Patent Application
20240390122
This invention belongs to the field of tools used by dentists for performing operations, and more particularly, to intra-oral irrigators.
Intra-oral irrigators are well known in the technical field of dental practice. These are devices which uses a stream of high-pressure pulsating water intended to remove plaque and food debris between teeth and below the gum line.
These devices may be used by dental professionals or by users. In the first case, an integration with the elements used by the dental practitioner in their daily routine is desirable.
Further, not every irrigator is suitable for every patient. The removal of the teeth and/or dental implant biofilm must be done in such a way not to create dental conditions or affecting the patient's teeth and/or dental implants in any negative form.
An alternative for the known irrigators, focused on these two questions, is provided in the present invention.
The invention provides an alternative solution for this problem by means of a dental irrigator.
Unless otherwise defined, all terms (including technical and scientific terms) used herein are to be interpreted as is customary in the art. It will be further understood that terms in common usage should also be interpreted as is customary in the relevant art and not in an idealised or overly formal sense unless expressly so defined herein.
In this text, the term “comprises” and its derivations (such as “comprising”, etc.) should not be understood in an excluding sense, that is, these terms should not be interpreted as excluding the possibility that what is described and defined may include further elements, steps, etc.
In a first inventive aspect, the invention refers to a dental irrigator comprising
With such a dental irrigator, a good cleaning of the sub-gingival zone may be achieved, since it does not use air, so the possibility of emphysema is reduced. To do so, a high pressure of the water is needed, usually higher than the standard pressure of dental chairs. The intermediate connector ensures that the working tip resists this high water pressure and does not disconnect from the main body.
In some particular embodiments,
This configuration with the engaging elements and the elastic element ensures that when the intermediate connector is in the blocking position (when released and pressed by the elastic element), the working tip is engaged by an element which is not a mere press fit connection.
In some particular embodiments,
The balls and the groove ensure this engagement which cannot be released by water pressure. The fact that the ball is configured to protrude both from the inner connection surface and from the outer connection surface means that has a diameter which is greater than the thickness of the wall of the second connection element; the fact that it protrudes from one side, the other or both of them depends on the pressure exerted onto the ball.
In some particular embodiments, the elastic element is a spring.
A spring is a common element which exerts the required force against the intermediate connector when required.
In some particular embodiments, the inner connection surface and the first portion of the working tip have a circular cross section.
A circular cross section allows the circular rotation of the working tip with respect to the main body, which is useful to adjust the specific direction in which the water exits the irrigator.
In some particular embodiments,
This symmetry ensures a proper retention force and a complete groove allows a complete circular adjustment of the working tip.
In some particular embodiments, the inner connection surface or the first portion of the working tip comprises friction o-rings arranged to create a friction fitting between the inner connection surface and the first portion of the working tip.
Friction o-rings allow the control of the circular movement of the working tip with respect to the main body.
In some particular embodiments, the dental irrigator further comprises
In a second inventive aspect, the invention provides a dental irrigator comprising
A reduced pressure is also beneficial for avoiding dental conditions, such as emphysemas or any other damage in the oral tissues. With an irrigator as the one defined by the present invention, these problems are avoided, since the fluid depressurizing element reduces the pressure of the air and water provided by an external device, such as a dental chair, which does not take into account these problems. With this invention, any water and air source may be used, and then each oral irrigator may be defined to provide an outlet with a predetermined pressure, for adapting to the different patients and their oral circumstances. In some cases, the air or the water may have a low pressure when entering the device, so it is not necessary that the combined jet may have a pressure which is lower than both the water pressure and the air pressure.
In some particular embodiments, the fluid depressurizing element comprises a fluid pneumatic atomizer comprising a first inlet arranged to receive the water jet from the water inlet, a second inlet arranged to receive the air jet from the air inlet and an outlet configured to provide the combined jet.
The fluid pneumatic atomizer is able to receive both inputs, coming from the connection portion, and providing a combined jet with a lower pressure. This embodiment joins all the features of the depressurizing element in a single physical element.
Further, the pneumatic atomizer allows a great efficiency with low pressure values, without depending on further features (angulation, time, distance, etc).
In some particular embodiments, the irrigator further comprises a tube connecting the exit of the fluid pneumatic atomizer with the fluid outlet. In some particular embodiments, both the fluid pneumatic atomizer and the fluid outlet comprise threaded portions for connecting the tube.
In some particular embodiments, the dental irrigator further comprises at least pressure reducer upstream the fluid pneumatic atomizer, arranged to reduce the pressure of the air jet and/or the water jet before entering the fluid pneumatic atomizer.
With individual pressure reducers, such as individual microvalves, a better adaptation is achieved, thus reducing mechanical requirements for the fluid pneumatic atomizer, which receives lower pressure jets.
In some particular embodiments, the fluid depressurizing element comprises
In these examples, the depressurizing element is divided into different functions: pressure is reduced in a first step by microvalves and then a mixing element (which may be as simple as a joint of the two conduits) produces the combined jet.
This alternative is less expensive than the atomizer, but in some cases, may require the appliance of other complementary features (to use the device during a predetermined time, or at a predetermined distance, or with a predetermined angle or with a predetermined arrangement of the exit bores, for example) to obtain the best performance.
In some particular embodiments, the mixing element is a chamber comprised in the working tip.
The chamber receives the water jet in a position which is close (less than 2 cm, particularly less than 1 cm) to the end of the working tip, thus allowing the mixture of the water and air to be formed within the chamber of the working tip.
The mixing of the water within the working tip chamber reduces the distance of travel for the mix from the device to the treated tooth or implant surface which in return enhances its efficiency.
In some particular embodiments, the fluid depressurizing element is configured to produce a combined jet with a pressure comprised between 60 and 140 kPa.
This pressure is particularly beneficial to avoid any dental affection, and for a proper care of brackets or any other implants. In the particular case of dental implants, treatment with high pressure water spray or spray comprising a mixture of water/air/micro particle materials (such as soda, erythritol, etc) may cause the release of titanium particles form the implant surface and initiate the cascade of low-grade inflammation through macrophages attraction/activation which in return leads to bone resorption. In case of teeth surfaces similar practices lead to surface alteration with the development of micro-cracks, irregular surface topography with pits and valleys, etc that lead to the formation of a surface that becomes amenable to bacteria colonization.
In some particular embodiments, the fluid depressurizing element comprises an air pressure adjuster and/or a water pressure adjuster.
A pressure adjuster allows the practitioner to select a particular pressure for the combined jet. Different dental chairs may have different air and/or water pressure outputs. With pressure adjusters, the practitioner is able to overcome the issues arising from this variability.
In some particular embodiments, the air pressure adjuster and/or the water pressure adjuster are accessible from outside the dental irrigator, thus being available for a user's access.
In some cases, the practitioner may need to modify the pressure regardless the supply conditions, so it is useful that this pressure adjuster is accessible. Thus, the practitioner may adapt at the combined jet to the particular features of the teeth of each patient, the presence of brackets, etc.
In some particular embodiments, the fluid depressurizing element comprises means for increasing or reducing the cross section of water pipes and/or air pipes.
This way of modifying the cross section of the pipes is an easy and reliable way of modifying the pressure in the air and water tubes.
In some particular embodiments, at least some portions of the irrigator are made out of materials that can be sterilized in an autoclave machine.
The invention also provides a method for using a dental irrigator according to the first inventive aspect, the method comprising the steps of
In some particular embodiments, the step of using the dental irrigator to clean the dental surface comprises introducing the dental irrigator inside the mouth of a patient to clean a dental surface, such as teeth and/or dental implants and/or dental prostheses. In different particular embodiments, the step of using the dental irrigator to clean the dental surface comprises using the dental irrigator to clean a dental surface, such as dental implants and/or dental prostheses located outside the mouth of a patient.
The main use of the dental irrigator is intra-oral, since it is especially suitable for cleaning dental surfaces inside the mouth of the patient. However, once the irrigator is connected with a suitable device (e.g. dental chair) that can provide for air and water supply, the said irrigator can also be used extra-orally (e.g. dental chair-side) for proper cleaning of the surfaces of dental prosthetic components (e.g. healing abutments, cover screws, etc) prior to their installation in the patient's mouth. Since some of these components are re-usable between patients (after proper disinfection and sterilization protocols have been applied), it is sometimes necessary to clean them by removing organic remnants from their surface. The treatment of the surfaces of these components with air/water jet irrigation as this jet is produced by the dental irrigator can eliminate this issue since it can remove these organic remnants.
This extra-oral method can be also applied to surgical tools. A first water-air cleaning is effective just after the tool has been used, better than waiting for them to be sterilized (this happens hours later, and the blood may dry on the surface of the tool). The treatment of the tools with the jet produced by the dental irrigator, prior to the initiation of the sterilization process, can efficiently and easily remove the blood and increase the safety and efficiency of proper disinfection/sterilization protocols of said tools prior to their use on other patients.
In some particular embodiments, the dental irrigator further comprises a connector, a handpiece and a working tip.
The irrigator comprises three conceptual elements (a connection portion, a fluid depressurizing element and a fluid outlet). However, the physical arrangement of these conceptual elements may be performed in many different ways, without limiting the invention.
In a standard embodiment, the connection portion coincides with a physical connector, the fluid depressurizing element is comprised within a physical handpiece and the fluid outlet is comprised in a physical working tip. In any of these cases, these physical parts may be combined in one, two or three separate parts (for example, the dental irrigator may be made of a single part, wherein the connector, the handpiece and the working tip are manufactured as a single part. In other embodiments, each physical element is manufactured separately and then assembled by some attachments (magnets, clipped joints, screws, rivets, glue, snap-fit joints or any other suitable means for a secure attachment of these physical elements). Each of these physical parts may be manufactured of a different material, but in other cases, the same material is used for all of them.
In other embodiments, the fluid depressurizing element may be comprised within the physical connector, or even in the physical working tip. This does not alter the spirit of the invention, which is that it comprises a connection portion, a fluid depressurizing element and an exit for the combined jet. The physical arrangement of the conceptual elements is not limited within the present invention (always requiring that the fluid mixer receives the water and air supply from the connection portion and provides a reduced-pressure combined jet to the fluid outlet.
In some particular embodiments, the dental irrigator further comprises at least one elastic o-ring located between the handpiece and at least one of the connector and the working tip.
These o-rings are intended to allow proper water and/or air sealing between the handpiece and at least one of the end parts (connector and working tip) during standard operation of said dental irrigator.
In some particular embodiments, the working tip is made out of elastomeric or other flexible material.
An adaptable working tip is advantageous for adapting to the morphology of the patient's tissue.
In some particular embodiments, the working tip has a straight or a curved shape.
In some particular embodiments, the fluid outlet comprised in the working tip is arranged to provide a fluid exit projected in the same direction as the tangent to the end of the working tip or in a different direction or in different directions.
In some particular embodiments, the fluid outlet comprised in the working tip has a shape of a circle, a semicircle, al ellipse, a spiderweb, a circle with at least one wing, a helix and/or a combination thereof.
A straight shape may be advantageous in some conditions, coupled with some of the shapes and orientations. A curved shape may be advantageous in other conditions, coupled with different shapes and orientations.
In some particular embodiments, the working tip comprises a chamber that is cylindrical or frustoconical, while the rest of the tip can have the same or a different shape.
In some particular embodiments, the dental irrigator further comprises a heater to increase the temperature of the water jet.
This is a useful feature since it can warm the water and produce a spray comprising a temperature that will reduce any cold sensitivity experienced by his/her teeth when the later receive the treatment.
In some particular embodiments, the dental irrigator further comprises a light source.
Apart of the advantage of having light and irrigation in a single device (not needing an external light source), the light direction is properly aligned with the working path of the device, making the whole process of operation easier.
In some particular embodiments, this light source is an electric light source, such as a LED or an halogen bulb. This means that the irrigator also comprises an electric supply for feeding the light source.
In other embodiments, the light source is an optic fibre light guide receiving light from an external element, such as the dental chair. In these cases, there is no need of any electric supply.
To complete the description and in order to provide for a better understanding of the invention, a set of drawings is provided. Said drawings form an integral part of the description and illustrate an embodiment of the invention, which should not be interpreted as restricting the scope of the invention, but just as an example of how the invention can be carried out. The drawings comprise the following figures:
The example embodiments are described in sufficient detail to enable those of ordinary skill in the art to embody and implement the systems and processes herein described. It is important to understand that embodiments can be provided in many alternate forms and should not be construed as limited to the examples set forth herein.
Accordingly, while embodiment can be modified in various ways and take on various alternative forms, specific embodiments thereof are shown in the drawings and described in detail below as examples. There is no intent to limit to the particular forms disclosed. On the contrary, all modifications, equivalents, and alternatives falling within the scope of the appended claims should be included. Elements of the example embodiments are consistently denoted by the same reference numerals throughout the drawings and detailed description where appropriate.
The basic operation of this irrigator is as follows: water enters the device at a first water pressure by the water inlet 2 of the connection portion 1. In turn, air enters the device at a first air pressure by the air inlet 3 of the connection portion 1. The water jet, after crossing through the connection portion, enters a first inlet of the fluid pneumatic atomizer, while the air jet, after crossing the connection portion, enters the second inlet of the fluid pneumatic atomizer 4. The fluid pneumatic atomizer 4 has an internal arrangement which mixes these two jets and decreases the pressure of both jets, producing a combined jet, which exits from its outlet, and has a pressure which is lower than the first air pressure and/or lower than the first water pressure.
Once this combined jet has been produced, it is transferred by a tube to the fluid outlet 5, which is configured to receive the combined jet from the fluid depressurizing element and projecting the combined jet outside the dental irrigator.
The aim of this dental irrigator is producing an outlet jet with a pressure comprised between 60 and 140 kPa, to avoid damaging the patient's oral tissue.
The specific location of the fluid pneumatic atomizer 4 may be varied depending on the design needs. It may be located in the connection portion or it may be located in any other location of the assembly.
This figure also shows two pressure adjusters, which are accessible for the user. An air pressure adjuster 14 is configured to modify the outlet air pressure and a water pressure adjuster 15 is able to modify the outlet water pressure. Thus, the practitioner is able to adapt the pressure drop depending on the supply features (each dental chair may have a different water and/or air pressure) and on the patient characteristics (gum tissue conditions, presence of brackets, etc).
This is an alternative arrangement, where pressure is reduced by specific pressure reducers 6, which are independent of the atomizer 4. In fact, if the pressure is reduced before the atomizer 4, the latter may be replaced by a simple mixing chamber, since there is no need of further pressure reduction. One of these pressure reducers 6 has an adjuster 16.
In this case, only air pressure is reduced, since the water pressure is considered to be perfectly suitable for being mixed with the air, without its pressure being reduced. In this particular embodiment, a simple mixing chamber 8 is therefore used, for a simple mixing of both jets.
In some particular embodiments, the working tip comprises a chamber that is cylindrical or frustoconical, while the rest of the tip can have the same or a different shape.
In the present figure, this chamber works as a mixing chamber 8. Since it is located near the tip of the device, this mix of the water within the working tip chamber reduces the distance of travel for the mixture within the device which is in some cases more efficient for the treatment of the teeth.
As seen in
In this particular embodiment, the connection portion coincides with a physical connector 11, the fluid depressurizing element is comprised within the connector 11 as well and the fluid outlet is comprised in the working tip 13.
Each physical element is manufactured separately and then assembled by some attachments (magnets, clipped joints, screws, rivets, glue, snap-fit joints or any other suitable means for a secure attachment of these physical elements). Each of these physical parts may be manufactured of a different material, but in other cases, the same material is used for all of them.
The working tip is made out of elastomeric or other flexible material, for adapting to the morphology of the patient's tissue.
In some cases, this device has heating means to increase the temperature of the water jet. If the water jet is too cold, it may cause discomfort in the patient, so a small heating resistance is provided to increase the temperature of the water jet, also increasing its effectiveness in cleaning the teeth.
This device may also have a light source, which is useful for the dental practitioner to have a better vision of what is happening inside the mouth of the patient. This light may be provided in two different ways. A first way is providing an electric supply in the device, so that an electric light source (such as a LED) located in the tip emits light which is enough for the dental practitioner to light the working zone. A different way of providing light is by an optic fibre, which receives light from the exterior and just directs it to the mouth of the patient. This is more expensive, but has the advantage of not needing any electrical supply.
In this figure, a first perspective view of the disassembled irrigator is shown.
In this figure, a connection portion 101 is seen. This connection portion 101 comprises a water inlet 102. Further, the irrigator 100 comprises a main body 103, which is intended to be connected to the connection portion 101, and comprises a first end 104 and a second end 106. The first end 104 comprises a first connection element intended to be coupled to the connection portion 101 and the second end 106 is intended to be coupled to a working tip 105. Hence, the main body is configured to let water pass from the first end 104 to the second end 106.
This second end 106 of the main body 103 comprises a second connection element 107 which extends from a main step 108 of the main body until the edge of this main body 103.
The second connection element 107 comprises an inner connection surface 109 and an outer connection surface 110. The inner connection surface 109 is intended to be coupled to the working tip 105, while the outer connection surface 110 is intended to interact with an intermediate connector 113.
The working tip 105 comprises a first portion 111, which is configured to be connected to the inner connection surface 109 and a second portion 112 configured to project the water outside the dental irrigator 100.
There is also an intermediate connector 113, which is arranged to manage the connection between the first portion of the working tip and the second connection element of the main body. Details of this element and this management will be explained in the following figures.
In this irrigator 100, water comes at a suitable pressure directly towards the water inlet. This suitable pressure is obtained by an external pump, which pumps water towards the irrigator. Hence, no air is used in this case, thus allowing the use of a higher pressure without the risk of causing emphysema.
The second connection element comprises a spring 114 which is arranged around the outer connection surface 110. This spring 114 is retained by the main step 108 of the main body and an interior step 115 located in the inner surface of the intermediate connector 113. Hence, the spring 114 exerts a force which intends to push the intermediate connector 113 further away from the main step 108 of the main body.
However, the second connection element 107 comprises a stop element 116 which prevents the intermediate connector 113 from escaping from the dental irrigator 100. This stop element 116 is an o-ring which is arranged on the outer connection surface 110 after the intermediate connector 113 is set into place.
As may be seen in this figure, the length of the outer connection surface 110 is greater than the distance between the interior step 115 and the end 121 of the intermediate connector 113. This is done on purpose, so that the intermediate connector may be forced against the spring force until reaching the main step.
In this case, the operation would be the following: the intermediate connector 113 is forced against the main step 108, as in
To control the circular rotation, there are some friction o-rings 119 arranged on the first portion 111 of the working tip 105. In other embodiments, these friction o-rings may be arranged on the inner connection surface 109. In any case, the aim of these rings 119 is to create a friction fitting between the inner connection surface 109 and the first portion 111 of the working tip 105. Thus, rotation is allowed, but in a controlled way.
In some cases, the irrigator may also comprise an air inlet and a mixing chamber configured to receive the air inlet and the water inlet, reduce the pressure of the mixture and carry the mixture to the second end of the main body.
Finally, at least some of the parts of the irrigator are made out of materials that may be sterilized in an autoclave machine. These parts are assembled by the interposition of elastic o-rings, which ensure water and air tightness of the device.
As seen in this figure, in some cases, the fluid outlet comprised in the working tip is arranged to provide a fluid exit projected in the same direction as the tangent to the end of the working tip or in a different direction or in different directions.
A straight shape may be advantageous in some conditions, coupled with some of the shapes and orientations. A curved shape may be advantageous in other conditions, coupled with different shapes and orientations.
As may be seen in this figure, the fluid outlet comprised in the working tip has a shape of a circle (A), a semicircle, an ellipse (B), a circle with at least one wing (C, D), a spiderweb (E), one or more bands (F, G), a helix (H), a square (1), a circle with obstacles (J), a triangle (K) or a combination thereof.
| Number | Date | Country | Kind |
|---|---|---|---|
| 20210100646 | Sep 2021 | GR | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/GR2022/000051 | 9/27/2022 | WO |
