Dental applicance for treating bruxism

A dental appliance for treating bruxism is provided which, according to one aspect of the invention, has a mouthpiece containing an electric source, electrodes, and circuitry connecting the source to the electrodes, and circuitry connecting the source to the electrodes. The electrodes are disposed to contact an interior surface of the wearer's mouth to conduct electric stimuli to the mouth. Included in the electronic circuitry, are sensors which trigger the flow of electric current from the source to the electrodes when squeezed together by the wearer's teeth.

TECHNICAL FIELD 
This invention relates to dental appliances, particularly to mouthpieces 
used to treat bruxing. 
BACKGROUND OF THE INVENTION 
Many people, for reasons not clearly understood, grind their teeth at night 
while sleeping. The usual complaints related by this group of people are 
soreness in joints, facial muscles, and neck muscles, headaches, clicking 
of the jaw, earaches, etc. Most of these people seek help from their 
dentist or physician who cite headache disorders, cranial neuralgia and 
facial pain as the most common symptoms. This grinding of the teeth is 
called bruxing. Commonly, the grinding of the teeth takes place during the 
night and the condition is referred to as nocturnal bruxism. Such 
clenching and grinding of the teeth can also lead to the onset of 
temporomandibular joint syndrome or temporomandibular disfunction referred 
to as TMJ syndrome or TMD. 
In spite of the fact that there has been an explosion of interest and 
research regarding bruxism and TMJ disorders in the past ten years, the 
most common treatment continues to be the "night splint" usually 
prescribed by dentists. A night splint is a plastic dental appliance made 
from a model of the patient's teeth and is designed to fit firmly on 
either the upper or lower teeth. The night splint is usually fitted to the 
upper teeth and is somewhat similar to a boxer's mouthpiece. 
In general, most attempts to relieve people of the TMJ syndrome or its 
precursor "nocturnal bruxism" have failed. People fitted with a night 
splint usually grind through the appliance over time and are required to 
have another made. Such an appliance may prevent further deterioration of 
the teeth and relieve pressure on the joints but does little or nothing to 
prevent the grinding process. 
Some inventions have attempted to incorporate the use of electronic stimuli 
in conjunction with various dental appliances. In both Tepper, U.S. Pat. 
No. 3,259,129, and Tepper, U.S. Pat. No. 3,277,892, a dental appliance for 
correcting tongue thrust problems is disclosed. Each of these patents 
describes a dental retainer including a source of electricity connected to 
a pair of electrodes embedded in the retainer. When the wearer's tongue is 
improperly thrust forward into contact with the electrodes, an electrical 
stimulus is imparted to the wearer's tongue. The Tepper devices, however, 
do nothing to prevent the wearer from grinding his teeth. 
Other related dental appliances are disclosed in Dellinger, U.S. Pat. No. 
4,396,373, issued Aug. 2, 1983, Smiley et al., U.S. Pat. No. 4,484,895, 
issued Nov. 27, 1984, and Lauks et al., U.S. Pat. No. 4,629,424, issued 
Dec. 16, 1986. None of these devices uses electronic stimuli to prevent 
bruxism. 
The present invention addresses the foregoing drawbacks and disadvantages 
of known dental appliances. 
SUMMARY OF THE INVENTION 
The present invention provides a dental appliance which, according to one 
aspect of the invention, has a mouthpiece, a source of electrical current 
affixed to the mouthpiece, and an electrode affixed to the mouthpiece. The 
electrode is disposed to contact an interior surface of the wearer's mouth 
when the mouthpiece is positioned therein. An electric circuit connects 
the source and the electrode so an electric current is selectively 
provided between the source and the electrode when the wearer's upper and 
lower teeth contact. The electric stimuli provided by the electrode causes 
the wearer to unclench his teeth.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
Referring generally to FIGS. 1 through 3, a dental appliance 10 according 
to the invention is comprised of a mouthpiece 12 and an associated 
electrical stimulus subassembly, designated generally as 13. The 
electrical stimulus subassembly is borne upon and affixed to the 
mouthpiece 12, and is comprised of a power source 14, electrodes 16 
disposed to contact an interior surface of the wearer's mouth when dental 
appliance 10 is positioned in the wearer's mouth, and an electric circuit 
18 connected between power source 14 and electrodes 16. 
Mouthpiece 12 can be one of a variety of types which are well known in the 
art. Typically, a full palate dental retainer, which may be of the Hawley 
type, or a similar splint type, or a self-contained lower jaw splint type 
retainer, may be used. Mouthpiece 12 is preferably made of a plastic 
substrate which is molded from a dental model of the patient's teeth. 
In a preferred embodiment, mouthpiece 12 has a generally horseshoe shape 
and comprises a curved front portion 20, a left leg 22 and a right leg 24. 
Left leg 22 and right leg 24 are integral with curved front portion 20 and 
would generally follow the contours of the wearer's upper or lower teeth. 
Mouthpiece 12 is configured to fit over the wearer's teeth and thus 
further includes a base 26 generally disposed to abut the chewing surface 
of the teeth. Extending from base 26 and disposed behind and in front of 
the wearer's teeth are an inner wall 28 and an outer wall 30, 
respectively. As shown in FIG. 3, base 26, inner wall 28, and outer wall 
30 also form a U-shape when taken in cross-section. 
Power source 14 includes battery cells 32 which are embedded in outer wall 
30 of mouthpiece 12. In a preferred embodiment, power source 14 has four 
lithium button cells which are connected in series. Each battery cell 32 
is preferably a dry cell rated at approximately 3 V. When dental appliance 
10 is being used, the battery life is 150 hours or more, while the shelf 
life of the batteries, under zero current flow conditions, can be several 
years. 
Electrodes 16 are preferably metal or plastic conductors embedded in outer 
wall 30 of both left leg 22 and right leg 24. Electrodes 16 are embedded 
in mouthpiece 12 to contact an interior surface of the wearer's mouth when 
mouthpiece 12 is properly inserted. In a preferred embodiment, electrodes 
16 contact the wearer's gum line, i.e., the tissue that surrounds the 
necks of teeth and covers the alveolar parts of the jaws. Electrodes 16 
are preferably arranged in a linear array along outer wall 30 of legs 22 
and 24 to contact the gum line in a plurality of locations. 
Electronic circuit 18 is connected between power source 14 and electrodes 
16 and selectively conducts electricity between the power source and the 
electrodes when the individual wearing the dental appliance brings his 
upper and lower jaws together into a closed position. Electronic circuit 
18 is preferably powered by battery cells 32 and generally comprises an 
ON/OFF switch 34, a sensor 36, and at least one flexible printed circuit 
board 38. Circuit 18 also includes an oscillator 40 connected to sensor 36 
through an inhibit circuit 42 all mounted on circuit board 38. In the most 
preferred embodiment, circuit board 38 is wrapped over the exterior 
surface of outer wall 30 on both left leg 22 and right leg 24, cemented in 
place and sealed with a plastic film 47. In certain applications, a 
portion of the circuit board may be obviated by spot welding connections 
directly to the cells and wiring them to a smaller circuit board mounted 
on either leg, shown for example on left leg 22 in FIG. 2. 
Generally, ON/OFF switch 34 energizes circuit 18 when it is closed or 
turned on. ON/OFF switch 34 is preferably a dynamic switch such as a field 
effect transistor (FET) connected to contacts 48 which have exposed ends 
extending through outer wall 30. The FET is biased to a nonconducting 
state until a conductive fluid, such as saliva, creates a conductive path 
between contacts 48 and turns it on. When dental appliance 10 is removed 
from the wearer's mouth and dried, the conductive path between contacts 48 
is broken thus returning switch 34 to its normally open or off position. 
When switch 34 is closed, current from power source 14 energizes 
electronic circuit 18. The current flows from power source 14 and 
effectively short-circuits through sensor 36, at least until pressure is 
exerted against sensor 36. Once adequate pressure is exerted, oscillator 
40 provides controlled electrical pulses or stimuli to electrodes 16. 
However, if switch 34 is in the open or off position, no current is 
allowed to flow from electric power source 14. 
Sensor 36 preferably functions as a dynamic switch and comprises a small 
diameter flexible tube 50 filled with a dilute saline solution 51. One or 
more tubes may be used. Tube or tubes 50 are made from a resilient, 
nonporous flexible rubber or plastic which is deformable under normal 
external pressure. Tube 50 can have different volumes or different levels 
of stiffness to alter its sensitivity to bruxing force. In a preferred 
embodiment, tube 50 extends across base 26 and has its inner end 52 and 
its outer end 54 embedded in inner wall 28 and outer wall 30, 
respectively. Tube 50 is thus disposed axially across leg 22 or 24 or both 
so that flexible tube 50 is squeezed together and collapses as the wearer 
bites down. When sufficient bruxing pressure is applied to tube 50, it is 
deformed to an extent that interrupts the continuous conductive fluid path 
extending through tube 50. Current can then no longer flow through saline 
solution 51 of sensor 36. Under these conditions, electronic circuit 18 is 
no longer short-circuited through tube 50. This allows battery cells 32 to 
power oscillator 40 which feeds pulses of energy via an isolation 
capacitor 54 to the electrodes 16 disposed in the wearer's mouth (see FIG. 
4). This electrical stimulation is detected by the trigeminal which 
supplies the face and upper and lower jaw with sensory nerves along the 
facial and the vagus. The ophthalmic and the maxillary divisions of the 
trigeminal are purely sensory, and the mandibular division contains motor 
fibers to the muscles of mastication as well. 
The bruxing pressure on tube 50 opens electrical circuit 18 to allow a 
small electric shock to be felt at the gum line stimulating the 
proprioception of the trigeminal efferent branch to cause the release of 
tension or contraction of the masticator muscles via the efferent branch 
of the trigeminal by reflex reaction. This relaxes the jaw musculature 
much like that experienced when one bites down a hard kernel of popcorn, 
causing a reflex reaction. In some applications, a reasonable shock level 
may be provided by 6 to 9 volts. 
Bruxing forces could be sufficient to damage tubes 50 in certain 
situations. Therefore, in the preferred embodiment, the resilient tubes 50 
will be fitted into the base of the appliance so they are only partially 
exposed to the bruxing forces. For instance, the round tube 50 could be 
positioned in a semi-circular trough so the bruxing force would be 
sufficient to interrupt the circuit without shearing or damaging the tube. 
An exemplary embodiment of electronic circuit 18 will now be described in 
detail. Referring to FIG. 5, contacts 48 include a first contact 60, which 
is coupled to the anode of power source 14, and a second contact 62, which 
is coupled to switch 34. Switch 34 generally includes a transistor 53, and 
a resistor 55. The gate of transistor 53 is directly coupled to contact 62 
and coupled to ground through resistor 55. The drain of transistor 53 is 
coupled to ground, and the source of transistor 53 is coupled to sensor 
36, a capacitor 74, and a timing circuit 88. 
When contact 60 is not electrically coupled to contact 62, switch 34 is 
OFF. In this configuration, an open circuit exists between the anode of 
power source 14 and the gate of transistor 53. Since no potential is 
applied to the gate of transistor 53, the source and drain of transistor 
53 remain electrically isolated. 
Switch 34 is ON when contact 60 is electrically coupled to contact 62 by 
conducting fluid, such as saliva or other moisture in a wearer's mouth. In 
this configuration, a circuit is completed between the anode of power 
source 14 and the gate of transistor 53, thus applying a potential at the 
gate of transistor 53 which allows current to flow from the source of 
transistor 53 to the drain of transistor 53. 
Oscillator 40 generally includes timing circuit 88, a plurality of 
resistors 64, 66, and 72, a capacitor 68, and capacitor 74. Timing circuit 
88, which may suitably includes a 7555 timing chip, has a plurality of 
terminals, 76, 78, 80, 82, 84 and 86. Terminal 80 is the discharge 
terminal of timing circuit 88 and is coupled to the anode of power source 
14 through resistors 64 and 66, and to capacitor 74 through resistor 66. 
Terminal 78 is the trigger terminal of timing circuit 88 and terminal 76 
is the threshold terminal of timing circuit 88. Terminals 76 and 78 are 
coupled to the anode of power source 14 through resistor 64 and to 
capacitor 74. Terminal 82 is coupled to the anode of power source 14 and 
terminal 86 of timing circuit 88 is coupled to ground through switch 34. 
Terminal 84 is the output terminal of timing circuit 88 and is coupled to 
the anode of power source 14 through capacitor 68 and resistor 72 and to 
capacitor 68. Capacitor 68 is coupled to electrodes 16 by a contact 70 and 
to the anode of power source 14 through resistor 72. 
When switch 34 is ON and sensor 36 is rendered nonconductive by pressure 
being exerted thereon, as discussed above, oscillator 40 is activated. In 
this configuration, the voltage at threshold terminal 76 is initially low, 
driving output terminal 84 high. Also, the voltage across capacitor 74, 
initially zero volts, increases as capacitor 74, no longer short-circuited 
by sensor switch 36, charges through resistor 64. The rate at which 
capacitor 74 is charged depends on the capacitance of capacitor 74 and the 
resistance of resistor 64. The voltage at terminal 84 remains high until 
the voltage at threshold terminal 74 reaches 2/3 the input voltage at 
terminal 82 (Vcc). 
When the voltage at threshold terminal 76 reaches 2/3 Vcc, the voltage at 
output terminal 84 is driven low. Also, discharge terminal 80 is tied to 
ground, causing capacitor 74 to discharge through resistor 66. The rate of 
discharge is determined by the capacitance of capacitor 74 and the 
resistance of resistor 66. The voltage at output terminal 84 remains low 
and capacitor 74 continues to discharge until the voltage at trigger 
terminal 78 reaches 1/3 Vcc. 
When the voltage at trigger terminal 78 falls below 1/3 Vcc, the output at 
terminal 84 is driven high. Also, the circuit between discharge terminal 
80 and ground is broken, causing capacitor 74 to recharge once again 
through resistor 64. Thus, when switch 34 is ON, and sensor switch 36 is 
nonconductive, the voltage at output terminal 84 will oscillate between 
high and low and the voltage across capacitor 74 will oscillate between 
1/3 Vcc and 2/3 Vcc. 
As described above, the voltage at output terminal 84 continuously 
oscillates between high and low. Initially, the voltage at output terminal 
84, contact 70, and contact 62 is high, making the potential across 
capacitor 68 zero. When oscillator 40 is activated and output terminal 84 
goes low, the voltage at contact 70 also goes low as the potential across 
a capacitor does not change instantaneously. Capacitor 68 begins to charge 
as current starts to flow from the high potential at contact 62 to the low 
potential at contact 70 through resistor 72 and the conductive moisture in 
the wearer's mouth. The rate at which capacitor 68 is charged depends upon 
the resistance of both resistor 72 and the capacitance of capacitor 68. As 
output terminal 84 goes high, the voltage at contact 70 is driven above 
Vcc to maintain the instantaneous potential across capacitor 68. The 
resulting current flow from contact 70 to contact 62 through resistor 72 
and the moisture in the wearer's mouth discharges capacitor 68. This 
process is continuously repeated as output terminal 84 oscillates between 
high and low while timing circuit 88 is activated. 
Sensor 36 connects one side of capacitor 74 to the other. As discussed 
above, when bruxing pressure is exerted against sensor 36, sensor 36 does 
not conduct, and when pressure is not exerted against sensor 36, sensor 36 
does conduct. Thus, when pressure is not exerted against sensor 36, 
capacitor 74 is short circuited and cannot charge, inhibiting circuit 18 
from operation and allowing no potential across capacitor 74. Since 
capacitor 74 cannot charge, the voltage at terminals 76 and 78 remain 
constant and timing circuit 88 remains inactive. In this configuration, 
oscillator 40 is inhibited and output terminal 84 will remain high. 
It will be understood that the foregoing description is of a preferred 
exemplary embodiment of this invention, and that the invention is not 
limited to the specific forms shown. For example, different configurations 
and materials may be used for mouthpiece 12, electronic circuit 18 may use 
different components than those listed and different numbers of tubes 50 
can be used in sensor 36. These and other modifications may be made in the 
design and arrangement of the elements without departing from the scope of 
the invention as expressed in the amended claims.