Device to combat dribbling

A device for teaching a patient to keep his lips closed, to combat dribbling, has a sensor electrode (12,22,46) for insertion between the lips, and an electrical detector (G1) and indicator (30) to indicate cessation of contact with at least one lip. The patient is thus reminded to keep his lips closed. In one form, there is a secondary electrode (26) attached to a remote part of the patient's body, the detector detecting when an electrical circuit through the body is broken by the sensor electrode falling from the lips. In another form, the sensor electrode (46) is upwardly hooked (50) to contact the upper lip, and the detector detects absence of electrical contact between sensor electrode and a frame (32) hooked behind the lower lip.

BACKGROUND TO THE INVENTION 
This invention relates to devices for teaching a patient to keep his lips 
closed. Such devices are particularly useful to combat a tendency to 
dribble, for example in patients suffering from certain forms of 
dysarthria, especially those associated with spasticity; in patients who 
persistently breathe through their mouths; and in patients who have 
suffered strokes. It is often possible for such a patient to swallow his 
saliva provided he can be taught to keep his lips closed. 
SUMMARY OF THE INVENTION 
The invention provides a device for teaching a patient to keep his lips 
closed, characterised in that it comprises an electrode adapted for 
insertion between the patients lips to make electrical contact with at 
least one of the lips when the lips are closed but not otherwise, 
electrical detector means arranged to detect when the electrode ceases to 
make contact with said lip, and an indicator operable by the detector 
means when such cessation of contact is detected. 
In one embodiment, the electrode includes a sheet portion for insertion 
between the lips, the free end of which may be curved out of the plane of 
the sheet. The electrode preferably has a backing portion generally 
perpendicular to the sheet to limit the extent to which the electrode can 
be inserted between the lips. 
The detector means may operate by detecting a change in capacitance and/or 
resistance between the sensor electrode and a second electrode provided 
for contacting with another part of the patient's body, on release of the 
sensor electrode from the patient's lips. The indicator means preferably 
provides an audible warning on release of the sensor electrode from the 
patient's lips. 
In an alternative form, a frame is provided around the electrode, 
electrical connection being made between the frame and the electrode when 
both are inserted between the closed lips of the patient, such connection 
being broken and detected by the detector means when the patient opens his 
lips. The frame may have a depending formation to hook behind the lower 
lip, the electrode being arranged to contact the upper lip when closed.

DESCRIPTION OF PREFERRED EMBODIMENTS 
FIGS. 1 and 2 shows a sensor electrode particularly intended for use with 
spastic patients. It comprises a backing portion in the form of a disc 10, 
of about 30 mm diameter, although the diameter is not very critical. 
Extending generally perpendicularly from a mid-portion of the backing disc 
10 is a sheet portion in the form of a tongue 12, having a free end 
portion 14 which is curved downwardly out of the plane of the rest of the 
tongue. The length 1 of this tongue will vary quite considerably from 
patient to patient, depending on whether the patient is an adult or a 
child and on the thickness of his lips. A length is chosen for any given 
patient such that the tongue 12 can be inserted between the patient's lips 
and gripped thereby, the backing disc 10 preventing further insertion, and 
the tongue 12 being sufficiently short that the patient cannot grip the 
tongue between his teeth. The curved end 14 of the tongue assists the 
patient in gripping the electrode, because it conforms to a limited extent 
with the surface of its lower lip inside his mouth. 
The backing disc 10 has a tail 16 formed from the same sheet but bent 
slightly backwardly as seen in FIG. 2. To this tail is soldered a lead 
wire 18. Insulation 20 is provided around this soldered joint and around 
the tail 16. 
FIGS. 3 and 4 show an alternative sensor electrode, which is intended for 
more general use than the electrode shown in FIGS. 1 and 2, for example 
with patients who persistently breathe through their mouths, and/or 
patients who have suffered strokes. This electrode has no back disc 10, 
and can therefore be manufactured from a single sheet of stainless steel. 
It comprises an elongate, generally oval sheet portion 22, wider than its 
length in the direction of insertion between the lips, typically about 30 
mm wide by 10 mm. However, it will be appreciated than the only 
restriction on the length dimension is that it should be possible for the 
patient to fit the electrode between his lips comfortably, while in the 
case of the width dimension the criterion is that the sheet portion 22 
shall be sufficiently wide to enable the patient to grip the electrode 
between his lips, while not being sufficiently wide as to allow the 
patient easily to grip the electrode between his teeth. One longer edge of 
the sheet portion 22 has a depending tail 24 to which is soldered a lead 
18, and which is provided with insulation 20 in the same manner as the 
electrode of FIGS. 1 and 2. The depending tail 24 provides a backing 
portion to assist in preventing the patient from inserting the sheet 
portion between his teeth, in a somewhat similar manner to the backing 
disc 10. 
The electrodes shown in FIGS. 1 to 4 are fabricated from sheet stainless 
steel, which is a material which is easy to clean, hygenic and acceptable 
to the patient. The shape and weight of the sensor electrodes are such 
that they are not retainable between the lips by any means other than a 
small but conscious effort to hold them there. It is also unlikely to be 
possible to accidentally knock the electrode in between the lips so as to 
damage the teeth or mouth of the patient. 
As an alternative material to stainless steel, the electrodes described 
could be moulded from a synthetic plastics material. A particularly 
preferred material is acrylic plastics, such as that used in the 
manufacture of dentures. In this case, when it is moulded the electrode 
will have a wire embedded in the surface of the tongue 12 or sheet portion 
22, to provide a conducting portion of the electrode. So that the 
electrode has a smooth finished surface (which is necessary in order not 
to aggravate the patient), the electrode is initially moulded with the 
wire slightly below the surface of the tongue or sheet portion, and is 
subsequently exposed by filing or other abrasive removal of material. The 
wire extends through the tail 16 or 24, and no separate lead wire 18 is 
needed. 
The above electrodes are used in conjunction with a secondary electrode 26 
(FIG. 7), which is simply a flat disc of, for example, stainless steel 
which in use is placed in contact with some portion of the patient's body. 
Suitably the electrode 26 is slipped inside the patient's waistband, in 
contact with his skin. The circuitry of FIG. 7 (described later) detects 
when a circuit between the sensor electrode and the secondary electrode 26 
through the patient's body is broken and provides an indication. 
FIGS. 5 and 6 shows a preferred sensor electrode device, which does not 
require a secondary electrode 26. It comprises an outer frame 32 bent from 
stainless steel wire. The ends 36,38 of the wire of this frame are moulded 
within a body portion 34 made from acrylic plastics material. The end 36 
is merely held in the plastics material, but the end 38 is connected 
within an insulating sleeve 42 to one wire of a connecting flex 40. The 
outer frame 36 has a depending W-shaped formation 44, which hooks behind 
the patient's lower lip and can be bent to give a good fit. We have found 
that the W formation enhances this fit. 
Between the ends 36,38, a sensor electrode 46 is moulded in the body. This 
electrode is a stainless steel wire with a covering insulating sleeve 48. 
The sensor electrode 46 is generally in the plane of the frame 32, except 
that where the frame has the W formation 44, it terminates in an upturned 
hook 50, which projects slightly above and beyond the frame. The sleeve 48 
insulates the entire electrode 46 except that at the very tip of the hook 
50 the sleeve terminates flush with the wire of the electrode, leaving the 
end bare. The sensor electrode 46 is connected within the sleeve 42 to a 
second wire of the flex 40. 
In use, with the W formation hooked behind the patient's lower lip, the 
bare tip of the hook 50 will contact the patient's upper lip as long as 
his mouth is closed, giving a circuit passing through his body from the 
sensor electrode 46 to the frame 32. This circuit is broken if the patient 
opens his mouth, the hook 50 no longer contacting the upper lip. The 
electrode device may fall from the patient's mouth, but this is not 
essential. 
FIG. 7 shows a circuit diagram of electronic equipment, together with the 
secondary electrode 26, which can be ued in conjunction with the 
electrodes of FIGS. 1 to 4 to detect when a patient has opened his mouth 
and the sensor electrode has fallen from between his lips. The sensor 
electrode is designated 28 in FIG. 7. The circuit is arranged to detect 
changes in capacitance and resistance between the electrodes 26,28 if the 
electrode 28 falls from between the patient's lips. If this occurs, an 
indicator in the form of a buzzer 30 is actuated. Visible indicators could 
be used, but an audible indicator is preferable since it serves as an 
instant reminder to the patient that he must close his mouth (replacing 
the sensor electrode 28) and thus the patient is taught to keep his mouth 
closed, and is prevented from dribbling. 
The secondary electrode 26 is connected to earth, while the sensor 
electrode 28 is connected to an input of an inverter gate G1, providing 
detector means. The input to the gate G1 is biased by a resistor network 
comprising resistors R1, R2, R3 and a potentiometer VR1. R1, VR1 and R2 
have resistances of about 500K.OMEGA., while R3 has a resistance of 
20M.OMEGA., and this means that the current to the input of the gate G1 
and passing through the electrode 28 is very small and not noticeable by 
the patient. Potentiometer VR1 is adjusted such that when the electrode 28 
is in the patient's mouth the voltage at the input of gate G1 is just 
below that necessary to trigger the gate. Consequently the output of gate 
G1 is at a high level. If the patient drops the electrode 28, the 
resulting change in capacitance and resistance between the input of gate 
G1 and earth triggers the gate so that its output falls to a low level. 
This is communicated to an input of a second similar gate G2, which acts 
as an inverter and buffer. The output of gate G2 then goes to a high level 
and turns on a driver transistor TR1 to operate the buzzer 30. When the 
electrode 28 is replaced between the patient's lips, the buzzer 30 will 
cease to operate. 
When the circuit of FIG. 7 is to be used with the electrode device of FIGS. 
5 and 6, the frame 32 is connected in place of the secondary electrode 26, 
and the sensor electrode 46 is connected in place of the sensor electrode 
28, through the flex 40. 
The gates G1 and G2 are provided by 1/6 each of a C-MOS integrated circuit 
type 4049, giving the desired high input impedance. The transistor TR1 is 
suitably of type 2N1316. However, it will be appreciated that other 
designs for the detector and indicator circuitry could be used.