as a square waveform, sawtooth waveform or triangle waveform.
It is further contemplated that additional sensors maybe utilized with the methods and devices in accordance with the present disclosure. For example, a blood pressure monitor may be affixed to the patient as described above. Other sensors, such as a sleep sensor, movement sensor, pulse oximetry sensor, temperature sensor, heart rate monitor, EKG, microphone, digital stethoscope, light sensor, sleep apnea device (CPAP) or camera may be used in combination with the therapy system 100 in accordance with the present disclosure. The sensors listed above could be used separately or in combination to provide additional data to the user or a health care provider as to the health of the user as well as to the response of the user to the therapy provided by the therapy system 100.
It is further contemplated that any of the above sensors could be incorporated into the therapy providing device 200 in accordance with the present disclosure. If incorporated into the therapy providing device 200, the data from each of the additional sensors could be utilized by the program to alter the therapy provided based upon data received from the various sensors. In an alternative embodiment, the data from each of the additional sensors could be stored on the resident memory contained within the therapy providing device 200. The therapy providing device 200 could then be turned into a service center after a period of time, wherein the data contained within the memory can be retrieved and analyzed. In yet another embodiment, the data stored within the memory can be downloaded from the therapy providing device 200 each time the therapy providing device is placed on the inductive charging pad. The data can then be transmitted to a collection center and analyzed. Additionally, the data could be uploaded to a server or other internet/network connected personal computer, such that the data could be viewed by the user, a health care provider or others.
In another embodiment, the device will store the number of uses and durations of usage to allow the health care practitioner to determine compliance of the patient. As in sleep apnea devices, reimbursement is only allowed if the patient is compliant in using the device for a certain percentage of use by tracking and recording the usage of the therapy providing device of the present disclosure, this data could be utilized for reimbursement purposes.
In another embodiment, the therapy providing system 100 of the present disclosure could be associated with a home health system, such as Honeywell's HOMMED system. In this embodiment, the therapy providing system 100 in accordance with the present disclosure would be coupled to a monitoring system. In this embodiment, a health care provider could remotely monitor users as well as their response to the therapy being provided. Further still, the therapy providing system 100 may be configured to recognize an emergency, such as excessively high blood pressure, excessively low blood pressure, high heart rate or low heart rate and generate an alert, such as an alarm or notification to an emergency response unit to request help for the user.
In accordance with the present disclosure, the therapy providing device 200 as described herein is disposed adjacent to or thereabout the clavicle just above the brachial plexus of the user. It is contemplated that the therapy providing device 200 may be placed at other locations on the user such as the sternum, jaw, scapula, kneecap, wrist or skull. When activated, the driver assembly 220 of the therapy providing device 200 generates a frequency in the form of a sound wave; this sound wave is transmitted to the clavicle and the skin adjacent the clavicle. The sound waves transmitted to the clavicle are transmitted in the form of vibrations. The vibrations travel through the clavicle and into the skin, the arteries, vessels, nerves, sensory corpuscles, airways, bones near the clavicle, ligaments and tendons. As a result, the vibrations are eventually transmitted to the baroreceptors, the nociceptors, the proprioreceptors and other somatasory sensors. Here, the vibrations interact with the baroreceptors and other sensors in a manner to lower blood pressure. In a preferred embodiment, the clavicle is chosen because it's easily accessible location as well as its ability to transmit sound or vibrations. The clavicle is easy to identify by a health care provider and a patient as it resides close to the surface of the skin regardless of body mass.
In accordance with the methods and devices of the present disclosure, activation of both, the carotid and aortic baroreceptors as well as other somatasory sensors can be achieved. It is believed that activation of both the carotid and aortic baroreceptors is beneficial in achieving lower blood pressure. It is believed that the methods provided according to the present disclosure mimic exercise, and therefore achieve a lowering of blood pressure. In accordance with the present disclosure, the vibration provided by the therapy providing devices 200 activates a baroresponse resulting in a lowering of blood pressure.
In accordance with the disclosure, the therapy may be provided at night time either right before the patient enters a sleep cycle or during a sleep cycle of the patient. It may be beneficial to provide the therapy in accordance with the present disclosure at night time as it is believed that one of the most important times to lower blood pressure is during the night. By providing therapy at night time in accordance with the present disclosure, the therapy can be utilized to address nighttime hypertension. Additionally, at night time, systemic drug levels are at their lowest, therefore there is a need for additional blood pressure control at this time. The therapy providing device of the present disclosure may be configured to provide two or more therapy providing sessions during a night time. As such, the therapy session after the first therapy session may be configured to initially begin at a lower volume/vibration or extension of the vibration source. By beginning the second or subsequent therapy sessions at a lower setting, the intention is to not wake the user from their sleep, over a period of pre-determined time, the volume/vibration or extension of the vibration source may increase.
In accordance with another embodiment of the present disclosure, it is believed that through the use of a single therapy providing device instead of two therapy providing devices can be utilized to lower only Diastolic blood pressure, wherein the use of both therapy providing devices can be utilized to lower both Systolic and Diastolic blood pressure.
It is contemplated that the therapy providing devices of the present invention may be utilized to raise blood pressure, ease snoring, and/or cause a relaxing sensation.
In accordance with the disclosure, the therapy may be provided prior to a users sleep cycle and again in the morning either before they awake or shortly after they have woken up.
In accordance with the disclosure, the therapy providing device may be programmed with frequencies, wherein other frequencies may be utilized to raise blood pressure at such times whereby raising the blood pressure would be therapeutic and beneficial to a patient. It may be desirable to raise blood pressure after childbirth or to counteract episodes of hypotension.
It is further contemplated that the device and methods according to the present disclosure may be utilized at any time. For example, it may be desirable to utilize the device during the day time, where the device could be utilized in combination with a blood pressure monitor, or alternatively, incorporate a blood pressure monitor for closed loop control. In this embodiment, the program would monitor the user's blood pressure and apply therapy on an as needed basis. The user could select to turn the system off if desired, for example if they are planning to engage in physical activity which will raise their blood pressure.
It is further contemplated that the therapy providing device of the present disclosure may be utilized to train or re-train a user's body to respond to it's own nerve signals. It is contemplated that the therapy providing device of the present disclosure may only need to be utilized for a period of time, and such, over time the user's body would regain control over the user's blood pressure. It is contemplated that the therapy providing device of the present disclosure may only be needed to be utilized for a period of time such as, 1 day, 2 days, 3 days, 4 days, 5 days, 6 days, 7 days, 8 days, 9 days, 10 days, 11 days, 12 days, 13 days, 14 days, 15 days, 16 days, 17 days, 18 days, 19 days, 20 days, 21 days, 22 days, 23 days, 24 days, 25 days, 26 days, 27 days, 28 days, 29 days, 30 days, 31 days, 2 months, 3 months, 4 months, 5 months, 6 months, 7 months, 8 months, 9 months, 10 months, 11 months, 1 year or more. It is contemplated that the user may reduce the amount of time they utilize the therapy providing device over time. For example, the user may be required to utilize the therapy providing device on a daily basis initially, and over time, they may begin to need to utilize the therapy providing device less as their bodies own system becomes trained or re-trained to control the user's blood pressure.
In accordance with the present disclosure, and referring to
As shown in
Referring now to
To achieve the results depicted in
Blood pressure measurements were taken before the application of the therapy, whereby the user's Systolic blood pressure averaged 131 mmHg at night time and 144 mmHg during the day. Diastolic blood pressure was 72 mmHg at night time and 87 mmHg during the day. After using the therapy for one evening (one 8 hour session as described above), Systolic blood pressure averaged 116 mmHg at nighttime and 131 mmHg at daytime and diastolic blood pressure averaged 66 mmHg at nighttime and 80 mmHg at daytime.
In accordance with the present disclosure, as described in detail above and with reference to the included publications, it is understood that baroreceptors and nerves affect blood pressure through a measured response generated by stretching or contraction of the arterial wall.
Nerve fibers, including baroreceptors, have the following input-output characteristics; threshold pressure, saturation, post-excitory depression (PED), Asymmetric Rate Sensitivity and hysteresis.
As long as pressure within an artery remains below a certain level, no nerve firing occurs, this is referred to as the nerve threshold pressure. Above the threshold pressure, the fiber responds by producing action potentials, i.e. as signal. Individual fibers within humans and animals possess a wide range of pressure threshold values.
As pressure increases within the artery, the firing rate of individual fibers increases. However, at certain pressure, further increases in input yield no further increase in output frequency, thereby reaching the saturation of the baroreceptor nerve.
If pressure input within the artery is stepped from a low pressure, which is higher than the threshold pressure, to a higher pressure, then returning to a lower pressure level, will result in a brief period of shutoff, that is there will be no firing of the baroreceptor nerve, also referred to as post-excitatory depression (PED). The baroreceptor nerve will return to its original firing rate after time.
Baroreceptor nerve frequency response to rising pressure is more pronounced than the response to falling pressure, otherwise known as asymmetric rate sensitivity.
Lastly, periodic inputs produce looping in pressure-frequency plots, another indication of the asymmetry between responses to rising and falling pressures otherwise referred to as hysteresis.
In accordance with the present disclosure, utilization of the devices in accordance with the methods described herein cause an activation of the nervous system which affect blood pressure. The nerve terminal endings respond to stretch or acoustic vibration, and produce a frequency-modulated train of action potentials which can override the natural frequencies to elicit a response. Wherein the therapy provided by the disclosure, utilizes acoustic vibration of specific frequencies applied at specific time intervals to activate the body's nervous system to elicit a blood pressure response. The therapy of the present disclosure is applied in a cyclic manner as it is believed that the baroreceptors may become saturated if stimulated for too long of a period of time. If the therapy was applied continuously it is believed that the baroreceptors would stop responding.
According to a method of the present disclosure, the therapy providing device is disposed adjacent to a user's clavicle. The clavicle, being a dermal bone, is capable of transmitting vibrations. The clavicle lies above the cerviocoaxillary which holds auxiliary arteries, veins, airways and the brachial plexus of nerves that supply the upper limb of the arm. Vibrating the clavicle is believed to create micro-pulsations which travel to the Aortic Baroreceptors and the Carotid Bulb Baroreceptors. These micro-pulsations are believed to be perceived as an increase in heart rate by the baroreceptors which then send a signal to the brain, thereby causing the body to lower blood pressure.
Selective stimulation of primary nerve endings can be obtained with careful control of the amplitude, displacement and the mode of application of the vibration or micro-pulsations.
It is believed that the therapy providing device in accordance with the present disclosure when disposed on a user's clavicle, thorax, jaw, patella and activated to produce a vibration or a plurality of vibrations using a transition, sweeping or stepping pattern for a period of time is believed to cause a baroresponse thereby causing an effect on blood pressure.
It is also contemplated in accordance with the present invention that the therapy providing device may be utilized in accordance with the disclosure herein to affect a user's sleep quality, such as the reduction or cessation of snoring or sleep apnea. Further still the therapy providing device may further benefit users who suffer from migraine headaches.
This application claims the benefit of U.S. Provisional Application No. 61,790,456, filed Mar. 15, 2013, and U.S. Provisional Application No. 61/845,886, filed Jul. 12, 2013, and U.S. Provisional Application No. 61/862,915, filed Aug. 6, 2013. This application is also a continuation-in-part of U.S. application Ser. No. 13/656,344, filed Oct. 19, 2012, which claims the benefit of U.S. Provisional Application No. 61/549,007, filed Oct. 19, 2011, U.S. Provisional Application No. 61/648,060, filed May 16, 2012, U.S. Provisional Application No. 61/681,469, filed Aug. 9, 2012, and U.S. Provisional Application No. 61/681,513, filed Aug. 9, 2012. The disclosure of each of these applications is incorporated by reference herein in its entirety. Any and all applications for which a foreign or domestic priority claim is identified in the Application Data Sheet as filed with the present application are hereby incorporated by reference under 37 CFR 1.57.
| Number | Date | Country | |
|---|---|---|---|
| 61790456 | Mar 2013 | US | |
| 61845886 | Jul 2013 | US | |
| 61862915 | Aug 2013 | US | |
| 61549007 | Oct 2011 | US | |
| 61648060 | May 2012 | US | |
| 61681469 | Aug 2012 | US | |
| 61681513 | Aug 2012 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 13656344 | Oct 2012 | US |
| Child | 14200919 | US |
