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Last Updated: March 29, 2024

Claims for Patent: 9,402,998


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Summary for Patent: 9,402,998
Title:Vestibular electronic orthodontic appliance expediter and method
Abstract: A vestibular electronic orthodontic appliance expediter constituted of a lingual sub-member and a buccal sub-member, the lingual sub-member arranged to fit a lingual contour of a gum of a patient, the buccal sub-member arranged to fit a buccal contour of a gum of the patient; a control circuitry; a power supply; a plurality of lingual electrodes, each associated with a particular tooth socket; and a plurality of buccal electrodes, each associated with a particular tooth socket. Either a first or a second type current is generated between lingual and buccal electrodes responsive to the control circuitry. Biochemical molecules involved in bone remodeling, augmented by the electric currents, may be applied to the expediter as a layer of gel containing those molecules on the expediter surface facing the gum tissue. Temperature control enhances the gel effects. pH measurement, as indicators of the cellular response to the combined treatment is further provided.
Inventor(s): Davidovitch; Zeev (Columbus, OH), Sanford; Robert (Hampton, NJ), Davidovitch; Moshe (Tel Aviv, IL)
Assignee: RAPID ORTHODONTICS, INC. (Columbus, OH)
Application Number:14/821,760
Patent Claims:1. A vestibular electronic orthodontic appliance expediter comprising: a lingual sub-member and a buccal sub-member, said lingual sub-member arranged to fit a lingual contour of a gum of a patient over a lingual side of an alveolar bone of the patient, said buccal sub-member arranged to fit a buccal contour of a gum of the patient over a buccal side of the alveolar bone; a control circuitry; a plurality of lingual electrodes disposed on said lingual sub-member, each of said plurality of lingual electrodes adapted to be juxtaposed with a respective one of a plurality of tooth sockets within the alveolar bone; and a plurality of buccal electrodes disposed on said buccal sub-member, each of said plurality of buccal electrodes adapted to be juxtaposed with a respective one of the plurality of tooth sockets within the alveolar bone, wherein said control circuitry is arranged to generate, via said plurality of lingual electrodes and said plurality of buccal electrodes at least one of: a plurality of orthogonal currents, each controlled separately responsive to said control circuitry; and a plurality of parallel currents, each controlled separately responsive to said control circuitry, wherein each of said plurality of orthogonal currents is generated between a respective one of said plurality of lingual electrodes and a respective one of said plurality of buccal electrodes, said respective ones associated with the same respective tooth socket, wherein each of said plurality of parallel currents is generated between one of: a respective one of said plurality of lingual electrodes and one of said plurality of lingual electrodes adjacent thereto; and a respective one of said plurality of buccal electrodes and one of said plurality of buccal electrodes adjacent thereto, and wherein the vestibular electronic orthodontic appliance expediter is shaped such as to be completely tissue borne.

2. The vestibular electronic orthodontic appliance expediter of claim 1, wherein said lingual sub-member and a buccal sub-member are formed into a single contiguous member.

3. The vestibular electronic orthodontic appliance expediter of claim 2, wherein said control circuitry is disposed within said single contiguous member.

4. The vestibular electronic orthodontic appliance expediter of claim 1, wherein said control circuitry is arranged to control the direction of each of said generated currents to expedite bone resorption or deposition caused responsive to an orthodontic force applied to a tooth disposed within the respective tooth socket by an orthodontic appliance.

5. The vestibular electronic orthodontic appliance expediter of claim 1, further comprising a plurality of electrical paths isolated from each other, said control circuitry in electrical communication with each of said plurality of lingual electrodes, or with each of said plurality of buccal electrodes, via a respective one of said plurality of electrical paths.

6. The vestibular electronic orthodontic appliance expediter of claim 1, wherein said control circuitry comprises a user input module arranged to receive a current polarity selection user input, wherein responsive to a particular current polarity selection user input received at said user input module, said control circuitry is arranged to control the direction of said generated orthogonal current between a first of said plurality of lingual electrodes and a first of said plurality of buccal electrodes to oppose the direction of said generated orthogonal current between a second of said plurality of lingual electrodes and a second of said plurality of buccal electrodes, and wherein said control circuitry is arranged to control the direction of said generated parallel current between a pair of adjacent ones of said plurality of lingual electrodes to oppose the direction of said generated parallel current between a pair of adjacent ones of said plurality of buccal electrodes.

7. The vestibular electronic orthodontic appliance expediter of claim 1, wherein said control circuitry comprises a user input module arranged to receive an electrode selection user input, wherein responsive to a particular electrode selection user input received at said user input module, said control circuitry is arranged to generate said plurality of orthogonal currents between a first set of said plurality of lingual electrodes and a first set of said plurality of buccal electrodes, and not generate an orthogonal current between a second set of said plurality of lingual electrodes and a second set of said plurality of buccal electrodes.

8. The vestibular electronic orthodontic appliance expediter of claim 1, wherein said control circuitry is arranged to alternately provide said generated currents for a predetermined active duration and not provide said generated currents for a predetermined quiescent duration, said predetermined active duration being 3-5 hours.

9. The vestibular electronic orthodontic appliance expediter of claim 1, further comprising: a temperature sensor arranged to sense the temperature of the gums of the alveolar bone; and a heating element arranged to heat the gums of the alveolar bone, responsive to said sensed temperature.

10. The vestibular electronic orthodontic appliance expediter of claim 1, further comprising a pH sensor arranged to sense the pH level of the gums of the alveolar bone, wherein said control circuitry is arranged to adjust the magnitude of said plurality of at least one of orthogonal currents and parallel currents responsive to said sensed pH level.

11. The vestibular electronic orthodontic appliance expediter of claim 1, wherein at least a portion of an oral mucosa facing surface of one of said lingual sub-member and said buccal sub-member is coated with a gel comprising an active section of molecules from one of: parathyroid hormone; prostaglandin E2 (PGE2); and interleukin 1 beta (IL-1 .beta.).

12. The vestibular electronic orthodontic appliance expediter of claim 1, wherein each of said plurality of lingual electrodes and each of said plurality of buccal electrodes extends from 1 millimeter apical to the gingival margin to the mucogingival junction of the gum.

13. The vestibular electronic orthodontic appliance expediter of claim 1, wherein each of said plurality of lingual electrodes and each of said plurality of buccal electrodes extends from 1 millimeter apical to the gingival margin to at least one millimeter over the mucosal tissue of the gum.

14. The vestibular electronic orthodontic appliance expediter of claim 1, wherein said control circuitry is arranged to generate the plurality of orthogonal currents and the plurality of parallel currents.

15. The vestibular electronic orthodontic appliance expediter of claim 1, wherein a first of said plurality of lingual electrodes is adapted to be juxtaposed with a first side of a particular tooth socket, and a second of said plurality of lingual electrodes is adapted to be juxtaposed with a second side of the particular tooth socket, the second side of the tooth socket opposing the first side of the tooth socket, wherein a first of said plurality of buccal electrodes is adapted to be juxtaposed with the first side of the particular tooth socket, and a second of said plurality of buccal electrodes is adapted to be juxtaposed with the second side of the particular tooth socket, and wherein said arrangement of said control circuitry to generate said currents comprises an arrangement to generate a first orthogonal current between said first lingual electrode and said first buccal electrode and a second orthogonal current between said second lingual electrode and said second buccal electrode, the direction of said second orthogonal current opposing the direction of said first orthogonal current.

16. The vestibular electronic orthodontic appliance expediter of claim 15, further comprising an orthodontic appliance arranged to provide a rotation force to a tooth having a root within the particular tooth socket, said rotational orthodontic force arranged to generate rotational motion of the tooth, said generated rotation motion defining: a first motion vector in a first direction at a portion of a first side of the tooth; and a second motion vector, in a second direction opposing said first direction, at a portion of a second side of the tooth, the second side of the tooth opposing the first side of the tooth; wherein a first axis extending between said first of said plurality of lingual electrodes and said first of said plurality of buccal electrodes is parallel and aligned with said first motion vector, wherein a second axis extending between said second of said plurality of lingual electrodes and said second of said plurality of buccal electrodes is parallel and aligned with said second motion vector, and wherein the direction of said orthogonal current generated between said first of said plurality of lingual electrodes and said first of said plurality of buccal electrodes and the direction of said orthogonal current generated between said second of said plurality of lingual electrodes and said second of said plurality of buccal electrodes are arranged to expedite bone resorption and deposition caused responsive to said provided rotational orthodontic force.

17. The vestibular electronic orthodontic appliance expediter of claim 1, wherein said control circuitry comprises a user input module arranged to receive an electrode selection user input, wherein responsive to a particular electrode selection user input received at said user input module said control circuitry is arranged to generate: a first of said plurality of parallel currents between a first pair of adjacent ones of said plurality of lingual electrodes; and a second of said plurality of parallel currents between a first pair of adjacent ones of said plurality of buccal electrodes, and not generate a parallel current between at least one of: a second pair of adjacent ones of said plurality of lingual electrodes; and a second pair of adjacent ones of said plurality of buccal electrodes.

18. A vestibular electronic orthodontic appliance expediter comprising: a lingual sub-member and a buccal sub-member, said lingual sub-member arranged to fit a lingual contour of a gum of a patient over a lingual side of an alveolar bone of the patient, said buccal sub-member arranged to fit a buccal contour of a gum of the patient over a buccal side of the alveolar bone; a control circuitry; a plurality of lingual electrodes disposed on said lingual sub-member, each of said plurality of lingual electrodes adapted to be juxtaposed with a respective one of a plurality of tooth sockets within the alveolar bone; and a plurality of buccal electrodes disposed on said buccal sub-member, each of said plurality of buccal electrodes adapted to be juxtaposed with a respective one of the plurality of tooth sockets within the alveolar bone, wherein said control circuitry is arranged to generate a plurality of orthogonal currents and a plurality of parallel currents via said plurality of lingual electrodes and said plurality of buccal electrodes, wherein each of said plurality of orthogonal currents is generated between a respective one of said plurality of lingual electrodes and a respective one of said plurality of buccal electrodes, said respective ones associated with the same respective tooth socket, wherein each of said plurality of parallel currents is generated between one of: a respective one of said plurality of lingual electrodes and one of said plurality of lingual electrodes adjacent thereto; and a respective one of said plurality of buccal electrodes and one of said plurality of buccal electrodes adjacent thereto, and wherein each of said generated orthogonal currents and each of said generated parallel currents is controlled separately responsive to said control circuitry.

19. The vestibular electronic orthodontic appliance expediter of claim 18, wherein the vestibular electronic orthodontic appliance expediter is shaped such as to be completely tissue borne.

20. The vestibular electronic orthodontic appliance expediter of claim 19, wherein each of said plurality of lingual electrodes and each of said plurality of buccal electrodes extends from 1 millimeter apical to the gingival margin to the mucogingival junction of the gum.

21. The vestibular electronic orthodontic appliance expediter of claim 19, wherein each of said plurality of lingual electrodes and each of said plurality of buccal electrodes extends from 1 millimeter apical to the gingival margin to at least one millimeter over the mucosal tissue of the gum.

22. The vestibular electronic orthodontic appliance expediter of claim 18, wherein a first of said plurality of lingual electrodes is adapted to be juxtaposed with a first side of a particular tooth socket, and a second of said plurality of lingual electrodes is adapted to be juxtaposed with a second side of the particular tooth socket, the second side of the tooth socket opposing the first side of the tooth socket, wherein a first of said plurality of buccal electrodes is adapted to be juxtaposed with the first side of the particular tooth socket, and a second of said plurality of buccal electrodes is adapted to be juxtaposed with the second side of the particular tooth socket, and wherein said arrangement of said control circuitry to generate a plurality of orthogonal currents comprises an arrangement to generate a first orthogonal current between said first lingual electrode and said first buccal electrode and a second orthogonal current between said second lingual electrode and said second buccal electrode, the direction of said second orthogonal current opposing the direction of said first orthogonal current.

23. The vestibular electronic orthodontic appliance expediter of claim 22, further comprising an orthodontic appliance arranged to provide a rotation force to a tooth having a root within the particular tooth socket, said rotational orthodontic force arranged to generate rotational motion of the tooth, said generated rotation motion defining: a first motion vector in a first direction at a portion of a first side of the tooth; and a second motion vector, in a second direction opposing said first direction, at a portion of a second side of the tooth, the second side of the tooth opposing the first side of the tooth; wherein a first axis extending between said first of said plurality of lingual electrodes and said first of said plurality of buccal electrodes is parallel and aligned with said first motion vector, wherein a second axis extending between said second of said plurality of lingual electrodes and said second of said plurality of buccal electrodes is parallel and aligned with said second motion vector, and wherein the direction of said orthogonal current generated between said first of said plurality of lingual electrodes and said first of said plurality of buccal electrodes and the direction of said orthogonal current generated between said second of said plurality of lingual electrodes and said second of said plurality of buccal electrodes are arranged to expedite bone resorption and deposition caused responsive to said provided rotational orthodontic force.

24. A vestibular electronic orthodontic appliance expediter comprising: a lingual sub-member and a buccal sub-member, said lingual sub-member arranged to fit a lingual contour of a gum of a patient over a lingual side of an alveolar bone of the patient, said buccal sub-member arranged to fit a buccal contour of a gum of the patient over a buccal side of the alveolar bone; a control circuitry; a plurality of lingual electrodes disposed on said lingual sub-member; and a plurality of buccal electrodes disposed on said buccal sub-member, wherein said control circuitry is arranged to generate a plurality of orthogonal currents via said plurality of lingual electrodes and said plurality of buccal electrodes, wherein each of said plurality of orthogonal currents is generated between a respective one of said plurality of lingual electrodes and a respective one of said plurality of buccal electrodes, wherein each of said generated plurality of orthogonal currents is controlled separately responsive to said control circuitry, wherein a first of said plurality of lingual electrodes is adapted to be juxtaposed with a first side of a particular tooth socket, and a second of said plurality of lingual electrodes is adapted to be juxtaposed with a second side of the particular tooth socket, the second side of the tooth socket opposing the first side of the tooth socket, wherein a first of said plurality of buccal electrodes is adapted to be juxtaposed with the first side of the particular tooth socket, and a second of said plurality of buccal electrodes is adapted to be juxtaposed with the second side of the particular tooth socket, and wherein said arrangement of said control circuitry to generate a plurality of orthogonal currents comprises an arrangement to generate a first orthogonal current between said first lingual electrode and said first buccal electrode and a second orthogonal current between said second lingual electrode and said second buccal electrode, the direction of said second orthogonal current opposing the direction of said first orthogonal current.

25. The vestibular electronic orthodontic appliance expediter of claim 24, further comprising an orthodontic appliance arranged to provide a rotation force to a tooth having a root within the particular tooth socket, said rotational orthodontic force arranged to generate rotational motion of the tooth, said generated rotation motion defining: a first motion vector in a first direction at a portion of a first side of the tooth; and a second motion vector, in a second direction opposing said first direction, at a portion of a second side of the tooth, the second side of the tooth opposing the first side of the tooth; wherein a first axis extending between said first of said plurality of lingual electrodes and said first of said plurality of buccal electrodes is parallel and aligned with said first motion vector, wherein a second axis extending between said second of said plurality of lingual electrodes and said second of said plurality of buccal electrodes is parallel and aligned with said second motion vector, and wherein the direction of said orthogonal current generated between said first of said plurality of lingual electrodes and said first of said plurality of buccal electrodes and the direction of said orthogonal current generated between said second of said plurality of lingual electrodes and said second of said plurality of buccal electrodes are arranged to expedite bone resorption and deposition caused responsive to said provided rotational orthodontic force.

26. The vestibular electronic orthodontic appliance expediter of claim 24, wherein the vestibular electronic orthodontic appliance expediter is shaped such as to be completely tissue borne.

27. The vestibular electronic orthodontic appliance expediter of claim 26, wherein each of said plurality of lingual electrodes and each of said plurality of buccal electrodes extends from 1 millimeter apical to the gingival margin to the mucogingival junction of the gum.

28. The vestibular electronic orthodontic appliance expediter of claim 26, wherein each of said plurality of lingual electrodes and each of said plurality of buccal electrodes extends from 1 millimeter apical to the gingival margin to at least one millimeter over the mucosal tissue of the gum.

29. The vestibular electronic orthodontic appliance expediter of claim 24, wherein said control circuitry is further arranged to generate a plurality of parallel currents via said plurality of lingual electrodes and said plurality of buccal electrodes, wherein each of said plurality of parallel current is generated between one of: a respective one of said plurality of lingual electrodes and one of said plurality of lingual electrodes adjacent thereto; and a respective one of said plurality of buccal electrodes and one of said plurality of buccal electrodes adjacent thereto.

30. A vestibular electronic orthodontic appliance expediter comprising: a lingual sub-member and a buccal sub-member, said lingual sub-member arranged to fit a lingual contour of a gum of a patient over a lingual side of an alveolar bone of the patient, said buccal sub-member arranged to fit a buccal contour of a gum of the patient over a buccal side of the alveolar bone; a control circuitry; a plurality of lingual electrodes disposed on said lingual sub-member, each of said plurality of lingual electrodes adapted to be juxtaposed with a respective one of a plurality of tooth sockets within the alveolar bone; a plurality of buccal electrodes disposed on said buccal sub-member, each of said plurality of buccal electrodes adapted to be juxtaposed with a respective one of the plurality of tooth sockets within the alveolar bone; and a plurality of adjustable pressure elements, wherein said control circuitry is arranged to generate, via said plurality of lingual electrodes and said plurality of buccal electrodes at least one of: a plurality of orthogonal currents, each controlled separately responsive to said control circuitry; and a plurality of parallel currents, each controlled separately responsive to said control circuitry, wherein each of said plurality of orthogonal currents is generated between a respective one of said plurality of lingual electrodes and a respective one of said plurality of buccal electrodes, said respective ones associated with the same respective tooth socket, wherein each of said plurality of parallel currents is generated between one of: a respective one of said plurality of lingual electrodes and one of said plurality of lingual electrodes adjacent thereto; and between a respective one of said plurality of buccal electrodes and one of said plurality of buccal electrodes adjacent thereto, and wherein each of said adjustable pressure elements is arranged to apply an adjustable amount of pressure to a respective one of said plurality of lingual electrodes and said plurality of buccal electrodes.

31. The vestibular electronic orthodontic appliance expediter of claim 30, wherein each of said adjustable pressure elements is arranged to expand responsive to air being injected therewithin, said adjustable amount of pressure applied responsive to said injected air.

32. The vestibular electronic orthodontic appliance expediter of claim 30, wherein each of said adjustable pressure elements is arranged to expand responsive to a pressure member being inserted therewithin, said adjustable amount of pressure applied responsive to said inserted pressure member.

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