The present disclosure relates to dental appliances, and, in particular, to dental appliances that may enhance respiratory performance, for example, during physical activity.
During engagement in a physical activity, the human body utilizes three pathways to create energy in the form of adenosine triphosphate (ATP). The body utilizes a mixture of both fats and carbohydrates to make ATP, with some minimal contributions from protein. However, despite the abundance of fat, the human body will fatigue during physical activity. One common cause of fatigue is the build-up of lactic acid, specifically the hydrogen ions associated with lactic acid build-up that interfere with producing ATP. Thus, reducing lactic acid build-up may reduce fatigue by reducing interference with the production of ATP, which may, for example, improve performance by increasing the duration or intensity of engagement in the physical activity.
Increasing carbon dioxide (CO2) exhalation may reduce build-up of lactic acid, as CO2 in solution acts as a buffer for hydrogen ions in the body. Increasing O2 uptake may also reduce the buildup of lactic acid. Thus, respiratory performance improvement including increasing exhalation of CO2 and increasing O2 uptake may reduce fatigue by reducing lactic acid buildup that may result in improved performance.
Cortisol is a glucocorticosteroid hormone that affects various tissues and organs in the human body. Cortisol may aid the body in responding to stress by, for example, maintaining cardiovascular functions. However, prolonged or excessively high levels of cortisol may cause fatigue, reduce endurance, suppress the immune system, and have other deleterious physiological effects. For example, protein synthesis, which is necessary for repairing and increasing muscles, is important for recovery following engagement in physical activity. However, elevated levels of cortisol have been shown to inhibit protein synthesis. By limiting the ongoing rise in cortisol levels, performance may be improved.
Accordingly, there is a need for improved apparatus as well as related methods that reduce build-up of lactic acid and cortisol during engagement in physical activity.
These and other needs and disadvantages may be overcome by the apparatus disclosed herein. Additional improvements and advantages may be recognized by those of ordinary skill in the art upon study of the present disclosure.
A dental appliance apparatus is disclosed herein. In various aspects, the dental appliance may include a body removably attachable to one or more teeth selected from premolars and molars, and a flange extending forth from lingual portions of the body to contact a tongue at one or more locations proximate the premolars and the molars in order to cause a contraction of the genioglossus that positions the tongue anteriorly and downward toward the mandible by stimulation of the hypoglossal nerve. The dental appliance may include a connector connected to the body, and the connector may pass about buccal-labial sides of the anterior teeth. A bumper may be included on a labial side of the connector, and the bumper may contact the lips to promote pursed lips breathing. An anterior flange may extend lingually from the connector to stimulate the hypoglossal nerve proximate a tongue tip of the tongue in order to cause contraction of the genioglossus that positions the tongue anteriorly and downward toward the mandible.
Related methods of use of the dental appliance may include the step of receiving a dental appliance within a mouth of a user, and may include the step of causing contraction of the genioglossus that positions the tongue anteriorly and downward toward the mandible by stimulating the hypoglossal nerve through contact of the hypoglossal nerve with more flanges that extend forth from lingual portions of the dental appliance. The hypoglossal nerve may be stimulated at various locations around the tongue including the side of the tongue and proximate the tip of the tongue, and flanges may be provided at various locations about the dental appliance to so stimulate the hypoglossal nerve by contact with the tongue.
This summary is presented to provide a basic understanding of some aspects of the apparatus and methods disclosed herein as a prelude to the detailed description that follows below. Accordingly, this summary is not intended to identify key elements of the apparatus and methods disclosed herein or to delineate the scope thereof.
The Figures are exemplary only, and the implementations illustrated therein are selected to facilitate explanation. The number, position, relationship and dimensions of the elements shown in the Figures to form the various implementations described herein, as well as dimensions and dimensional proportions to conform to specific force, weight, strength, flow and similar requirements are explained herein or are understandable to a person of ordinary skill in the art upon study of this disclosure. Where used in the various Figures, the same numerals designate the same or similar elements. Furthermore, when the terms “top,” “bottom,” “right,” “left,” “forward,” “rear,” “first,” “second,” “inside,” “outside,” and similar terms are used, the terms should be understood in reference to the orientation of the implementations shown in the drawings and are utilized to facilitate description thereof. Use herein of relative terms such as generally, about, approximately, essentially, may be indicative of engineering, manufacturing, or scientific tolerances such as ±0.1%, ±1%, ±2.5%, ±5%, or other such tolerances, as would be recognized by those of ordinary skill in the art upon study of this disclosure.
The dental appliance disclosed herein, in various aspects, may be removably attached to at least a portion of the teeth of the user. The dental appliance disclosed herein, in various aspects, may enhance respiratory performance of the user by interaction with various anatomical features of the mouth, jaw, or face, and, thus, increase athletic performance of the user. In various aspects, the dental appliance may afford protection to the teeth, tongue, lips, mandible, or other anatomical features of the mouth, jaw, or face.
The design of the dental appliance, in various aspects, is such that, when the dental appliance is positioned in the mouth, with the individual biting down, the dental appliance stimulates the hypoglossal nerve (XII cranial nerve) causing the genioglossus (tongue protruding muscle) to protrude/contract in a forward motion. This forward contraction of the genioglossus results in an increased oropharynx opening in the throat (Garner, D. P. and McDivitt, E., Effects of mouthpiece use on airways openings and lactate levels in healthy college males. Compendium: A Supplement of Continuing Education in Dentistry, 30(2): 9-13 (2009) and Garner, D. P., Effects of various mouthpieces on respiratory physiology during steady state exercise in college-aged subjects. Gen Dent, 63, 30-34 (2015).
Thus, when a user starts exercising, he/she should breathe through the mouth, while biting down on the mouthpiece. This may result in a type of pursed lip breathing which has been shown to lower ventilation, while improving oxygen and carbon dioxide kinetics and lactate levels during and after endurance exercise. While exercising anaerobically (specifically resistance exercise), the user should clench down and breathe through his/her mouth. This has been shown to decrease cortisol levels post exercise (see study by Garner, Dudgeon, McDivitt and Scheett, The effects of mouthpiece use on gas exchange parameters during steady-state exercise in college-aged men and women. J Am. Dent. Assoc. 2011 142(9) 1041-1047 and Garner, D. P., Dudgeon, W. D., and McDivitt, E., The effects of mouthpiece use on cortisol levels during an intense bout of resistance exercise. Journal of Strength and Conditioning, 25(10): 2866-2871(2011).
As used herein, ventilation is the measure of air into and out of the lunges, and respiratory rate is the measure of the exchange of oxygen and carbon dioxide within the lungs. Specifically, ventilation is the defined as the liters per minute. Respiratory rate is defined herein as breaths per minute. Tidal volume is defined herein as the volume of air inhaled and exhaled during one breath.
Anterior, as used herein, refers to portions of the mouth proximate the front of the mouth for example, proximate the lips or the front incisors. Posterior, as used herein, refers to the back of the mouth, for example, proximate the 3rd molar (if present) or the pharynx. Mesial, as used here, refers to the midline of the mouth. The central incisors are usually located on either side of the mesial line or midline. For example, a structure that extends mesially may extend toward the mesial line or midline, and a structure that is positioned mesially may be positioned about the mesial line or midline. Axial, as used herein, refers to directions along a vertical axis of the body as, for example, generally defined by the spinal column.
The tongue is a complex collection of muscles and nerves that may be stimulated in various ways either directly or indirectly by the dental appliance. The tongue muscles may be divided functionally into protruder muscles that move the tongue blade in the anterior direction and retractor muscles that pull the tongue in the posterior direction toward the posterior pharyngeal wall. Protruder muscles include the extrinsic genioglossus, the intrinsic verticalis and transversus muscles. Retractor muscles include the extrinsic hyoglossus and styloglossus, and the intrinsic inferior and superior longitudinalis muscles. Stimulation of both the genioglossus and hyoglossus may cause depression of the tongue.
The tongue muscles are innervated by branches of the hypoglossal nerve, which is the twelfth cranial nerve. The hypoglossal nerve trunk bifurcates into large mesial and lateral branches as the hypoglossal nerve approaches the tongue muscles, with the mesial branch containing axons supplying the protruder muscles (both intrinsic and extrinsic muscles) and the lateral branch the retractors.
The hypoglossal motor nucleus receives both excitatory and inhibitory synaptic input from many brain regions. Direct inputs originate in the nucleus of the solitary tract, the majority of the reticular nuclei, the principal and spinal trigeminal nuclei, reticularis subcoeruleus, the caudal Raphe nucleus, and the Kolliker-Fuse nucleus. These regions, in turn, receive substantia nigra, the superior colliculus, and the mesencephalic trigeminal nucleus. Many of these regions modulate ventilatory drive, with the reticular formation containing the interneurons that link the central respiratory drive from the pre-Botzinger complex with the hypoglossal motor nucleus. Accordingly, the tongue including the tongue muscles may be connected to respiratory performance through the hypoglossal nerve, so that respiratory performance may be increased by stimulating the tongue or positioning the tongue in certain positions. Increased respiratory performance may reduce fatigue by reducing lactic acid formation, and increased respiratory performance may reduce cortisol levels, which may promote muscle healing and have other beneficial effect.
For example, pursing of the lips appears to correlate with contraction of the genioglossus including expansions or contractions of other tongue muscles thereby positioning the tongue anteriorly and downward toward the mandible. When engaging in pursed lips breathing, the subject purses their lips while breathing in and breathing out slowly. There are two types of pursed lips breathing with one being a decrease in respiratory rate and an increase in tidal volume and the other type of pursed lips breathing being one with a decrease in respiratory rate with no change in tidal volume. It has been found that subjects with chronic obstructive pulmonary disease (COPD) experienced a subsequent and significant reduction in respiratory rate with faster recovery when subjects with COPD practiced pursed lip breathing while exercising, so that pursed lips breathing may be associated with increased respiratory performance.
As noted above, pursed lip breathing may be correlated with the contraction of the genioglossus. Studies of the genioglossus have found that contraction of the genioglossus may cause dilation of the pharyngeal airway. Particularly, when the genioglossus is contracted (i.e. the tongue is pushed down toward the mandible and forward toward the anterior teeth), there is a subsequent relaxation of the pharyngeal area in the back of the throat. Thus, pursed lips breathing may cause contraction of the genioglossus muscle that, in turn, causes dilation of the pharyngeal airway, resulting in the observed increased respiratory performance with pursed lips breathing. Thus, a dental appliance that promotes pursed lips breathing may increase respiratory performance.
In addition, stimulation of the hypoglossal nerve at various locations by the dental appliance may cause contraction of the genioglossus that positions the tongue down and anteriorly thereby resulting in dilation of the pharyngeal airway and concomitant increased respiratory performance. Various stimulations of the hypoglossal nerve by the dental appliance may otherwise signal various other nerves, nuclei, or regions of the brain that may produce various physiological effects that increase respiratory performance. Genioglossus may include the genioglossus as well as other protruder and retractor muscles, and contraction of the genioglossus may include movement of the other protruder muscles or movement of the retractor muscles, as would be readily understood by those of ordinary skill in the art upon study of this disclosure.
A forward shift of the mandible such as may occur with the dental appliance implementations disclosed herein may increase the pharyngeal area. Applicant has found airway anatomical differences with various implementations of the dental appliance, specifically measuring the diameter and width of the oropharynx with computed tomography (CT) scans that demonstrated a 9% improvement in both the diameter and width when subjects used the dental appliance. (See Garner, D. P. and McDivitt, E., Effects of mouthpiece use on airways openings and lactate levels in healthy college males. Compendium: A Supplement of Continuing Education in Dentistry, 30(2): 9-13 (2009)). Although the mandibular displacement of that implementation of the dental appliance was not as pronounced as those with a sleep apneic device, a significant effect on oropharynx width occurred when using the dental appliance.
Finally, it was found that implementations of the dental appliance that allowed subjects to clench all their teeth evenly with vertical displacement and a level pressure distribution between all teeth resulted in increased respiratory performance.
In various aspects, the dental appliance may comprise two bodies received on either side of the mouth with the two bodies connected to one another by a connector. The bodies may be constructed of a plurality of material layers bonded or otherwise secured to one another in various ways. In general, the body portions of the dental appliance may be composed of one or more layers of materials. These materials may include ethyl-vinyl acetate (EVA); thermoplastic polyolefin, various ethylene-based elastomers; various hydrocarbon resins (which are may be combined with EVA, thermoplastic polyolefin, or various ethylene-based elastomers), polycaprolactone (which may be combined with EVA), low-density polyethylene, high density poly-ethylene, polycarbonate and/or various polymers, laminates and other materials that will be recognized by those skilled in the art upon review of the present disclosure. In certain aspects, the composite material may be a pre-laminated sheet including a layer of polycarbonate bound to a layer of polyester urethane which is available under the trade name Durasoft® from the Scheu Dental Co. located in Iserlohn, Germany. Typically, these materials may be selected with a durometer (hardness) of between about 70 A to about 96 A or between about 55 D and about 90 D.
As described herein, in various aspects, one of the material layers of the plurality of material layers is a bite pad, and another of the material layers is an occlusal pad. Various other material layer(s) may be interposed between the bite pad and the occlusal pad, and additional material layer(s) may be placed about the occlusal pad or about the bite pad, in various aspects. The dental appliance may be constructed, at least in part, of the bite pad bonded to the occlusal pad, and the bite pad with the occlusal pad bonded thereto forms at least a portion of the dental appliance. In various aspects, the bite pad may support the occlusal pad, may interact with other elements of the dental appliance, and may confer various mechanical properties upon the dental appliance. The bite pad may interact with the teeth, and, thus, may be configured with treads including other tooth grippable surface, and the bite pad may have a selected hardness as indicated, for example, by a Shore hardness value as measured by a durometer. In various aspects, the occlusal pad may engage the user's teeth to attach removably the dental appliance thereto, and the occlusal pad may be custom fitted to engage the user's teeth. The occlusal pad may have a selected hardness as indicated, for example, by a Shore hardness value.
The bite pad is composed of one or more bite pad materials. In various aspects, the bite pad material may include a mixture of styrene block copolymer and ethylene vinyl acetate (EVA). An exemplary styrene block copolymer is available as DYNAFLEX® part number G2782 from GLS Corporation, Thermoplastic Elastomers Division, 833 Ridgeview Dr., McHenry, Ill. 60050. EVA is available from a number of sources, such as the ELVAX® resins from Dupont Packaging and Industrial Polymers, 1007 Market Street, Wilmington, Del. 19898.
In various aspects, the bite pad material may include a mixture of a styrene block copolymer and a polyolefin elastomer. The polyolefin elastomer may be a copolymer of ethylene and octene-1. An exemplary copolymer is available as ENGAGE® from Dupont Canada, Inc., P.O. Box 2200, Streetsville, Mississauga, Ontario L5M 2H3.
The bite pad material may include, in various aspects, a mixture of a thermoplastic rubber, which includes thermoplastic elastomer and thermoplastic urethane, with a polyolefin elastomer. Exemplary thermoplastic rubbers are Santoprene® thermoplastic elastomer from Advanced Elastomer Systems, L. P., 388 South Main Street, Akron, Ohio 44311 and Kraton® thermoplastic elastomer from the Shell Oil Company, Houston, Tex. Kraton® includes astyrene-ethylenelbutylenes-styrene block copolymer. In various aspects, the bite pad material may include polypropylene part number AP6112-HS from Huntsman Corporation, Chesapeake, Va. 23320. In various aspects, the bite pad material may include HD-6706 ESCORENE® Injection Molding Resin [a high density polyethylene] from ExxonMobil Chemical Company, P.O. Box 3272, Houston, Tex.
The bite pad material of the bite pad, in various aspects, may have a durometer of at least 60 D to resist substantial deformation and retaining a substantially planar configuration between at least two cusps of the teeth of the user when the teeth of the user are clenched about the bite pad. In various aspects, the bite pad material of the bite pad may have a durometer of between about 60 D to about 90 D although this may vary. In some aspects, the bite pad material of the bite pad has a Shore A hardness of about 82.
The occlusal pad is composed of one or more occlusal pad materials. In various aspects, the occlusal pad material may be transformable between a pliable state and a non-pliable state. In the pliable state, the occlusal pad material of the occlusal pad may be shaped to conform to the teeth of the user. In the non-pliable state, the occlusal pad material of the occlusal pad generally retains its conformance to the teeth of the user as shaped when in the pliable state. In various aspects, the occlusal pad may be transformed between the pliable state and the non-pliable state by heating and cooling, respectively. For example, heating the occlusal pad material in warm water may allow the occlusal pad to be fitted to the user's teeth and, after having been fitted, the occlusal pad material may be cooled to the non-pliant state thereby capturing the fit of the user's teeth in the occlusal pad material. The occlusal pad material is transformed from the non-pliable state to the pliable state at a temperature tolerable by the user upon placement of the occlusal pad material in the pliable state within the user's mouth, in various aspects. The occlusal pad material may transform between the non-pliant and pliant state at a temperature greater than human body temperature but less than about 100° C., in various implementations.
In various aspects, the occlusal pad material of the occlusal pad includes a mixture of polycaprolactone. An exemplary polycaprolactone is Capra 6500 polycaprolactone from Perstorp, UK Limited, Warrington, Cheshire UK. In various aspects, the occlusal pad material of occlusal pad 40 includes a mixture of polycaprolactone and ethylene vinyl acetate (EVA) such as ELVAX®. In various aspects, the occlusal pad material of occlusal pad 40 includes ethylene vinyl acetate (EVA) alone, such as ELVAX®. In various aspects, the occlusal pad material of occlusal pad 40 includes a mixture of polycaprolactone and a polyolefin elastomer, and the polyolefin elastomer may be a copolymer of ethylene and octene-1. An exemplary copolymer is available as ENGAGE® from Dupont Canada, Inc., P.O. Box 2200, Streetsville, Mississauga, Ontario L5M 2H3.
Connector 70 includes bumper 80, and occlusal pads 40, 42 include flanges 90, 92, in this implementation. Bodies 20, 22 of exemplary dental appliance 10 include occlusal pads 40, 42 bonded to bite pads 30, 32, respectively. As illustrated, side 46 of occlusal pad 40 is bonded to side 36 of bite pad 30 and side 48 of occlusal pad 42 is bonded to side 38 of bite pad 32. Sides 36, 38, are generally oriented opposite to sides 37, 39 of bite pads 30, 32, respectively, and sides 46, 48, are generally oriented opposite to sides 47, 49 of occlusal pads 40, 42, in this implementation.
Occlusal pads 40, 42 define occlusal pad channels 56, 58 in sides 47, 49, respectively, in this implementation. In exemplary dental appliance 10, occlusal pad channels 56, 58 may removably engage teeth on opposing sides of the mandible generally in the posterior portion of the mandible. For example, occlusal pad channels 56, 58 of dental appliance 10 engage the mandibular 1st bicuspid, mandibular 2nd bicuspid, mandibular 1st molar, mandibular 2nd molar, and mandibular 3rd molar on the right and left sides, respectively. Occlusal pad channels 56, 58 may be fit to the user's teeth in order to conform to the shape of the user's teeth including interstices between the user's teeth. Note that the mandibular 3rd molars (left and right; i.e. wisdom teeth) may be omitted from the illustrations and discussion herein for clarity of explanation and because the mandibular 3rd molars are frequently absent.
The occlusal pad channels 56, 58 are elongated, as illustrated, and are generally oriented along the mesial-distal axis. The at least a portion of occlusal pad channels 56, 58 may extend over one or more of the canines, premolars and/or molars on each side of the mouth. The occlusal pad channels 56, 58 may be configured in shape of the teeth of the user. A channel occlusal surface 57, 59 of occlusal channels 56, 58, respectively, contacts at least a portion of the occlusal surface of the teeth. The channel occlusal surfaces 57, 59 may be configured to conform to a least a portion of the occlusal surface of the user's teeth and may be configured to conform to the surfaces of all of the teeth received in the occlusal channels 56, 58. To conform, typically, cavities will be formed in the channel occlusal surfaces 57, 59 that correspond to at least the cusps of the occlusal surfaces of the teeth. In certain aspects, this may more evenly distribute the force from clenching or an impact over the occlusal surface of the teeth and, among other things, may also improve retention and fitment of dental appliance 10.
When occlusal pad cannels 56, 58 of occlusal pads 40, 42 are engaged with the teeth of the mandible, sides 47, 49 of occlusal pads 40, 42 are oriented toward the gum of the mandible and sides 37, 39 of bite pads 30, 32 are oriented toward teeth of the upper jaw. The teeth of the upper jaw may engage with sides 37, 39 of bite pads 30, 32, respectively. Sides 37, 39 of bite pads 30, 32 may include treads and so forth, and may otherwise be generally adapted to contact occlusal surfaces of posterior teeth of the upper jaw opposite to the mandibular teeth engaged with occlusal pad channels 56, 58 of occlusal pads 40, 42.
Bite pads 30, 32 may be of sufficient hardness to resist substantial penetration by the teeth and deformation as the teeth of the user are clenched about bite pads 30, 32. Bite pads 30, 32 may be formed from a material such as, for example, high density polyethylene or polypropylene that may have a durometer of between about 60 D to about 90 D.
As illustrated in
Connector 70 may be configured to extend as an arch around either the lingual side, labial side, or both the lingual side and labial side of the anterior teeth of the user, in various implementations. In certain implementations, connector 70 may extend along or just below the gum line on dental appliance 10, which is configured to be removably attached to the mandibular teeth.
Connector 70 and occlusal pads 40, 42 may be formed as a unitary structure in some implementations such that connector 70 extends between occlusal pads 40, 42, as illustrated. In other implementations, connector 70 and bite pads 30, 32 may be formed as a unitary structure, such that connector 70 extends between bite pads 30, 32. In still other implementations, connector 70 may be attached to bite pads 30, 32, occlusal pads 40, 42, or both bite pads 30, 32 and occlusal pads 40, 42 by, for example, various adhesives, mechanical connections, thermal bonding, and combinations thereof.
When dental appliance 10 is positioned in the mouth with occlusal pad channels 56, 58 engaged with posterior mandibular teeth, connector 70 generally passes about labial portions of the anterior mandibular teeth of the user with side 71 of connector 70 biased against the anterior mandibular teeth, and side 73 of connector 70 is oriented labially (i.e. toward the lips). Note that side 71 of connector 70 is fit to the user's teeth, in this implementation, so that side 71 conforms to the shape of the user's teeth including the interstices between the teeth.
As illustrated in
Flanges 90, 92 extend forth mesially from lingual side 14 of dental appliance generally along the straight portions of the “U,” as illustrated in
As illustrated, flanges 90, 92 are somewhat wedge-shapes with the broad part of the wedge being where flanges 90, 92 emerge from lingual side 14 of dental appliance 10 and flanges 90, 92 then tapering to form edge 91, 93. In other implementations, flanges 90, 92 may be more planar in shape with generally constant thickness between sides 96, 98 and generally constant thickness between sides 97, 99. Flanges 90, 92 extend mesially a distance sufficient to impinge upon the side of the tongue thereby compressing portions of the genioglossus while avoiding creating a gag response, the distance being specific to the anatomy of the user, in various implementations.
Edges 91, 93 are formed along the side of flanges 90, 92 that extend furthest in the mesial lingual direction. Edges 91, 93 are sufficiently blunt (illustrated as being rounded but other implementations may have other shapes) so that edges 91, 93 do not injure the tongue. The axial dimension of edge 91, 93 is less than the axial dimension of bases 20, 22 as given, for example, by the length between side 39 and side 49 or the length between lingual body edge 133 and side 39.
Flanges 90, 92 are exemplary, and flange as used herein may include protuberances, extensions, or structures that extend forth from the lingual side of the dental appliance and are configured to touch the tongue in order to stimulate the hypoglossal nerve of the tongue, for example, by compression of the genioglossus including other muscles or tissues of the tongue. The flanges 90, 92 may stimulate the hypoglossal nerve by touching portions of the tongue enervated by thy hypoglossal nerve such as portions of the tongue along the side of the tongue. Flanges, such as flanges 90, 92, may have other shapes in other implementations. Edges 91, 93 are exemplary, and edge as used herein may include portions of the flange that generally contact the tongue to stimulate the hypoglossal nerve.
The implementation of dental appliance 10 includes supports 52 (illustrated in phantom) that are imbedded within flanges 90, 92 to support structurally flanges 90, 92. Flanges 90, 92 may be of unitary construction with the occlusal pads 40, 42, so that flanges 90, 92 are formed of the same material as occlusal pads 40, 42 and molded around supports 52. Supports 52, in this implementation are cantilevered from bite pads 30, 32 with support ends 51 of supports 52 secured to bite pads 30, 32. Supports 52 may be of unitary construction with bite pads 30, 32, or support ends 51 of supports 52 may be attached to bite pads 30, 32, for example, by adhesive. Supports 52 have a “T” shape at support ends 53, but may have, for example, a “Y” shape, or other shape or combination of shapes, in other implementations. Various numbers of supports 52 may be included in various implementations of dental appliance 10, or, in some implementations, supports 52 may be omitted entirely. In other implementations, flanges, such as flanges 90, 92, may extend lingually mesially from bite pads, such as bite pads 30, 32, and may be formed of the same material as the bite pads, or flanges may extend forth from other portions of a lingual side of a dental appliance, such as lingual side 14 of dental appliance 10.
As illustrated in
The biasing of edges 91, 93 of flanges 90, 92 against at least portions of sides 110, 112, respectively, of tongue 100 may compresses the genioglossus along the side of the tongue or may otherwise physically touch the tongue to stimulate the hypoglossal nerve. Stimulation of the hypoglossal nerve by flanges 90, 92 may cause contraction of the genioglossus that positions the tongue 100 anteriorly and lowered toward the mandible, which may result in dilation of the pharyngeal airway and, thus, increased respiratory performance. Scalloped edges 91, 93, as illustrated, may be more effective in stimulating the hypoglossal nerve than straight edges, as, for example, the scalloped edges may differentially compress the genioglossus or otherwise differentially stimulate the tongue. For example, peaks of the scallop shape may compress the genioglossus while the valleys of the scallop shape may compress the genioglossus a lesser amount than the peaks or may avoid compressing the genioglossus altogether. Edges, such as edges 91, 93, may have waved, straight, saw-tooth, or other configurations or combinations of configurations, in other implementations.
Occlusal pad channels 56, 58 of bodies 20, 22 engage teeth 500k, 5001, 500m, 500n on the right side and teeth 500a, 500b, 500c, 500d on the left side, respectively, as illustrated in
Note that the mandibular 3rd molars (left and right; (i.e. wisdom teeth) are omitted from
Connector 70 generally passes about buccal-labial portions of the anterior mandibular teeth of the user with side 71 of connector 70 biased against the anterior mandibular teeth, for example teeth 500e, 500f, 500g, 500h, 500i, 500j, and side 73 of connector 70 is oriented labially (i.e. toward the lips), as illustrated in
As illustrated in
Portions of connector 70 extend posteriorly from lingual side 66 of tooth 62 to form anterior flange 74 with posterior end 75. Anterior flange 74 may extend a distance T from the centerline of tooth 62 to posterior end 75, as illustrated in
Engagement of anterior flange 74 including posterior end 75 or side 78 with portions of the tongue 100 proximate tongue tip 113 as well as the position of anterior flange 74 with respect to connector 70 may cause contraction of the genioglossus, and may, by the location of side 78, position the tongue 100 anteriorly and lowered toward the mandible, which may result in dilation of the pharyngeal airway and, thus, increased respiratory performance.
It should be noted that stimulation of the lip(s), such as lip 120, by bumper 80 and contraction of the genioglossus caused by stimulation of tongue 100 at various locations by flanges 74, 90, 92 all potentially implicate stimulation of the hypoglossal nerve including the trigeminal nerve (fifth cranial nerve), and various portions of the brain in communication with the hypoglossal nerve or the trigeminal nerve that may be associated with respiration. Thus, such stimulation of the tongue at various locations by flanges 74, 90, 92 as well as pursed lips breathing as provoked by bumper 80 may increase respiratory performance is other ways that may or may not be known at present.
When the teeth are engaged in the occlusal channel 58 of dental appliance 10, a buccal body edge 131 of body 22 is positioned above the gum line of the user, as illustrated. In other implementations, buccal body edge 131 may extend below the gum-line of the user, or portions of buccal body edge 131 may be above the gum-line while other portions of buccal body edge 131 may extend below the gum-line. In some implementations, the buccal body edge 131 may be generally proximate the occlusal surface of the teeth so that the buccal side of occlusal channel 58 is either de minimis or omitted entirely.
Similarly, lingual body edge 133 may be variously positioned above the gum-line, as illustrated. Lingual body edge 133 may extend below the gum-line or portions of lingual body edge 133 may be above the gum-line while other portions of lingual body edge 133 may extend below the gum-line, in various implementations. In some implementations, the lingual body edge 133 may be generally proximate the occlusal surface of the teeth so that the lingual side of channel 58 is either de minimis or omitted entirely.
Flange 92, as illustrated, is of generally unitary construction with occlusal pad 42, and support 52 is cantilevered from bite pad 32 to support flange 92. Support end 51 of support 52 is attached to bite pad 32, and support end 53 of support 52 has a “T” configuration, as illustrated, and support 52 lies internally within flange 92. Edge 93 of flange 92 may be biased against the side 112 of the portion of the tongue 100, for example, from about tooth 500a to tooth 500d. In other implementations, flange 92 may be of generally unitary construction with occlusal pad 42, or flange 92 may be of unitary construction with one or more other layers interposed between bite pad 32 and occlusal pad 42.
As illustrated in
As illustrated in
As illustrated in
The thickness t from the occlusal surface of a tooth, such as tooth 106, to side 39 of bite pad 32, as illustrated in
As illustrated in
The thickness t may vary from about 1 mm to about 2 mm, in some implementations. In various implementations, thickness t may be generally about 5 mm at posterior end 17 and about 4 mm at anterior end 19. Thickness t may be generally in the range of about 2 mm to about 6 mm at proximal end 17 and thickness t may be generally in the range of about 1 mm to about 4 mm at anterior end 19. Most specifically, the thickness t may range approximately from 1.7 mm to 2.2 mm, while the thickness t at the anterior end 19 to side 39 of bite pad 32 at the anterior end 19 may range between approximately 0.7 mm to 1.2 mm. In some implementations, the thickness t may approach 0.00 millimeters (e.g. an edge) at the anterior end 19. In various implementations, the bite pads slope, for example with 1 mm anterior end 19 increasing gradually in slope to 2 mm posterior end 17. Note that, in implementations without a bite pad, such as bite pad 32, length L, width W, thickness t, and slope At/L may be defined in reference to such implementations in ways as would be readily recognized by those of ordinary skill in the art upon study of this disclosure.
The slope At/L may enhance forward protrusion of the mandible (jaw) due to the biting down on these bite pads, the lack of material on the backside of the front bottom teeth, and the material on the inside of the dental appliance which aids in pushing the tongue in and forward, in such implementations.
The bite pads 30,32 elevate and create a minimal opening so that the individual may clench on the dental appliance and breathe through the mouth. If the thickness t too large, dental appliance 10 may not properly stimulate the hypoglossal nerve in ways that result in a pushing down and forward motion of the tongue, so that the dental appliance 10 fails to function properly. If the thickness t too large, a pressing down of the tongue by dental appliance 10 may not occur. In various other implementations, the thickness t may be between about 0.25 millimeter and about 2.5 millimeters. Bite pads 30, 32 may have a constant thickness with respect to length, a varying thickness with respect to length, or either a constant or varying thickness along the width.
The effects of dental appliance 10 use on respiratory performance may be related, at least in part, to the even contact between occlusal surfaces and bite pads 30, 32, which may be promoted by the slope At/L. The slope At/L may allow all teeth to contact bite pads 30, 32 equally at maximal intercuspal positions. Laboratory results seem to indicate that differences in the evenness of contact between teeth, along with varying vertical dimensions have resulted in different outcomes (Garner, 2015). (See: Murakami, S., Maeda, Y., Ghanem, A., Uchiyama, Y., & Kreilborg, S. Influence of mouthguard on temporomandibular joint. Scand J Med Sports, 18, 591-595 (2008); Pae, A., Yoo, R., Noh, K, Pake, J., & Kwon, K The effects of mouthguards on the athletic ability of professional golfers. Dent Traumatol, 29, 47-51 (2013))
For example, the slope of bite pad 32, as illustrated in
Anterior flange 74 engages tongue tip 113 in various ways to stimulate the hypoglossal nerve. As illustrated, tongue tip 113 of tongue 100 is in contact with posterior end 75 of anterior flange 74 and with side 78 of anterior flange 74, which may cause positioning of the tongue down and anteriorly resulting in dilation of the pharyngeal airway and concomitant increased respiratory performance.
As illustrated in
In the implementation of
When occlusal pad cannels 256, 258 of occlusal pads 240, 242 are engaged with maxillary teeth, sides 247, 249 of occlusal pads 240, 242 are oriented toward the maxillary gums and sides 237, 239 of bite pads 230, 232 are oriented toward the mandibular teeth. The mandibular teeth may engage with sides 237, 239 of bodies 220, 222, respectively, which may include treads and so forth, and may otherwise be generally adapted to engage the mandibular teeth.
As illustrated in
As illustrated in
In various implementations, flanges 290, 292 may be of unitary construction with the occlusal pads 240, 242, so that flanges 290, 292 are formed of the same material as occlusal pads 240, 242. In various implementations, flanges 290, 292 may be of unitary construction with the bite pads 230, 232, so that flanges 290, 292 are formed of the same material as bite pads 230, 232. Flanges 290, 292 may extend forth from various portions of lingual side 214 of dental appliance 200 including various portions of body 220, 222, in various implementations.
As illustrated in
Edge 291 of flange 290 may be biased against at least portions of side 310 of the portion of the tongue 300, for example, adjacent maxillary tooth 306. Edge 293 of flange 292 may be biased against portions of side 310 of tongue 300, as illustrated in
As illustrated in
Various commercially available dental appliances and modifications of the commercially available dental appliances were tested in vivo in Experiment 1. These tests are labeled R1-R5 and are described as follows:
Two exemplary configurations of the dental apparatus according to the present disclosure were tested in vivo in Experiment 1. These are labeled and described as follows:
In Experiment 1, the subject ran 5 minutes on a treadmill with the dental appliance inserted in the subject's mouth. Then, the respiratory rate of the subject was measured using a True Max metabolic cart manufactured by Parvo Medics, Inc., Sandy, Utah immediately following the 5 minute run on the treadmill, The same subject tested each of the dental appliances. The tests occurred on different days, so that the subject had sufficient time to recover physically between tests. The subject was, of course, in good physical condition. Results for the various dental appliances are illustrated in
As illustrated in
Thus, these experimental results indicate that respiratory rate decreased by as much as 13 BPM when dental appliances DG prototype and DG tong were used by the subject from the respiratory rates exhibited when the subject either used no dental appliances R1 or when the subject used dental appliances R2-R5. The decrease in respiratory rate using dental appliances DG prototype and DG tong is indicative of increased respiratory performance resulting from use of dental appliances DG prototype and DG tong.
In operation, the dental appliance, such as dental appliance 10, 140, 150, 200, 450, may be received in the mouth of the user in removable attachment to one or more teeth, such as tooth 500a, 500b, 500c, 500d, 500k, 5001, 500m, 500n, or various maxillary teeth such as maxillary molars and maxillary bicuspids. The dental appliance may be removably attached to various combinations of teeth in various implementations.
With the dental appliance removably attached within the mouth of a user, one or more flanges, such as flange 74, 90, 92, 290, 292, 432, 438, 442, 462, 472, 482, 486, 492, 690 may contact the tongue, such as tongue 100, 300, 405, 455, 609 to stimulate the hypoglossal nerve of the tongue at various locations in order to prompt forward contraction of the genioglossus. Forward contraction of the genioglossus may result in dilation of the pharyngeal airway and concomitant increased respiratory performance. The hypoglossal nerve may be stimulated at various locations around the tongue including the side of the tongue and proximate the tip of the tongue, and flanges may be provided at various locations about the dental appliance to so stimulate the hypoglossal nerve by contact with the tongue.
A bumper, such as bumper 80, may stimulate the lip or lips to provoke pursed lip breathing that may increase respiratory performance. Wedge shaped bite pads, such as bite pads 30, 32, may position the jaw in ways that increase respiratory performance.
Various stimulations of the lips, the hypoglossal nerve, positioning of the jaw, and combinations thereof by the dental appliance may increase respiratory performance by other as yet unrecognized physiologic responses.
The foregoing discussion along with the Figures discloses and describes various exemplary implementations. These implementations are not meant to limit the scope of coverage, but, instead, to assist in understanding the context of the language used in this specification and in the claims. The Abstract is presented to meet requirements of 37 C.F.R. § 1.72(b) only. This Abstract is not intended to identify key elements of the apparatus and methods disclosed herein or to delineate the scope of this disclosure. Upon study of this disclosure and the exemplary implementations herein, one of ordinary skill in the art may readily recognize that various changes, modifications and variations can be made thereto without departing from the spirit and scope of the inventions as defined in the following claims.
This continuation patent application claims priority to and benefit of, under 35 U.S.C. § 120, U.S. Continuation patent application Ser. No. 16/406,324, filed May 8, 2019 which claims priority to U.S. patent application Ser. No. 14/993,198, now issued as U.S. Pat. No. 10,328,225, filed Jan. 12, 2016, which claims priority and benefit of U.S. Provisional Patent Application No. 62/244,107 filed Oct. 20, 2015, all of which are hereby incorporated by reference in their entireties herein.
Number | Date | Country | |
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62244107 | Oct 2015 | US |
Number | Date | Country | |
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Parent | 16406324 | May 2019 | US |
Child | 17545434 | US | |
Parent | 14993198 | Jan 2016 | US |
Child | 16406324 | US |