Patent Description:
A mandibular advancement device of the type referred to in this specification is already disclosed in <CIT>, which discloses the preamble of claim <NUM>, and <CIT>. The mandibular advancement device disclosed has both intraoral and extraoral portions. The present invention is mainly concerned with the extraoral portion of the device.

The purpose of the device is to adjust the position of the mandible of the wearer so that their airway is clear to enable normal breathing. Typically, this type of device is worn at night while the wearer is sleeping. The device typically includes manual mechanical adjustment means that allow the wearer, or a care giver, to manually adjust the position of the mandible of the wearer. The problem with this is that once the position is selected, and the wearer goes to sleep, then the device keeps the mandible in that position during the entire sleep period. Unfortunately, what may have been the best position for the mandible at the commencement of sleep may not be the best position at other times during the sleep cycle. For example, if the breathing alters during the night, this indicates that the device may need adjusting. Often a partner, care giver, or the wearer themselves needs to intervene and make manual adjustments to the device. This is disruptive and non-conducive to a good night's sleep.

It is therefore an object of the present invention to provide automatic adjustment means for the extraoral portion of a mandibular advancement device that at least mitigates some of the aforementioned problems.

<CIT> discloses a lower-jaw advancement snore guard with automatic adjustment. A snore guard body is composed of an upper jaw portion, a lower jaw portion and a lower-jaw advancement adjusting device, wherein the upper jaw portion and the lower jaw portion are provided with a customized upper alveolus and a customized lower alveolus, respectively; the lower-jaw advancement adjusting device is provided with a micro speed-reduction motor, a battery, a PLC, a snore sensor, a body position sensor, a nose mouth respiratory air flow sensor, a blood oxygen saturation sensor and a wireless communication device.

According to one form, the present invention is a mandibular advancement device according to claim <NUM>.

The pad assembly includes sensor means that are adapted to sense the airflow emanating from the nose of the wearer as they breath while wearing the device and feed the sensor data collected in real time to logic control means contained within the body portion.

The logic control means are adapted to process the sensor data it receives to determine if the position of the mandibular of the wearer needs adjusting to improve airflow from the wearer, and if so, then the logic control means are adapted to activate the motorised means to either extend or retract the lower arm for the appropriate distance, thereby causing the pad assembly to apply more or less pressure to the subnasal maxillary bone, and thereby change the position of the mandible of the wearer into the desired position.

Preferably, the device further includes manual means that are adapted to enable a user to manually control the motorised means so that the user can set a first desired position for the extraoral portion of the device.

Preferably, the manual means includes a switch that causes the motorised means to slide the lower arm out of the body portion when the switch is in a first position, and slidably retract the lower arm when the switch is in the opposite position.

In one preferred embodiment, the switch is a rocker switch.

Preferably, the switch is located on the extraoral portion of the body portion.

In another preferred embodiment, the switch is located on the pad assembly as a pair of momentary switches, one for retraction and one for extension.

In another preferred embodiment, the manual means also include a portable device such as a handheld computer, such as a smart phone, wherein said smart phone is wirelessly paired with the logic control means, and wherein the smart phone includes an app that includes manual control means that interact with the logic control means and is adapted to manually cause the motorised means to either extend of retract the lower arm.

Preferably, the portable device includes an app that records an optimal first position of the extraoral portion of the mandibular advancement device so that when subsequent mandibular advancement devices are paired to the portable device and linked to the specific account within the app, the app controls the optimal first position of that device that is best for that account holder.

Preferably, the portable device includes an app that links to an account belonging to the specific wearer of the device, and the account is adapted to receive telemetry from the logic control means, either in real-time, or in batch mode, and this telemetry is logged for that specific wearer within their account for subsequent analysis of breathing patterns and movement of the wearer's mandibular over a time period.

Optionally, the app includes alarm means that are enabled if/when the telemetry is lost from the mandibular advancement device.

Optionally, the app includes alarm means that are enabled if/when a fault within the adjustment means is detected by the logic control means, or if the battery powering the motorised means reaches a pre-set minimum charge.

According to another form, the present invention is a method of adjusting the position of the extraoral portion of a mandibular advancement device, including the steps of:.

Turning firstly to <FIG>, where we are shown an isometric view of a mandibular advancement device <NUM>. The device includes an extraoral portion <NUM> and an intraoral portion <NUM>. A body portion <NUM> is at the interface between the two portions and is therefore partly intraoral towards the posterior end and extraoral towards the anterior end. Electric motor means (not visible in this view) are encapsulated within the body portion <NUM>. The extraoral portion <NUM> includes a lower straight arm <NUM> that is adapted to slide into or out of a corresponding opening <NUM> in the anterior end of the body portion <NUM>. The straight arm <NUM> may include a rack <NUM> that engages with a pawl on the electric motor to cause the arm to move into or out of the body portion <NUM> as shown by the double ended arrow. A rocker switch <NUM> is formed in the extraoral portion of the body portion <NUM> and this is able to control the electric motor means. When the switch <NUM> is rocked in a first position, the motorised means act upon the lower arm <NUM> and forces it to move outwardly, and when the rocker switch <NUM> is rocked to a second position, the motorised means acts upon lower arm and forces it to move into the body portion. The upper portion of the extraoral portion <NUM> terminates at a pad assembly <NUM>. When the mandibular advancement device <NUM> is worn, the pad assembly contacts the subnasal maxillary bone of the wearer. The upper pad assembly <NUM> braces against a lower pad <NUM> that is located on the intraoral portion <NUM> of the device <NUM> and contacts the gingiva and/or teeth of the wearer. The opposing forces applied by the pad assembly <NUM> and the lower pad <NUM> combine to adjust the position of the mandible of the wearer. By moving the extraoral portion <NUM> of the device <NUM>, the operator of the rocker switch <NUM> thereby adjusts the force applied upon the subnasal maxillary bone of the wearer, and thereby causes a change in the position of the wearer's mandible.

Now turning to <FIG>, where we are shown an alternative embodiment of the present invention. In this embodiment, the rocker switch is removed from the body portion <NUM> and is relocated to the pad assembly <NUM> as a pair of momentary switches <NUM> and <NUM>'. These momentary switches act similarly to the rocker switch <NUM> as shown in <FIG>. When an operator, perhaps the wearer, depresses momentary switch <NUM>, the electric motor encapsulated inside the body portion <NUM> is activated and causes the lower arm <NUM> to retract into the body portion <NUM>, and when the operator depresses momentary switch <NUM>', the electric motor is activated and causes the lower arm <NUM> to extend out from the body portion <NUM>. The extraoral portion includes electrical wiring, preferably encapsulated within its body that enables the action of either momentary switch to activate the electric motor means within the body portion <NUM>.

In <FIG> we are shown another preferred embodiment of the present invention. In this embodiment, all mechanical switches are removed from the device <NUM> and the electric motor means are instead controlled wirelessly. In this embodiment, the body portion <NUM> includes wireless transmission and receiving means that are adapted to pair with an external computerised device. In this example, a smart phone <NUM> is shown. The smart phone <NUM> includes an app that is designed to work with the device <NUM>. In one mode of the app, the operator can use virtual buttons displayed on the smart phone's <NUM> screen to cause the electric motor means to move the lower arm <NUM> into or out of the body portion <NUM>.

In <FIG>, we are shown a plan view of the body portion <NUM> in accordance with one embodiment of the present invention. In this view we can see the electric motor <NUM> mounted inside the lower half of the body portion <NUM>. The electric motor <NUM> is powered by rechargeable battery <NUM>. Optionally, the invention may also include logic control means <NUM>. The logic control means may be programmed to provide automatic functionality of the device <NUM>. Wireless connectivity may also be included. The body portion <NUM> may also include a wireless antenna <NUM> that enables the device <NUM> to wirelessly connect to an external computerised device. As shown in this view, the electric motor <NUM> is fitted with a pawl <NUM> that engages with the rack <NUM> on the lower arm <NUM>. Of course, other arrangements for engagement between the electric motor <NUM> and the lower arm <NUM> are possible and fit within the scope of this invention. Also shown in this view is one preferred option using electrical rails <NUM> and <NUM>' for transmitting electrical signals when momentary switches are included upon the pad assembly. The electrical rails <NUM> and <NUM>' are electrically connected to the slide contacts <NUM> and <NUM>'.

In <FIG>, we are shown another embodiment of the present invention. In this embodiment, two airflow sensors <NUM> and <NUM>' are located directly below the nostrils of the wearer of the device. As the wearer breathes, the sensors <NUM> and <NUM>' determine the airflow rate. This data is then fed to the logic control means via wires <NUM> and <NUM>'. The logic control means are programmed to analyse the airflow data. If the logic control means determine that the flowrate associated with the wearer's breathing has changed sufficiently, then the logic control means are programmed to autonomously engage the electric motor means and adjust the position of the wearer's mandible in an attempt to affect the wearer's breathing and return the rate of airflow back within a set of control limits. The logic control means may also send telemetry wirelessly to an external computerised device. This can be done continuously or in batches. This arrangement makes the device <NUM> completely automatic. Once the nominal breathing rate is determined, and the maximum and minimum control points set, then the device will automatically alter the position of the wearer's mandible in an autonomous attempt to correct undesirable changes in breathing. The telemetry sent to the external computerised device is capable of giving the wearer and other carers and health service professionals valuable insights into the wearer's breathing patterns while using the device.

The device may also include a manual override, as shown in this example as rocker switch <NUM> so that a wearer can take manual control of the device. A slider switch may be included on either the body, or the pad assembly that enables a wearer or care giver to switch off the automatic mode of operation.

While the above description includes the preferred embodiments of the invention, it is to be understood that many variations, alterations, modifications and/or additions may be introduced into the constructions and arrangements of parts previously described without departing from the essential features of the invention.

It will be also understood that where the word "comprise", and variations such as "comprises" and "comprising", are used in this specification, unless the context requires otherwise such use is intended to imply the inclusion of a stated feature or features but is not to be taken as excluding the presence of other feature or features.

Claim 1:
A mandibular advancement device of the type having both intraoral (<NUM>) and extraoral portions (<NUM>), the extraoral portion (<NUM>) including a lower arm (<NUM>) that is substantially straight and a curved upper arm that curves upwardly from the lower arm (<NUM>) and back towards a face of a wearer of the device, the posterior end of the upper arm including a pad assembly (<NUM>) that is adapted to make contact with, and apply pressure to, a subnasal maxillary bone of the wearer,
the mandibular advancement device further including:
an adjustment means including a body portion (<NUM>) that is at an interface between the intraoral (<NUM>) and extraoral (<NUM>) portions and thereby is part intraoral and part extraoral, wherein the pad assembly (<NUM>) of the device includes sensor means (<NUM>,<NUM>') that are adapted to sense the airflow emanating from a nose of the wearer as they breathe while wearing the device,
characterised by:
the body portion (<NUM>) including motorised means encapsulated within the body portion (<NUM>), a substantial portion of the lower arm (<NUM>) being engageable with the motorised means, the motorised means being adapted to engage with the lower arm (<NUM>) and cause it to slidably extend from, or slidably retract into, the body portion (<NUM>), wherein the lower arm (<NUM>) extends directly outwardly from the extraoral part of the body portion;
wherein sensor means (<NUM>, <NUM>') are also adapted to feed sensor data collected in real time to logic control means (<NUM>) contained within the body portion (<NUM>); and wherein the logic control means (<NUM>) are adapted to process the sensor data they receive to determine if a position of a mandible of the wearer needs adjusting to improve airflow from the wearer, and if so, then the logic control means (<NUM>) are adapted to activate the motorised means to either extend or retract the lower arm (<NUM>) for an appropriate distance, thereby causing the pad assembly (<NUM>) to apply more or less pressure to the subnasal maxillary bone, and thereby change the position of the mandible of the wearer into a new position.