This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2022-034701 filed on Mar. 7, 2022, the contents of which are incorporated herein by reference.
The present disclosure relates to a sensor attachment system, a respiratory gas sensor, and a compatible airway adaptor.
Japanese Patent Application Laid-Open Publication No. 2019-174152 discloses a sensor attachment system including an airway adaptor connectable to a tracheal tube of a respirator and a respiratory gas sensor attachable to the airway adaptor. By attaching the respiratory gas sensor to the airway adaptor, a state of exhaled gas of a patient (for example, concentration or partial pressure of carbon dioxide) can be detected. To improve the measurement accuracy of information measured by the respiratory gas sensor, the respiratory gas sensor is attached to the airway adaptor in a state in which the respiratory gas sensor and the airway adaptor are positioned.
In general, the respiratory gas sensor is repeatedly used, while the airway adaptor is disposable. Various types of airway adaptors are prepared according to applications, such as non-intubation airway adaptors and intubation airway adaptors. Here, an intubation airway adaptor is an airway adaptor used for invasive positive pressure ventilation in which a tracheal tube is inserted into a trachea of a patient. On the other hand, a non-intubation airway adaptor is an airway adaptor used for non-invasive positive pressure ventilation in which no tracheal tube is inserted into a trachea of a patient. In general, the respiratory gas sensor is attachable to all types of airway adapters.
When the respiratory gas sensor is compatible with both invasive positive pressure ventilation and non-invasive positive pressure ventilation, it is preferable that the respiratory gas sensor is attachable to all types of airway adapters (in particular, intubation airway adapters and non-intubation airway adapters). On the other hand, when the respiratory gas sensor is applicable only to invasive positive pressure ventilation, it may not be preferable that the respiratory gas sensor is attachable to a non-intubation airway adaptor. For example, to improve the measurement accuracy of a CO2 concentration in respiratory gas (exhaled gas) of a patient, calibration of the CO2 concentration of the respiratory gas sensor is generally performed before using the respiratory gas sensor. A calibration method for the CO2 concentration may be different between invasive positive pressure ventilation and non-invasive positive pressure ventilation. When the respiratory gas sensor to which the calibration method for invasive positive pressure ventilation is applied is attached to a non-intubation airway adaptor, the respiratory gas sensor may not be able to detect the CO2 concentration of the patient with high accuracy. As another example, a respiratory gas sensor for an adult may be assumed to be attached to an airway adaptor for a neonate. In this case, it is assumed that a tracheal tube connected to a neonatal airway adaptor is bent excessively due to the weight of the respiratory gas sensor for an adult. In this manner, there is room for consideration of a sensor attachment system in which a respiratory gas sensor is attachable or not attachable to an airway adaptor depending on a type of the airway adaptor.
A first aspect of the present disclosure relates to a sensor attachment system including: a sensor configured to detect a state of respiratory gas of a subject; and a compatible airway adaptor compatible with the sensor. The sensor includes a respiratory gas detector configured to detect the state of the respiratory gas of the subject, and a sensor-side engagement portion engageable with the compatible airway adaptor. The compatible airway adaptor includes a tube portion having a respiratory gas ventilation passage through which the respiratory gas passes, and an adapter-side engagement portion engageable with the sensor-side engagement portion. The sensor is attachable to the compatible airway adaptor in a state in which the compatible airway adaptor and the sensor do not interfere with each other, and the sensor is not attachable to an incompatible airway adaptor that is not compatible with the sensor in a state in which the incompatible airway adaptor and the sensor interfere with each other.
A second aspect of the present disclosure relates to a respiratory gas sensor. The respiratory gas sensor is configured to detect a state of respiratory gas of a subject and is attachable to a compatible airway adaptor compatible with the respiratory gas sensor. The respiratory gas sensor includes: a respiratory gas detector configured to detect the state of the respiratory gas of the subject; and a sensor-side engagement portion engageable with the compatible airway adaptor. The respiratory gas sensor is attachable to the compatible airway adaptor in a state in which the compatible airway adaptor and the respiratory gas sensor do not interfere with each other, and the respiratory gas sensor is not attachable to an incompatible airway adaptor that is not compatible with the respiratory gas sensor in a state in which the incompatible airway adaptor and the respiratory gas sensor interfere with each other.
A third aspect of the present disclosure relates to a compatible airway adaptor. The compatible airway adaptor is attachable to a respiratory gas sensor configured to detect a state of respiratory gas of a subject. The compatible airway adaptor includes: a tube portion having a respiratory gas ventilation passage through which the respiratory gas passes; and an adapter-side engagement portion configured to engage with the respiratory gas sensor. The respiratory gas sensor includes an attachment preventing portion configured to cause the respiratory gas sensor to be unattachable to an incompatible airway adaptor that is not compatible with the respiratory gas sensor, and the compatible airway adaptor further includes an accommodation portion configured to accommodate the attachment preventing portion to prevent interference with the attachment preventing portion.
Exemplary embodiment(s) of the present invention will be described in detail based on the following figures, wherein:
A sensor attachment system 1 according to an embodiment of the present disclosure (hereinafter, referred to as the present embodiment) will be described below with reference to the drawings. Dimensions of members illustrated in the drawings may be different from actual dimensions of the members for the sake of convenience of description. In the present embodiment, an X-axis direction, a Y-axis direction, and a Z-axis direction set for the sensor attachment system 1 illustrated in
The compatible airway adaptor 3 is an airway adaptor compatible with the respiratory gas sensor 2. That is, the respiratory gas sensor 2 is attachable to the compatible airway adaptor 3. More specifically, the respiratory gas sensor 2 is attachable to the compatible airway adaptor 3 in a state in which the compatible airway adaptor 3 and the respiratory gas sensor 2 do not interfere with each other.
Next, configurations of the respiratory gas sensor 2 will be specifically described with reference to
As illustrated in
As illustrated in
The fitting portion 23 is defined by side wall portions 23a and 23b facing each other in the Y-axis direction and a bottom portion 23c connected to a corresponding end of each of the side wall portions 23a and 23b. The side wall portion 23a is provided with a light emitting unit 42. The side wall portion 23b is provided with a light detecting unit 41. That is, the light emitting unit 42 and the light detecting unit 41 face each other through the fitting portion 23 in the Y-axis direction. As illustrated in
The light emitting unit 42 and the light detecting unit 41 function as a respiratory gas detector that detects the state of the respiratory gas of the patient. The light emitting unit 42 can include a first light emitter that emits first infrared light and a second light emitter that emits second infrared light having a wavelength different from that of the first infrared light. The light detecting unit 41 can include a first light detector that detects the first infrared light emitted from the first light emitter and a second light detector that detects the second infrared light emitted from the second light emitter. In the present embodiment, the respiratory gas detector is not limited to the light emitting unit and the light detecting unit.
The first infrared light is absorbed by carbon dioxide contained in the respiratory gas, whereas the second infrared light is not absorbed by carbon dioxide. In this manner, an intensity of the first infrared light detected by the first light detector changes according to a concentration of carbon dioxide contained in the respiratory gas. On the other hand, a detected light intensity of the second infrared light detected by the second light detector does not change according to the concentration of carbon dioxide. Therefore, the first infrared light is used as measurement light for measuring the concentration of carbon dioxide, while the second infrared light is used as reference light. A controller (not illustrated) provided in the respiratory gas sensor 2 can generate a vital signs signal indicating the state of the respiratory gas of the patient (concentration or partial pressure of carbon dioxide contained in respiratory gas) based on a ratio between an intensity of a first measurement signal output from the first light detector and an intensity of a second measurement signal output from the second light detector.
The controller may perform calibration processing of the carbon dioxide concentration before generating the vital signs signal indicating the state of the respiratory gas of the patient. By performing the calibration processing in advance, the measurement accuracy of the carbon dioxide concentration can be improved. A method for the calibration processing of the carbon dioxide concentration may be different depending on invasive positive-pressure ventilation or non-invasive positive-pressure ventilation.
Next, configurations of the compatible airway adaptor 3 will be specifically described with reference to
The tube portion 30 can include the respiratory gas ventilation passage 40 through which the respiratory gas exhaled from the patient passes. The tube portion 30 can include a first tube portion 32 having a first outer diameter and a second tube portion 33 having a second outer diameter greater than the first outer diameter. Both of the first tube portion 32 and the second tube portion 33 have a cylindrical shape, and the respiratory gas ventilation passage 40 is implemented by a hollow region of the first tube portion 32 and a hollow region of the second tube portion 33. The first tube portion 32 is connected to an external device such as a respirator or an airbag through a tube. The second tube portion 33 is connected to a device attached to the patient, such as a tracheal tube or a mask.
The sensor attachment portion 31 determines a position of the respiratory gas sensor 2 relative to the compatible airway adaptor 3. When the respiratory gas sensor 2 is attached to the compatible airway adaptor 3, the sensor attachment portion 31 is fitted to the fitting portion 23 of the respiratory gas sensor 2. The sensor attachment portion 31 is disposed between the first tube portion 32 and the second tube portion 33 in the X-axis direction, which is a longitudinal direction of the compatible airway adaptor 3. The sensor attachment portion 31 has a hollow region. The hollow region of the sensor attachment portion 31 communicates with the hollow region of the first tube portion 32 and the hollow region of the second tube portion 33. In this manner, the respiratory gas of the patient passes through the hollow region of the second tube portion 33, and then passes through the hollow region of the sensor attachment portion 31 and the hollow region of the first tube portion 32.
The sensor attachment portion 31 is provided with a pair of glass windows (not illustrated) facing each other in the Y-axis direction. The pair of glass windows transmits infrared light. In a state in which the respiratory gas sensor 2 is attached to the compatible airway adaptor 3, one of the pair of glass windows faces the light emitting portion 42 in the Y-axis direction, and the other one of the pair of glass windows faces the light detecting unit 41 in the Y-axis direction.
The first flange portion 45 is disposed between the first tube portion 32 and the sensor attachment portion 31 in the X-axis direction. In a state in which the respiratory gas sensor 2 is attached to the compatible airway adaptor 3, the first flange portion 45 covers a portion of the first surface 24 of the respiratory gas sensor 2 in the X-axis direction. The second flange portion 46 is disposed between the second tube portion 33 and the sensor attachment portion 31 in the X-axis direction. In a state in which the respiratory gas sensor 2 is attached to the compatible airway adaptor 3, the second flange portion 46 covers a portion of the second surface 27 of the respiratory gas sensor 2 in the X-axis direction.
The first adapter-side engagement portion 34 engages with the first sensor-side engagement portion 21 of the respiratory gas sensor 2 (see
The second adapter-side engagement portion 35 engages with the second sensor-side engagement portion 26 (see
The pair of first accommodation portions 36 prevent interference between the respiratory gas sensor 2 and the compatible airway adaptor 3. The pair of first accommodation portions 36 are disposed between the first tube portion 32 and the sensor attachment portion 31 in the X-axis direction, and face each other through the first adapter-side engagement portion 34 in the Y-axis direction. The pair of first accommodation portions 36 are cutout portions provided in the first flange portion 45. As illustrated in
The pair of second accommodation portions 37 prevent interference between the respiratory gas sensor 2 and the compatible airway adaptor 3. The pair of second accommodation portions 37 are disposed between the second tube portion 33 and the sensor attachment portion 31 in the X-axis direction, and face each other through the second adapter-side engagement portion 35 in the Y-axis direction. The pair of second accommodation portions 37 are cutout portions provided in the second flange portion 46. Each of the pair of second accommodation portions 37 accommodates a corresponding one of the pair of second attachment preventing portions 25 (see
In the present embodiment, since the compatible airway adaptor 3 is provided with the pair of first accommodation portions 36 and the pair of second accommodation portions 37, interference between the respiratory gas sensor 2 and the compatible airway adaptor 3 is prevented, and the compatible airway adaptor 3 is attachable to the respiratory gas sensor 2.
Next, an example of an incompatible airway adaptor will be described below with reference to
Here, the incompatible airway adaptor is an airway adaptor that is not compatible with the respiratory gas sensor 2. That is, the respiratory gas sensor 2 is not attachable to the incompatible airway adaptor 3a. More specifically, the respiratory gas sensor 2 is not attachable to the incompatible airway adaptor 3a in a state in which the incompatible airway adaptor 3a and the respiratory gas sensor interfere with each other.
As illustrated in
The tube portion 30a can include a respiratory gas ventilation passage 40a. The tube portion 30a can include a first tube portion 32a having a first outer diameter and a second tube portion 33a having a second outer diameter greater than the first outer diameter. The sensor attachment portion 31a determines a position of the respiratory gas sensor 2a relative to the incompatible airway adaptor 3a. Each of the first adapter engagement portion 34a and the second adapter engagement portion 35a engages with a corresponding portion of the respiratory gas sensor 2a.
The pair of first interference protruding portions 142 are configured such that the respiratory gas sensor 2 interferes with the incompatible airway adaptor 3a. The pair of first interference protruding portions 142 are protruding portions provided on the first flange portion 45a. As illustrated in
The pair of second interference protruding portions 143 are configured such that the respiratory gas sensor 2 interferes with the incompatible airway adaptor 3a. The pair of second interference protruding portions 143 are protruding portions provided on the second flange portion 46a. Each of the pair of second interference protruding portions 143 interferes with a corresponding one of the pair of second attachment preventing portions 25 (see FIG. 3). In particular, each of the pair of second interference protruding portions 143 comes into contact with the corresponding second attachment preventing portion 25 such that the corresponding second attachment preventing portion 25 interferes with the incompatible airway adaptor 3a. In this manner, the fitting portion 23 of the respiratory gas sensor 2 is not fitted to the sensor attachment portion 31a of the incompatible airway adaptor 3a, and thus the respiratory gas sensor 2 is not attachable to the incompatible airway adaptor 3a.
According to the present embodiment, the respiratory gas sensor 2 is attachable to the compatible airway adaptor 3 in a state in which the compatible airway adaptor 3 and the respiratory gas sensor 2 do not interfere with each other. On the other hand, the respiratory gas sensor 2 is not attachable to the incompatible airway adaptor 3a in a state in which the incompatible airway adaptor 3a that is not compatible with the respiratory gas sensor 2 and the respiratory gas sensor interfere with each other. In this manner, it is possible to provide the sensor attachment system 1 in which the respiratory gas sensor 2 is attachable or not attachable to an airway adaptor depending on a type of the airway adaptor, and it is possible to improve usability of the sensor attachment system 1 and the respiratory gas sensor 2.
For example, when the respiratory gas sensor 2 is a respiratory gas sensor that is applicable only to invasive positive pressure ventilation, the compatible airway adaptor 3 may be an intubation airway adaptor, while the incompatible airway adaptor 3a may be a non-intubation airway adaptor. In this case, the respiratory gas sensor 2 is attachable to the compatible airway adaptor 3 that is an intubation airway adaptor, and is not attachable to the incompatible airway adaptor 3a that is a non-intubation airway adaptor.
When the respiratory gas sensor 2 is a respiratory gas sensor for an adult, the compatible airway adaptor 3 may be an airway adaptor for an adult, while the incompatible airway adaptor 3a may be an airway adaptor for a neonate. In this case, the respiratory gas sensor 2 is attachable to the compatible airway adaptor 3 that is an airway adaptor for an adult, and is not attachable to the incompatible airway adaptor 3a that is an airway adaptor for a neonate.
In the present embodiment, it is possible to provide the sensor attachment system 1 in which the respiratory gas sensor 2 is attachable or not attachable to an airway adaptor depending on a type of the airway adaptor through the cooperation between the pair of first attachment preventing portions 22 and the pair of first accommodation portions 36 and the cooperation between the pair of second attachment preventing portions 25 and the pair of second accommodation portions 37. In this manner, the usability of the sensor attachment system 1 and the respiratory gas sensor 2 can be improved. In particular, the first attachment preventing portions 22 and the second attachment preventing portions 25 provided on the respiratory gas sensor 2 can reliably prevent the attachment of the respiratory gas sensor 2 to the incompatible airway adaptor 3a.
In the present embodiment, in the Y-axis direction, the pair of first attachment preventing portions 22 face each other through the first sensor-side engagement portion 21, and the pair of second attachment preventing portions 25 face each other through the second sensor-side engagement portion 26. According to such an arrangement structure, it is possible to reliably prevent the respiratory gas sensor 2 from being attached to the incompatible airway adaptor 3a, while it is possible to reliably attach the respiratory gas sensor 2 to the compatible airway adaptor 3. In this regard, the single first adapter-side engagement portion 34 is reliably snap-fitted to the first sensor-side engagement portion 21, and the single second adapter-side engagement portion 35 is reliably snap-fitted to the second sensor-side engagement portion 26. For this reason, the respiratory gas sensor 2 can be reliably attached to the compatible airway adaptor 3. On the other hand, since the pair of first attachment preventing portions 22 and the second attachment preventing portion 25 reliably interfere with the incompatible airway adaptor 3a, attachment between the respiratory gas sensor 2 and the incompatible airway adaptor 3a is reliably prevented.
In the present embodiment, the pair of first attachment preventing portions 22 and the pair of second attachment preventing portion 25 are columnar bodies extending in the Z-axis direction. For this reason, when the respiratory gas sensor 2 is inserted into the incompatible airway adaptor 3a along the Z-axis direction, the pair of the first attachment preventing portions 22 and the pair of second attachment preventing portions 25 extending in the Z-axis direction reliably interfere with the incompatible airway adaptor 3a. In particular, as illustrated in
Although the embodiment of the presently disclosed subject matter is described above, the technical scope of the presently disclosed subject matter should not be construed as being limited to the description of the embodiment. It is understood by those skilled in the art that the present embodiment is an example and various modifications may be made within the scope of the inventions described in the claims. The technical scope of the presently disclosed subject matter should be determined based on the scope of the inventions described in the claims and the scope of equivalents thereof.
In the present embodiment, the first attachment preventing portions 22 and the second attachment preventing portions 25 are provided on the respiratory gas sensor 2, and the number of attachment preventing portions is not particularly limited. In a same or similar manner, the number of the first accommodation portions 36 accommodating the first attachment preventing portions 22 and the number of the second accommodation portions 37 accommodating the second attachment preventing portions 25 are not particularly limited. For example, the single first attachment preventing portion 22 may be provided on the first surface 24 of the respiratory gas sensor 2, and the single second attachment preventing portion 25 may be provided on the second surface 27 of the respiratory gas sensor 2. In this case, the number of the first accommodation portions 36 and the number of the second accommodation portions 37 may be one.
In the present embodiment, the first attachment preventing portions 22 are disposed in the vicinity of the first sensor-side engagement portion 21, and the second attachment preventing portions 25 are disposed in the vicinity of the second sensor-side engagement portion 26.
In the present embodiment, attachment preventing portions are provided on the respiratory gas sensor 2 and accommodation portions that accommodate the attachment preventing portions are provided on the compatible airway adaptor 3, and the present embodiment is not limited thereto. In this regard, the attachment preventing portions may be provided on the airway adaptor, and the accommodation portions that accommodate the attachment preventing portions may be provided on the respiratory gas sensor. In this case, the attachment between the respiratory gas sensor and the airway adaptor is possible or not possible depending on a type of the respiratory gas sensor. In this case, each of plural attachment preventing portions provided on the airway adaptor may be a columnar body extending along the Z-axis direction. Further, each of plural accommodation portions provided on the respiratory gas sensor compatible with the airway adaptor (hereinafter referred to as compatible respiratory gas sensor) may be a groove extending along the Z-axis direction. In this way, by inserting each of the plural attachment preventing portions into the corresponding accommodation portion, the airway adaptor is attachable to the compatible respiratory gas sensor. On the other hand, a respiratory gas sensor that is not compatible with an airway adaptor (hereinafter referred to as incompatible respiratory gas sensor) is not provided with an accommodation portion that accommodates an attachment preventing portion. For this reason, when the plural attachment preventing portions provided on the airway adaptor interfere with the incompatible respiratory gas sensor, attachment between the airway adaptor and the incompatible respiratory gas sensor is reliably prevented.
The aforementioned embodiment is summarized as follows.
The present disclosure provides a sensor attachment system, a respiratory gas sensor, and a compatible airway adaptor with improved usability. In particular, the present disclosure provides a sensor attachment system in which a respiratory gas sensor is attachable or not attachable to an airway adaptor depending on a type of the airway adaptor.
A first aspect of the present disclosure relates to a sensor attachment system including: a sensor configured to detect a state of respiratory gas of a subject; and a compatible airway adaptor compatible with the sensor. The sensor includes a respiratory gas detector configured to detect the state of the respiratory gas of the subject, and a sensor-side engagement portion engageable with the compatible airway adaptor. The compatible airway adaptor includes a tube portion having a respiratory gas ventilation passage through which the respiratory gas passes, and an adapter-side engagement portion engageable with the sensor-side engagement portion. The sensor is attachable to the compatible airway adaptor in a state in which the compatible airway adaptor and the sensor do not interfere with each other, and the sensor is not attachable to an incompatible airway adaptor that is not compatible with the sensor in a state in which the incompatible airway adaptor and the sensor interfere with each other.
According to the above configuration, the respiratory gas sensor is attachable to the compatible airway adapter in a state in which the compatible air adapter that is compatible with the respiratory gas sensor and the respiratory gas sensor do not interfere with each other. On the other hand, the respiratory gas sensor is not attachable to the incompatible airway adaptor in a state in which the incompatible airway adaptor that is not compatible with the respiratory gas sensor and the respiratory gas sensor interfere with each other. In this manner, it is possible to provide a sensor attachment system in which a respiratory gas sensor is attachable or not attachable to an airway adaptor depending on a type of the airway adaptor, and it is possible to improve usability of the sensor attachment system.
A second aspect of the present disclosure relates to a respiratory gas sensor. The respiratory gas sensor is configured to detect a state of respiratory gas of a subject and is attachable to a compatible airway adaptor compatible with the respiratory gas sensor. The respiratory gas sensor includes: a respiratory gas detector configured to detect the state of the respiratory gas of the subject; and a sensor-side engagement portion engageable with the compatible airway adaptor. The respiratory gas sensor is attachable to the compatible airway adaptor in a state in which the compatible airway adaptor and the respiratory gas sensor do not interfere with each other, and the respiratory gas sensor is not attachable to an incompatible airway adaptor that is not compatible with the respiratory gas sensor in a state in which the incompatible airway adaptor and the respiratory gas sensor interfere with each other.
According to the above configuration, the respiratory gas sensor is attachable to the compatible airway adapter in a state in which the compatible air adapter that is compatible with the respiratory gas sensor and the respiratory gas sensor do not interfere with each other. On the other hand, the respiratory gas sensor is not attachable to the incompatible airway adaptor in a state in which the incompatible airway adaptor that is not compatible with the respiratory gas sensor and the respiratory gas sensor interfere with each other. In this manner, a respiratory gas sensor is attachable or not attachable to an airway adaptor depending on a type of the airway adaptor, and it is possible to improve usability of the respiratory gas sensor.
A third aspect of the present disclosure relates to a compatible airway adaptor. The compatible airway adaptor is attachable to a respiratory gas sensor configured to detect a state of respiratory gas of a subject. The compatible airway adaptor includes: a tube portion having a respiratory gas ventilation passage through which the respiratory gas passes; and an adapter-side engagement portion configured to engage with the respiratory gas sensor. The respiratory gas sensor includes an attachment preventing portion configured to cause the respiratory gas sensor to be unattachable to an incompatible airway adaptor that is not compatible with the respiratory gas sensor, and the compatible airway adaptor further includes an accommodation portion configured to accommodate the attachment preventing portion to prevent interference with the attachment preventing portion.
According to the above configuration, the accommodation portion configured to accommodate the attachment preventing portion is provided on the compatible airway adaptor to prevent interference with the attachment preventing portion provided on the respiratory gas sensor, and thus the respiratory gas sensor is attachable to the compatible airway adaptor. In this manner, it is possible to provide a compatible airway adaptor that is compatible with a respiratory gas sensor.
According to the present disclosure, it is possible to provide a sensor attachment system, a respiratory gas sensor, and a compatible airway adaptor with improved usability. In particular, it is possible to provide a sensor attachment system in which a respiratory gas sensor is attachable or not attachable to an airway adaptor depending on a type of the airway adaptor.
Number | Date | Country | Kind |
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2022-034701 | Mar 2022 | JP | national |