DE19904260A1 - Glasses for use by patient suffering from sleep apnea have sensors to detect symptoms of sleep disturbance, logic controlling elements and light element that can be triggered to wake patient up - Google Patents

Abstract

Device comprises a glasses frame (1) with integrated light elements (3) and a support plate (16) with connections for sensors (4, 11, 14) that detect micro-electronically the symptoms of sleep disturbance caused by obstructive sleep apnea and deliver these to a processor where they are analyzed and if necessary a trigger signal sent to a waking light element (3).

Description

The invention relates to glasses consisting of devices for Monitoring and lighting elements to wake people up with Sleep disorders. With the glasses according to the invention, in particular Individuals are awakened from sleep under an obstructive and / or suffer from central sleep apnea.

[State of the art]

Sleep disorders are often associated with snoring, the physical or can have neuropathological causes. The snoring noises are in the Mouth, nose and throat through the air flow during inspiration and of expiration. The most striking sounds when snoring arise from the action of wind power on the front and posterior palate. Medically there is an obstructive sleep apnea.

The physiopathological causes of snoring - obstructive sleep apnea - are diverse: What is important, however, is that people who usually snore heavily often also suffer from central sleep apnea (reduced breathing drive, substantial CNS defect), which has low oxygen saturation (SaO ₂ ) has the consequence. This reduced ventilation also leads to an insufficiently deep sleep. The result is reduced daily activity. In order to avert the risk of hypoxia (insufficient O ₂ saturation in the blood), these people must be woken up from sleep in good time.

Known methods to wake a snoring person include:

• - Awaken by a second person
• - Wake up with a timer with a preset alarm time and acoustic alarm device (clock alarm).

A device is also known with which the snoring noises of a microphone placed near the snoring person be recorded and after appropriate electromagnetic Converting an acoustic alarm signal is generated.

All of these methods have the disadvantage that an additional person can act must or this is disturbed by the waking process even in his sleep.

OBJECT OF THE INVENTION

The invention is therefore based on the object of a device for waking to create, regardless of the influence and influence of a another person and externally connected devices and one optimal wake-up time with alarm activation.

This problem is solved by a device with the features of Claim 1. Advantageous embodiments of the invention are in the Subclaims specified.

[Examples]

In the following, the invention is explained on the basis of exemplary embodiments. Show it:

Fig. 1 shows an inventive apparatus with light element and microphone,

Fig. 2 electronic circuit of the inventive apparatus with light element and microphone,

Fig. 3 shows a variant of the electronic circuit of the inventive apparatus with light element, microphone and thermal sensor,

Fig. 4 shows a further variant of the electronic circuit of the inventive device with a microphone, lighting element and O ₂ sensor,

Fig. 5 shows a further variant of the electronic circuit of the device according to the invention with microphone, light element, O ₂ sensor and thermal sensor.

The apparatus according to Fig. 1 consists of a spectacle frame (1) which is adapted to the anatomical conditions of the carrier. The glasses normally present in glasses are replaced by an opaque plate ( 2 ), in the center of which the light elements ( 3 ) with a light opening are mounted in the direction of the eyes. In Fig. 1a, the view is shown with the plate mounted. Each light element ( 3 ) consists of at least one LED or other electro-optical light elements (e.g. electroluminescence). Two power sources ( 7 ) are fitted into the side of the glasses frame. Fig. 1b shows the back of the carrier plate ( 16 ) for recording and circuitry linking the microphone ( 4 ), analyzer ( 5 ), amplifier ( 6 ) and switching circuit ( 10 ). The carrier plate ( 16 ) is connected mechanically and in terms of circuitry via plug contacts to the plate ( 2 ) and the spectacle frame ( 1 ).

The luminosity of the light elements ( 3 ) must be so great that the sleeping person is awakened by the luminous flux or light effects falling into the eye.

The microphone ( 4 ) can be designed in two versions. The microphone ( 4 ) is a version for the airborne snoring noises or a version for sound waves of the snoring noises conducted over the bones.

The analyzer ( 5 ) is an electronic module for analyzing and discriminating the snoring noises recorded with the microphone ( 4 ). An adapter connection ( 17 ) is connected to the analyzer in order to be able to carry out external polygraphic registration and analysis. The voltage source ( 7 ) supplies the electronic components with the necessary voltage.

., The apparatus according to Figures 1 and 2 operates as follows:
The snoring noises are picked up by the microphone ( 4 ) and sent to the analyzer ( 5 ) for analysis.

The electrical signals are processed in the analyzer ( 5 ) as follows:
The electrical signals coming from the microphone ( 4 ) are amplified in an amplifier ( 6 ) and further processed in the following, manually adjustable amplitude integral discriminator stage with pulse shaper stage ( 8 ). In the integral discriminator, those impulses that fall below the set threshold value are separated out. The discriminator can be technically implemented by a trigger circuit (trigger circuit), such as Schmitt, tunnel diode, and blocking oscillator triggers with their own pulse shaping stages. The downstream pulse shaper generates standardized output pulses with constant amplitude and duration. For the counting and intermediate storage of the relevant pulses generated by the snoring noises, the pulses supplied by the downstream pulse shaper are fed to a pulse rate counter ( 9 ).

The following event is used to decide whether a light signal should be triggered:
A: There are more than x significant snores per minute.

The light element ( 3 ) is started in the switch circuit ( 10 ). The light signal can be switched off manually using a reset button and the device can be restarted.

The device according to Fig. 1 and Fig. 3 consists of the glasses frame ( 1 ) with the power sources ( 7 ), the plate ( 2 ) with the light elements ( 3 ) and the support plate ( 16 ) with the microphone ( 4 ), the analyzer ( 5 ), the amplifier ( 6 ) and the switching circuit ( 10 ). In addition, a thermal sensor ( 11 ) (e.g. thermistor) is connected via a signal line and clamped to the nasal septum.

The analyzer ( 5 ) is an electronic module for analyzing and discriminating the snoring noises recorded with the microphone ( 4 ) and the temperature changes registered by the thermal sensor ( 11 ).

The voltage source ( 7 ) supplies the electronic components with the necessary voltage.

. The inventive device according to Figures 1 and 3 works as follows.:
The snoring noises are picked up by the microphone ( 4 ) and sent to the analyzer ( 5 ) for analysis.

The same occurs with the temperature changes registered by the thermal sensor ( 11 ) as a result of expiration and inspiration. These temperature changes correspond to the respiratory rate.

The electrical signals are processed in the analyzer ( 5 ) as follows:
The signals coming from the microphone ( 3 ) are processed according to FIG. 3 via the amplifier ( 6 ), the amplitude integral discriminator stage with pulse shaper stage ( 8 ) and the pulse rate counter ( 9 ). The pulses supplied by the pulse shaper ( 8 ) are additionally fed to a coincidence circuit ( 12 ).

The temperature changes in the nasal septum associated with inspiration and expiration generate a changing current at the thermal sensor ( 11 ), which corresponds to the respiratory rate. This current is amplified in an amplifier ( 6 ) and also fed to an amplitude integral discriminator with pulse shaper ( 8 ) and the coincidence circuit ( 12 ) as described above.

The standardized output signals of the two pulse shapers are fed synchronously to the two pulse rate counters ( 9 ) and the coincidence circuit ( 12 ) (e.g. diode bridge) for further processing.

The coincidences between the impulses of the acoustic and thermal signals are determined in the coincidence circuit ( 12 ).

The logic ( 13 ) is used to decide whether a light signal should be triggered. The following events are used for this:
A: There are more than x snoring noises per minute
B: There are fewer than y breaths per minute
C: There are less than z% coincidences.

With a suitable Boolean or fuzzy function E (A, B, C) Events A, B and C give you the decision E to trigger the Light signal to wake you up.

The light element ( 3 ) is started in the switch circuit ( 10 ). The light signal is switched off manually by a reset button and the device is restarted.

The apparatus according to Fig. 1 and Fig. 4 corresponds in structure to in Fig. 1 and Fig. 3 illustrated. The main difference is the use of a sensor ( 14 ) for the oxygen saturation SaO ₂ on the nasal septum or on the ear instead of the thermal sensor ( 11 ). This oxygen sensor ( 14 ) is connected to the analyzer ( 5 ) via a signal line.

., The apparatus according to Figures 1 and 4 functions as follows:
The snoring noises are picked up by the microphone ( 4 ) and sent to the analyzer ( 5 ) for analysis.

The same applies to the O ₂ values registered by the O ₂ sensor ( 14 ) as a result of expiration and inspiration.

The electrical signals are processed in the analyzer ( 5 ) as follows:
The signals coming from the microphone ( 4 ) are processed according to FIG. 4 via the amplifier ( 6 ), the amplitude integral discriminator stage with pulse shaper stage ( 8 ) and the pulse rate counter ( 9 ).

The change in O ₂ saturation associated with inspiration and expiration at the nasal septum or ear produces a changing current at the O ₂ sensor ( 14 ) which corresponds to this O ₂ saturation. This current is amplified in an amplifier ( 6 ) and fed to a differential discriminator with pulse shaping stage ( 15 ).

The logic ( 13 ) is used to decide whether a light signal should be triggered. The following events are used for this:
A: There are more than x snoring noises per minute
B: There is an O ₂ saturation of less than y%.

By a suitable boolean or fuzzy function E (A, B) of the events A and B you get the decision E for triggering the light signal to wake you up.  

The light element ( 3 ) is started in the switch circuit ( 10 ). The light signal is switched off manually by a reset button and the device is restarted.

The apparatus according to Fig. 1 and Fig. 5 is similar in construction shown in Fig. 1 and Fig. 3 illustrated. The main difference is the additional use of a sensor ( 14 ) for the oxygen saturation SaO ₂ on the nasal septum or ear.

The inventive device according to FIG. 1 and FIG. 5 works as described for Fig. 1, Fig. 3 and Fig. 4 described below.

The logic ( 13 ) is used to decide whether a light signal should be triggered. The following events are used for this:
A: There are more than x snoring noises per minute
B: There is an O ₂ saturation of less than y%
C: There are fewer than z breaths per minute
D: There are less than m% coincidences.

With a suitable Boolean or fuzzy function E (A, B, C, D) Events A, B, C and D give decision E for triggering of the light signal to wake you up.

The light element ( 3 ) is started in the switch circuit ( 10 ). The light signal is switched off manually by a reset button and the device is restarted.

Reference list

1

Glasses frame

2nd

plate

3rd

Light elements

4th

microphone

5

Analyzer

6

amplifier

7

Voltage source

8th

Amplitude integral discriminator with pulse shaper stage

9

Pulse rate counter

10th

Switch circuit

11

Thermal sensor

12th

Coincidence circle

13

logic

14

O ₂

-Sensor

15

Amplitude differential discriminator with pulse shaper stage

16

Carrier plate for the electronics

17th

Adapter connection for signal transmission to external recording devices and analysis devices

Claims (5)

1. A device for waking people suffering from sleep disorders due to sleep apnea, consisting of

• a) an eyeglass frame ( 1 ) with integrated light elements ( 3 ), a support plate ( 16 ) with connections for the sensors ( 4 ), ( 11 ), ( 14 ), the symptoms of obstructive sleep apnea and / or central symptoms caused by the sleep disorder Detect sleep apnea microelectronically and an analyzer ( 5 ), which processes the sensor signals electronically and logically and triggers light signals through the light elements ( 3 ) for waking.

2. Device according to claim 1, consisting of

• a) an anatomically adapted spectacle frame ( 1 ) for receiving the two voltage sources ( 7 ), as well as two interchangeable plates ( 2 ) in which light elements ( 3 ) are located,
• b) an exchangeable carrier plate ( 16 ), which is mounted on the plates ( 2 ) and the glasses frame ( 1 ), for circuitry linking and recording the microphone ( 4 ), the analyzer ( 5 ), the amplifier ( 6 ) and the switching circuit ( 10 ) and the sensor connections.

3. Apparatus according to claim 1 and 2, characterized in that

• a) the plates ( 2 ) are interchangeable and thus prefabricated light elements ( 3 ) according to physiological requirements and / or personal ideas can be used with corresponding light effects (e.g. flashing, bezels with star pattern etc.) or luminosity,
• b) the carrier plate ( 16 ) with its electronic components is interchangeable and thus different prefabricated analyzer circuits for the various sensors - O ₂ sensor ( 14 ) for O ₂ saturation, a thermal sensor ( 11 ) for the nasal and oral air flow and an acoustic sensor ( 4 ) for snoring noises - can be used individually or in combination,
• c) the eyeglass frame ( 1 ) is interchangeable and thus in accordance with fashionable or anatomical wishes, respectively. Requirements can be shaped and prefabricated.

4. Apparatus according to claim 1 to 3, characterized in that

• a) the respiratory rate is monitored by connecting a thermal sensor ( 14 ) for nasal and oral air flow to the analyzer ( 5 ),
• b) the oxygen saturation SaO _{2 is} monitored by connecting an O ₂ sensor ( 11 ) attached to the nasal septum or ear to the analyzer ( 5 ),
• c) the breathing frequency and / or the oxygen saturation are linked to the snoring noises in the analyzer ( 5 ) via a boolean or fuzzy logic function and the light signals are triggered when a significant value is exceeded.

5. Apparatus according to claim 1 to 4, characterized in that

• a) via an adapter connection ( 17 ) to the analyzer ( 5 ) an external polygraphic registration and analysis z. B. is feasible in the sleep laboratory.