The present application describes a sensory unit for implant-supported dental implants or prostheses that will provide neuro-sensory information to the trigeminal nerve endings.
Previous studies related to the matter herein disclosed discussed the use of a bionic device for transducing masticatory pressure into an electrical stimulus, capable of being perceived by the body in the form of nociceptive stimulus, triggering on the part of the organism an adequate motor defense response or decrease of muscle contraction.
However, this type of devices did not contemplate the possibility of identifying the gradient of mechanical force exerted on the masticatory surfaces of the teeth of the implant-supported or implant-retained prosthesis, namely the modulation of the electrical signal produced from the mechanical forces exerted by the fixed prosthesis, on the abutment resting on the implant.
Therefore, and as a differentiating element in relation to the prior art, the present unit has the ability to better match light mechanical loads to a specific individualized signal. This fact is important, since it returns one of the important functions of natural teeth, which is to signal the position of the jaw as a determining factor to provide information to the structures of the cerebral cortex that allow a motor response to the beginning of gait movement, and to define the sequence of contraction of the various muscle groups in view of the coordinated movement of body displacement, inserted in a trajectory.
The present application describes a sensory unit for dental implants, characterized in that it comprises at least one dental device responsible for transforming the mechanical forces from occlusion and mastication actions into electrical signals; and at least one stimulator device responsible for transforming electrical signals from the dental device into neuronal stimuli; wherein the neuronal stimuli promote the restoration of the proprioceptive, nociceptive and stereognostic sensitivity of the user.
In a proposed embodiment, the at least one dental device transmits the electrical signals to the at least one stimulator device.
In yet another possible embodiment, the electrical signals are transmitted from the at least one dental device to the at least one stimulator device via a leading wire system or via a wireless communication system.
In yet another possible embodiment, the at least one stimulator device applies neuronal stimuli to the nerve endings of the maxillary or mandibular trigeminal bundles.
In yet another possible embodiment, the at least one dental device comprises the use of a sealed titanium encapsulation for the incorporation of all constituent elements.
In yet another possible embodiment, the constituent elements of the at least one dental device comprise the use of biocompatible force sensing material, a battery, an signal acquisition and processing circuit, an integration module, and a transmitter module.
In yet another possible embodiment, the at least one stimulator device comprises the use of an airtight biocompatible coating that incorporates all constituent elements.
In yet another possible embodiment, the constituent elements of the at least one stimulator device comprise the use of a receiver, a battery, an integration module, a processing module, a conductive filament, a conductive housing with biocompatible coating and a conductive filament incorporated in the conductive housing and interface with “cuff” type electrodes.
In yet another possible embodiment, the at least one dental device can be installed in several locations comprising the dental implant, the prosthetic abutment, the prosthetic device that integrates the prosthetic abutment, occlusal surface of the fixed prosthesis teeth or yet in the space reserved for the screw well that fastens the abutment to the implant head.
In yet another possible embodiment, the at least one stimulator device can be installed in several locations comprising the vicinity of the terminal branch, respectively of the infraorbital nerve, in the upper maxillary nerve branch, or in the vicinity of the mentonian nerve, in the lower maxillary or mandibular nerve branch.
The present application describes a sensory unit for dental implants or prostheses and aims at returning tooth sensitivity lost as a result of tooth extraction, devitalization, ablative oral surgery, and infections that are the cause for neurophysiological disturbances in stomatognathic system functioning.
Therefore, the present invention aims at restoring the neurosensitive connection between the teeth, or their substitutes, whether they are implants, cemented crowns or screwed to implants or any other mechanical device related thereto, and the brain, making it possible to be applied on abutments, dental implants, crowns, or prosthetic structures mechanically related thereto. The problem that this solution allows to overcome is the lack of sensitivity that patients rehabilitated with fixed prostheses on implants complain about. This lack of sensitivity causes a deficit in the ideation of the masticatory model, as well as changes in the perception of the dimension, hardness, and texture of food, thus contributing to a significant loss of the ability to taste food. The loss of dental sensitivity, when causing a decrease in the sensitive input of proprioception and stereognosis, indirectly decreases the abilities of body posture, balance and locomotion while walking and running.
The present unit then makes it possible to contribute to the reestablishment of proprioceptive, nociceptive and stereognostic sensitivity, either diminished or lost due to teeth extraction and/or devitalization.
In this way, the superior functions are improved as a consequence of the restoration of related sensitivities, namely:
Individuals who have this unit implemented in their mouth will be able to perform more differentiated masticatory cycles, in lesser numbers and with greater efficiency, as the information that reaches the brain is more detailed about the hardness, texture, dimension, and taste of the foods that have been placed in the mouth.
This unit thus makes it possible to better discern the masticatory model for each class of food. On the other hand, it will also improve the perception of food hardness, preventing masticatory overloads, and therewith, minimizing the occurrence of fractures of fixed prostheses, so frequent in this type of prosthetic devices.
Acting in complementarity, these units may also provide and act as a tool for detecting and preventing parafunctional masticatory movements, commonly known as bruxism.
The benefits of the present technique are evident and can be applied in the clinical field of stomatology, dental medicine, maxillofacial surgery, physical medicine and rehabilitation, gerontology, sports medicine, among others.
For an easier understanding of the present application, figures are herein attached, which represent embodiments which however are not intended to limit the art herein disclosed.
Referring to the figures, some embodiments are now described in more detail, which are not intended, however, to limit the scope of the present application.
The present application describes a sensory unit composed of two or more subunits, or devices. The set of the two devices that act in sequence, provides restitution of masticatory dental sensitivity, and proprioceptive dental sensitivity.
The first functionality replaced by the developed unit is important for the functions of grasping, mastication, swallowing food, and controlling occlusal overloads. The second is to restore the dental sensitivity established by small contacts between the dental cusps, and which allow the brain to receive spatial information about the position of the jaw and thereby improve the functions of body posture, gait and running.
One of the devices, hereinafter referred to as the dental device (100), as it is installed in the dental arch, can be incorporated in several locations comprising the dental implant, the prosthetic abutment, and also the prosthetic device that integrates the prosthetic abutment. The main purpose of the dental device (100) is to receive the mechanical loads from occlusion and mastication, and to transform them into electrical signals. These electrical signals will in turn be transmitted to another device, called a stimulator device (200), said transmission can be carried out through a leading wire system, or through a wireless communication system, through the most appropriate biocompatible method for the relevant case.
The dental device (100), therefore, has the function of transforming the mechanical loads into electrical signals that will then be transmitted to the stimulator device (200).
In one of the proposed embodiments, the dental device (100) is installed in the dental arch, being installed between the abutment and the implant, and has a component that allows the interface between the implant and the abutment, the housing (1) being made up of a biocompatible force sensing material. The remaining constituent components of the dental device (100) will also comprise a battery (2), an signal acquisition and processing circuit (3), an integration module (4) and a transmitter (5) that could be a micro antenna. All these components will be grouped and included in an abutment with a conical, straight or angled profile. The material responsible for sealing and encapsulating all these components, incorporating them in a single compartment, is titanium in one of the proposed embodiments. The signal acquisition and processing circuit (3) is responsible for processing and sending the signals from the force sensing housing (1) to the integration module (4). The integration module (4) is responsible for receiving the electrical signals and sending thereof to the antenna (5) in order to be transmitted to the neuronal stimulation unit (200).
The dental device (100), in one of the proposed embodiments, is mostly made of titanium, and has an extended dimension in the form of a “multi-unit” abutment, incorporating inside all electronic components necessary for the detection of mechanical forces of dental occlusion and transformation thereof into a modulated electrical signal. The detected forces will have an amplitude between 0.2N and about 180N.
The dental device (100), therefore, has the particularity of being able to be installed in the region of the occlusal surface of the teeth of the fixed prosthesis, or else, in a more miniaturized form and at micro scale, in the space reserved for the screw well that tightens the abutment to the implant head.
In terms of dimensions, and in one of the proposed implementation forms, the dental device (100) comprises diameters between 1 mm and 5 mm, preferably between 1.5 mm and 4.3 mm, and a total height of approximately 6.5 mm.
The stimulator device (200) consists of several components grouped within an airtight biocompatible coating (12). Among these, an signal acquisition and processing circuit (11), a receiver (9), which may be a micro antenna and a signal amplifier circuit, a battery (8), an integration module (6), a processing module (7) and generation of neural stimuli, and a conductive filament of neural stimulus for surrounding tissues (10) which is incorporated in the conductive housing (13) can be part of one of the proposed embodiments. The stimulator device (200) will be installed in the vicinity of the end branch, respectively of the infraorbital nerve, in the upper maxillary nerve branch, or in the vicinity of the mentonian nerve, in the lower maxillary or mandibular nerve branch. The conductive filament of neural stimulus for surrounding tissues (10) is composed, in one of the proposed embodiments, by a chromium-cobalt-nickel alloy (MP35N) or by a platinum-iridium alloy.
The stimulator device (200) is constructed of biocompatible and flexible material, and can be coated in materials derived from polyfluorethanes, including all electronic components (at micro or nano scale) necessary for the production of neuronal stimulus, or neural stimuli in continuous mode, pulse, or sequence of pulses, with an electric current intensity that can vary between a few hundred microamperes and a few milliamperes with variable frequency between 5 to 100 hz, and a duration of a few hundred microseconds.
In one of the proposed embodiments, the receiver (9) of the stimulator device (200) will be responsible for receiving the signal from the dental device (100), ensuring the delivery thereof to the integrating component (6) for the purpose of being transformed by the signal acquisition and processing circuit (11) in a type of neurological signal that crosses the coating (12) of the stimulator device (200), and excites the nerve endings in the vicinity. Among the remaining components of the stimulator device (200), it is also possible to list the conductive stimulation filament (13) which will be embedded in the coating of the stimulator device (200). The integration module (6) is, therefore, responsible for the amplification of the electrical signal from the dental device (100), demodulating the signal, and its preliminary processing. The amplification and neural stimulus production module (7) is responsible for receiving the signal from the integration module (6), and modulating and amplification the neuronal stimulus. Finally, the conductive housing with a biocompatible coating (12) ensures hermetic encapsulation of the entire microsystem.
The stimulator device (200) will therefore be responsible for receiving electrical signals from the dental device (100), thus modeling, processing and transforming them into neural stimuli that will be transmitted through the tissues in the vicinity of nerve endings, to the nerve bundle endings. This signal is generated in the receiving device itself, and will be transmitted for application in the nerve ending of the branch at bundle V2 or V3 of the maxillary sensitive trigeminal bundle and mandibular sensitive trigeminal bundle. This nerve stimulation, will make its way to the brainstem, and therefrom to the posterior thalamic nuclei, going up to the sensitive cerebral cortex, being then due to the phenomenon of cerebral neuroplasticity, interpreted as a neurological signal coming from the masticatory region, being processed as such by the brain to provide a motor, masticatory or postural response, or an integrative response through the cerebral amygdala or the hippocampus, with the generation of mood changes, or stimulation of cognitive functions, such as memory and concentration.
Still in relation to the characteristics of the stimulator device (200), and in one of the proposed embodiments, it has approximate dimensions of 6.0 mm in width and 2.5 mm in height.
The present description is of course in no way restricted to the embodiments presented herein and a person of ordinary skill in the art may provide many possibilities of modifying it without departing from the general idea as defined in the claims. The preferred embodiments described above are obviously combinable with each other. The following claims further define preferred embodiments.
Number | Date | Country | Kind |
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116518 | Jun 2020 | PT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2021/055143 | 6/11/2021 | WO |