KR20220085272A - Medicine nebulizer, medicine treatment system having the same, and medicine treatment method using the same - Google Patents

Abstract

The present invention relates to a drug nebulizer, a drug treatment system including the same, and a drug treatment method using the same, and more particularly, it is possible to visually check the amount of a drug inhaled by a patient, It relates to a drug nebulizer capable of reducing stress and resistance to treatment, a drug treatment system including the same, and a drug treatment method using the same.
The present invention relates to a drug nebulizer 100 of a drug treatment system comprising a body part 200 for generating compressed air and a drug nebulizer 100 for spraying a drug with compressed air generated from the body part 200, , The drug nebulizer 100 includes a drug storage unit 110 in which a container for storing drugs is formed; an air delivery tube 120 connected to the main body 200 and the drug storage 110 to deliver compressed air generated from the main body 200 to the drug storage 110; In combination with the drug storage unit 110, the drug delivery unit 130 that delivers the drug sprayed from the drug storage unit 110 to the patient's respiratory tract and measures the patient's respiration with the air introduced by the patient's respiration Discloses a drug nebulizer 100, characterized in that it comprises a respiration measurement unit (140).

Description

Drug nebulizer, drug treatment system including the same, and drug treatment method using the same {Medicine nebulizer, medicine treatment system having the same, and medicine treatment method using the same}

The present invention relates to a drug nebulizer, a drug treatment system including the same, and a drug treatment method using the same, and more particularly, it is possible to visually check the amount of drug inhaled by a patient, It relates to a drug nebulizer capable of reducing stress and resistance to treatment, a drug treatment system including the same, and a drug treatment method using the same.

A drug nebulizer, such as a nebulizer, is a drug treatment system used for patients with diseases such as asthma, emphysema, and chronic bronchitis. Using compressed air, the nebulized drug is inhaled into the patient's nose or mouth to inject the drug into the patient's trachea and bronchi. and to the lungs to treat diseases.

However, since these drug nebulizers spray the drug regardless of the patient's breathing timing, it is difficult to measure the exact amount of drug inhaled by the patient.

In addition, since the drug nebulizer uses compressed air to inject the drug, a compressor motor for generating the compressed air is used, and at this time, there is a problem in that the noise of the motor is generated and the patient feels stress during the treatment process.

In particular, in the case of infant patients, they were surprised by the noise of the compressor motor and refused to receive respiratory treatment, which made it difficult to treat them.

In order to solve the above problems, the present invention is a drug nebulizer that can visually check the amount of drug inhaled by a patient, and converts noise caused by motor driving into music to reduce the patient's objection to treatment, comprising the same A drug treatment system and a drug treatment method using the same are provided.

The present invention was created to achieve the object of the present invention as described above, and the present invention is a drug for spraying a drug with the compressed air generated from the main body 200 and the main body 200 for generating compressed air In the drug nebulizer 100 of the drug treatment system including the nebulizer 100, the drug nebulizer 100, the drug storage unit 110 in which a container for storing the drug is formed; an air delivery tube 120 connected to the main body 200 and the drug storage 110 to deliver compressed air generated from the main body 200 to the drug storage 110; a drug delivery unit 130 coupled to the drug storage unit 110 to deliver the drug sprayed from the drug storage unit 110 to the respiratory tract of the patient; Discloses a drug nebulizer 100, characterized in that it comprises a respiration measurement unit 140 for measuring the respiration of the patient with the air introduced by the respiration of the patient.

The drug delivery unit 130, the vertical portion 131-1 coupled to the drug storage unit 110, the vertical portion 131-1 is formed extending in a right angle direction, both ends are open horizontal portion ( 131-2) and a cylinder part 131 including; a respiratory contact part 132 fitted to one end of the horizontal part 131-2 and in direct or indirect contact with the patient's respiratory tract; and a drug delivery part 130 including a stopper part 133 fitted to open and close the other end of the horizontal part 131-2; The respiration measurement unit 140 may be installed on the inside of the horizontal portion (131-2).

The respiration measurement unit 140, and one or more rotary wing units 141 rotated by the patient's breathing; a rotating shaft 142 that supports the one or more rotating blades, but both ends are fixed through the horizontal portion 131-2; A rotation sensor unit 143 connected to one end of the rotation shaft 142 to measure rotation information of the rotation shaft 142 may be included.

The respiration measurement unit 140 may be installed on the inside of the drug delivery unit 130 .

In addition, the present invention, in the drug treatment system including the above-described drug nebulizer 100, the drug treatment system, the drug inhalation amount derivation unit 300 for outputting the drug intake amount through the patient's respiration information, and ; The drug intake derivation unit 300 includes a respiration information conversion unit 310 for converting the signal received from the respiration measurement unit 140 into respiration information; a display unit 330 visually showing the patient's drug intake; Acquires the patient's respiration information from the respiration information conversion unit 310, derives the patient's drug intake based on the acquired respiration information of the patient, and transmits the respiration information control unit 320 to the display unit 330 may include

The respiration information may be at least one of a patient's respiration rate, a patient's respiratory pressure, a patient's respiratory flow, a patient's expiratory volume, a patient's inspiratory volume, a patient's expiration time, a patient's inspiratory time, a patient's expiration, and an inspiratory interval. have.

The respiration information control unit 320, the patient's respiration information, the compressed air pressure of the main body 200 and the size and volume of the drug nebulizer 100, the amount of the drug, the drug injection speed and time at least any one Taking this into account, the patient's drug intake can be derived.

The display unit 330 may output an intake curve and an expiration curve of the patient, and a drug intake curve corresponding to the intake curve and the expiration curve.

The drug treatment system, the noise sensor 400 for measuring the noise generated when the motor is driven; and a noise reducing unit 500 for purifying the noise detected by the noise sensor 400 into music; The noise alleviation unit 500 includes a noise information conversion unit 510 for converting the noise detected by the noise sensor 400 into noise information; a sound output unit 530 for outputting music; It may include a sound control unit 520 that controls the sound output unit 530 to output music based on the noise information provided from the noise information conversion unit 510 .

The noise information may be decibels of motor noise.

The sound control unit 520 may control the sound output unit 530 so that the music output from the sound output unit 530 is output in decibels greater than decibels of motor noise.

In addition, the present invention discloses a drug treatment method for performing respiratory treatment of a patient, wherein the drug treatment method is a drug treatment method performed using the above-described drug treatment system.

The present invention has the advantage that it can help in patient treatment by visually showing the amount of drug inhaled by the patient through the drug inhalation amount derivation unit to visually provide the patient, guardian, and medical staff how much the drug has been applied to the patient. .

In addition, the present invention has the advantage of reducing the patient's stress and the patient's objection to treatment by converting the noise of the motor into music through the noise alleviation unit.

In addition, the present invention has the advantage that it is possible to reduce the fatigue of caregivers and medical staff by reducing the child's treatment rejection, and to improve the treatment effect of the patient.

1 is a perspective view showing a drug treatment system according to the present invention.
Figure 2a is a cross-sectional view of the drug nebulizer, a side cross-sectional view showing the rotation of the respiration measurement unit during inspiration of the patient.
Figure 2b is a cross-sectional view of the drug nebulizer, a side cross-sectional view showing the rotation of the respiration measurement unit during the exhalation of the patient.
3 is a cross-sectional view in the I-I direction of Figure 2a, a cross-sectional view showing the front of the respiration measurement unit.
4 is a conceptual diagram showing a drug intake amount derivation unit according to the present invention.
5 is a conceptual diagram showing a noise alleviator according to the present invention.

Hereinafter, a drug nebulizer according to the present invention, a drug treatment system including the same, and a drug treatment method using the same will be described with reference to the drawings.

The present invention relates to a drug nebulizer 100 of a drug treatment system comprising a body part 200 for generating compressed air and a drug nebulizer 100 for spraying a drug with the compressed air generated from the body part 200, , The drug nebulizer 100, the drug storage unit 110 in which a container for storing the drug is formed; an air delivery tube 120 connected to the main body 200 and the drug storage 110 to deliver compressed air generated from the main body 200 to the drug storage 110; a drug delivery unit 130 coupled to the drug storage unit 110 to deliver the drug sprayed from the drug storage unit 110 to the respiratory tract of the patient; Discloses a drug nebulizer 100, characterized in that it comprises a respiration measurement unit 140 for measuring the respiration of the patient with the air introduced by the respiration of the patient.

Here, the main body 200 is a configuration for generating compressed air, and various configurations are possible.

The main body 200 may include various motors to generate compressed air, for example, may include a compressor motor.

On the other hand, the drug nebulizer 100 is a device that assists in respiratory treatment by spraying a drug with compressed air generated from the main body 200 and providing it to the respiratory tract of a patient, and various configurations such as a nebulizer are possible. .

Here, the drug nebulizer 100, the drug storage unit 110 in which a container for storing the drug is formed; an air delivery tube 120 connected to the main body 200 and the drug storage 110 to deliver compressed air generated from the main body 200 to the drug storage 110; a drug delivery unit 130 coupled to the drug storage unit 110 to deliver the drug sprayed from the drug storage unit 110 to the respiratory tract of the patient due to compressed air; It may include a respiration measurement unit 140 for measuring the respiration of the patient with the air introduced by the respiration of the patient.

The drug storage unit 110 is a configuration in which a container for storing drugs is formed, and various configurations are possible.

Here, the drug storage unit 110, as shown in FIGS. 2A to 2B, may contain various drugs for respiratory treatment such as asthma, pneumonia, and bronchiolitis, and may include an inflammatory regulator and symptom reliever. is of course

The shape of the drug storage unit 110 may have various shapes, and may have various materials such as synthetic resins and ceramics.

The air delivery tube 120 is connected to the body part 200 and the drug storage part 110 to deliver compressed air generated from the body part 200 to the drug storage part 110 as a configuration. , various configurations are possible.

Specifically, the air delivery tube 120 transfers the compressed air generated by the motor of the main body 200 to the drug storage unit 110 to convert the drug stored in the drug storage unit 110 into a fine aerosol. can make

Here, the air delivery tube 120 may have various materials, for example, may include a material such as rubber or silicone.

The drug delivery unit 130 is combined with the drug storage unit 110 to deliver the drug sprayed from the drug storage unit 110 to the respiratory tract of the patient due to compressed air, and various configurations are possible. .

The drug delivery unit 130 may have a variety of materials, for example, may have a material of a synthetic resin such as silicone, plastic, of course.

Specifically, the drug delivery unit 130 is formed extending in a direction perpendicular to the vertical portion 131-1 coupled to the drug storage unit 110 and the vertical portion 131-1, and both ends are open. a cylinder part 131 including a horizontal part 131-2; a respiratory contact part 132 fitted to one end of the horizontal part 131-2 and in direct or indirect contact with the patient's respiratory tract; It may include a drug delivery unit 130 including a stopper portion 133 fitted to open and close the other end of the horizontal portion (131-2).

The cylinder part 131 is a configuration that delivers a drug to the respiratory tract of the patient, and various configurations are possible.

Here, the cylinder part 131 may have various shapes such as a cylindrical shape and a rectangular shape, and may have a 'T'-shaped structure including a vertical part 131-1 and a horizontal part 131-2.

The vertical portion 131-1 is a configuration coupled to the drug storage unit 110, as shown in FIGS. 2A to 2B, and various configurations are possible.

Here, the vertical portion 131-1 may be integrally formed with the drug storage unit 110, and may be formed separately to be coupled to the drug storage unit 110 in various ways, such as by fitting.

The horizontal portion 131-2 is formed to extend in a direction perpendicular to the vertical portion 131-1 and has both ends open, and various configurations are possible.

As shown in FIGS. 2A to 2B , the horizontal portion 131-2 may be formed to extend in any direction, such as a direction perpendicular to the vertical portion 131-1 as well as a horizontal direction or a deviated direction, of course. to be.

The respiratory contact part 132 is fitted to one end of the horizontal part 131-2 and is in direct or indirect contact with the patient's respiratory tract, and various configurations are possible.

For example, the respiratory contact unit 132, as shown in FIGS. 1 to 2B, the drug delivery unit 130 is formed with a mouthpiece that the patient can bite with his mouth on one side of the patient Direct contact with the mouth of the patient, or a mask that covers the patient's mouth and nose is formed on one side to indirectly contact the patient's respiratory tract.

In addition, it goes without saying that the respiratory contact part 132 may be detachably coupled to the horizontal part 131 - 2 .

The stopper 133 is a configuration that is fitted to open and close the other end of the horizontal portion 131 - 2 , and various configurations are possible.

The stopper 133 may be fitted to the other end of the horizontal portion 131 - 2 as shown in FIGS. 2A to 2B , and in this case, may be detachably coupled to the cylinder portion 131 . of course there is

On the other hand, during respiratory treatment using a conventional nebulizer, the drug sprayed with the nebulizer is administered only while the patient inhales, whereas the nebulizer continuously injects the drug regardless of the patient's breathing timing, so the patient's accurate drug There is a difficulty in not being able to measure the inhalation amount.

That is, when the patient exhales, the drug that is not inhaled is discharged to the atmosphere in front of the patient, and there is a problem in that it is not possible to accurately measure how much the drug is inhaled by the patient due to the loss of the drug.

The present invention further includes a respiration measurement unit 140 that can more accurately provide the amount of the drug inhaled by the patient by measuring the patient's respiration in the drug nebulizer 100 in order to solve the above problems.

The respiration measurement unit 140, as a configuration for measuring the respiration of the patient with the air introduced by the respiration of the patient, various configurations are possible.

At this time, the respiration measurement unit 140 may be installed at any position where air due to the patient's breathing flows in order to use the air introduced into the patient's breathing, but in order to receive structural stability and air flow effectively, the 3 , it may be installed inside the horizontal part 131 - 2 of the cylinder part 131 .

For example, the respiration measurement unit 140, and one or more rotary wing units 141 rotated by the patient's breathing; a rotating shaft 142 that supports the one or more rotating blades, but both ends are fixed through the horizontal portion 131-2; A rotation sensor unit 143 connected to one end of the rotation shaft 142 to measure rotation information of the rotation shaft 142 may be included.

Here, the rotor blade 141 is configured to rotate by the patient's breathing, and various configurations are possible.

Here, the rotor blade 141 is rotated by the patient's inhalation or exhalation, and may be rotated in opposite directions by the air generated by the patient's inhalation and exhalation, respectively.

The rotor blade 141 may have various shapes, and may be formed in a plate shape, a rod shape, or the like.

In addition, the rotor blade 141 may have one or more various numbers, and may have various materials such as silicon, synthetic resin, ceramic, and the like.

Here, the rotating shaft 142 is configured to support the one or more rotating blades, but both ends are fixed through the horizontal portion 131-2, and various configurations are possible.

The rotation shaft 142 may be fixedly installed through the cylinder part 131 as shown in FIGS. 2A to 3 , but is not limited thereto, and is installed anywhere in the position where air flows due to the patient's breathing. can be

Of course, the rotation shaft 142 may have various shapes, and may have various materials such as metal, plastic, ceramic, and the like.

Here, the rotation sensor unit 143 is connected to one end of the rotation shaft 142 to measure rotation information of the rotation shaft 142 , and various configurations are possible.

Here, the rotation information of the rotation shaft 142 may include various information related to rotation, such as the number of rotations of the rotation shaft, the rotation direction and the rotation speed, which may be transmitted to the respiration information conversion unit 310 to be described later.

Furthermore, the respiration measurement unit 140 uses the pressure difference between both ends of the resistor, including the resistor used in the lung test device, or uses the temperature difference between exhalation and inspiration, including an electric heating wire, or a sound transmission device. Respiratory information can also be acquired by using the difference in height and volume of sound during exhalation and inspiration by installing it.

On the other hand, it may include a drug intake derivation unit 300 to obtain a drug intake amount through the patient's respiration information obtained from the respiration measurement unit (140).

The drug intake derivation unit 300, as shown in FIG. 4, a respiration information conversion unit 310 for converting the signal received from the respiration measurement unit 140 into respiration information; a display unit 330 visually showing the patient's drug intake; Acquires the patient's respiration information from the respiration information conversion unit 310, derives the patient's drug intake based on the acquired respiration information of the patient, and transmits the respiration information control unit 320 to the display unit 330 may include

At this time, the drug inhalation amount deriving unit 300, a memory unit that can store respiration information and rotation information, etc., the rotation sensor unit 143 and the display unit 330, such as a communication unit that can communicate wirelessly / wired, etc. Of course, it can be included.

Here, for the wireless communication, zigbee, Bluetooth, XBee, Wifi, etc. may be used.

The respiration information conversion unit 310, as a configuration for converting the signal received from the respiration measurement unit 140 into respiration information, various configurations are possible.

Specifically, the respiration information conversion unit 310 may convert information such as the number of rotations, rotation direction and rotation speed of the rotation shaft of the rotation shaft from the rotation sensor unit 143 to the patient's respiration information.

For example, the respiration information conversion unit 310 may derive the respiration flow rate by multiplying the rotation speed and rotation time of the rotation shaft using the principle of the flow meter, and the rotation direction is clockwise through the rotation direction. In the case of an exhaled state, it can be deduced that it is an inspiratory state in the case of a counterclockwise direction.

Here, the patient's respiration information may be various information related to the patient's respiration, such as the patient's respiration rate, the patient's respiratory pressure, the patient's respiratory flow, the patient's expiration time, the patient's inspiration time, and the patient's expiration and inspiratory interval.

The display unit 330 is a configuration that visually shows the amount of drug inhaled by the patient, and various configurations are possible.

Here, the display unit 330 may include one or more display devices such as a computer monitor or a smartphone to visually show the patient's drug intake amount, and the display unit 330 may be fixed to the drug treatment system or , can be installed to be movable.

In addition, the display unit 330, in order to visually show the patient's drug intake to the patient, caregiver, and medical staff, the patient's inspiratory curve and expiratory curve and the drug intake curve corresponding to the inspiratory curve and the expiratory curve are output as an image can do.

Here, the respiration information control unit 320 obtains the patient's respiration information from the respiration information conversion unit 310, derives the patient's drug intake based on the acquired respiration information of the patient, and displays it on the display unit 330. As a configuration for transmitting, various configurations are possible.

Specifically, the respiration information control unit 320, the patient's respiration information, the compressed air pressure of the main body 200 and the size and volume of the drug nebulizer 100, the amount of the drug, the drug injection rate and time at least Taking any one into account, the patient's drug intake can be derived.

For example, the respiration information control unit 320 receives data on the respiratory flow rate and respiration time of the patient's exhalation state, the respiration flow rate and respiration time of the inspiratory state, and through this, the expiratory volume and the inspiratory volume can be derived, and the The injection speed and injection time of the drug can be derived through the pressure of the compressed air of the main body 200, the velocity of the compressed air, the size and volume of the drug nebulizer 100, the amount of the drug, and the like.

At this time, information such as the pressure of the compressed air of the main body 200, the speed of the compressed air, the size and volume inside the drug nebulizer 100, the amount of the drug, etc. can be entered in advance in the respiration information control unit 320 of course there is

That is, the respiration information control unit 320 displays information on the expiration curve according to the expiration time and amount, information on the inspiration curve according to the inspiration time and the amount of inspiration, and the amount of the drug through the injection speed and injection time of the drug. By transmitting to the unit 330, the display unit 330 can output the patient's inspiratory curve and expiratory curve and the drug intake curve corresponding to the inspiratory curve and expiratory curve as an image.

On the other hand, since the drug injection device uses compressed air to inject the drug, a compressor motor is used to generate the compressed air, and at this time, the noise of the motor is generated.

Such motor noise can give stress to the patient. In particular, in the case of infant patients, they are surprised by the motor noise and refuse treatment, resulting in difficulties in treatment, and parents complaining of guilt, anxiety and fatigue due to care There were problems such as

The present invention includes a noise sensor 400 for measuring noise generated when driving a motor in order to solve the above problems; It may include a noise alleviation unit 500 for purifying the noise detected by the noise sensor 400 into music.

The noise sensor 400 is a configuration for measuring noise generated when the motor is driven, and various configurations are possible.

At this time, the noise sensor 400 may be located anywhere, but it may be preferable to be installed in the main body 200 .

The noise alleviation unit 500 is a configuration for purifying the noise detected by the noise sensor 400 into music, and various configurations are possible.

Specifically, the noise alleviation unit 500 includes a noise information conversion unit 510 for converting the noise detected by the noise sensor into noise information; a sound output unit 530 for outputting music; It may include a sound control unit 520 that controls the sound output unit 530 to output music based on the noise information provided from the noise information conversion unit 510 .

In this case, the noise alleviation unit 500 may include a memory unit that can store music and noise information, and a communication unit that can communicate wirelessly/wired with the noise sensor 400 and the sound output unit 530 and the like. of course there is

Here, for the wireless communication, zigbee, Bluetooth, XBee, Wifi, etc. may be used.

The noise information conversion unit 510 is a configuration that converts the noise detected by the noise sensor into noise information, and various configurations are possible.

Here, the noise information may be various information related to noise, such as decibels of motor noise and audible frequencies of motor noise.

Here, the sound output unit 530 is a configuration for outputting music, and various configurations are possible.

In this case, the music may be selected in various ways according to the patient's age, gender, and taste, for example, nursery rhymes may be selected in the case of an infant patient.

The sound output unit 530 may have any configuration as long as it can output music, and may be, for example, a speaker, a headphone, or an earphone.

Meanwhile, the sound control unit 520 is a configuration that controls the sound output unit 530 to output music based on the noise information provided from the noise information conversion unit 510 , and various configurations are possible.

Specifically, the sound controller 520 can minimize the stress and rejection caused by the motor noise of the patient by outputting the music sound louder than the motor sound or reproducing the music such as the audible frequency of the noise.

More specifically, the sound control unit 520 may control the sound output unit 530 such that the music output from the sound output unit 530 is output in decibels greater than the decibels of the motor noise.

For example, in general, the motor noise is 70 dB to 85 dB, and since the decibel is a logarithmic function, a difference of about 3 dB is required in order to output music that is twice the decibel of the motor noise. Unit 530 can be programmed to output 73 dB to 88 dB of music.

Meanwhile, the main body 200 may include a soundproof box in which the main body 200 can be accommodated in order to reduce noise generated by the motor.

The soundproof box can use various materials to prevent noise generated from the motor from leaking out, for example, glass fiber, rock wool, felt, cork, soft fiber board, polyurethane, asbestos felt, rock fiber, foamed styrene resin. etc. may be used.

In addition, it goes without saying that the drug treatment method for performing respiratory treatment of a patient may be performed using the above-described drug treatment system.

Since the above has only been described with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention as noted above should not be construed as being limited to the above embodiments, and It will be said that the technical idea and the technical idea accompanying the fundamental are all included in the scope of the present invention.

10: drug treatment system 100: drug nebulizer
200: body part

Claims (12)

In the drug nebulizer 100 of a drug treatment system comprising a body part 200 for generating compressed air and a drug nebulizer 100 for spraying a drug with the compressed air generated from the body part 200,
The drug nebulizer 100,
a drug storage unit 110 in which a container for storing drugs is formed;
an air delivery tube 120 connected to the main body 200 and the drug storage 110 to deliver compressed air generated from the main body 200 to the drug storage 110;
a drug delivery unit 130 coupled to the drug storage unit 110 to deliver the drug sprayed from the drug storage unit 110 to the respiratory tract of the patient;
Drug nebulizer 100, characterized in that it comprises a respiration measurement unit 140 for measuring the respiration of the patient with the air introduced by the respiration of the patient. The method according to claim 1,
The drug delivery unit 130, the vertical portion 131-1 coupled to the drug storage unit 110, the vertical portion 131-1 is formed extending in a right angle direction, both ends are open horizontal portion ( 131-2) and a cylinder part 131 including;
a respiratory contact part 132 fitted to one end of the horizontal part 131-2 and in direct or indirect contact with the patient's respiratory tract;
and a drug delivery part 130 including a stopper part 133 fitted to open and close the other end of the horizontal part 131-2;
Drug nebulizer 100, characterized in that the respiration measurement unit 140 is installed inside the horizontal portion (131-2). 3. The method according to claim 2,
The respiration measurement unit 140,
One or more rotary blades 141 that rotate by the patient's breathing;
a rotating shaft 142 that supports the one or more rotating blades, but both ends are fixed through the horizontal portion 131-2;
The drug nebulizer 100, which is connected to one end of the rotation shaft 142 and comprises a rotation sensor unit 143 for measuring rotation information of the rotation shaft 142. The method according to claim 1,
The respiration measurement unit 140, the drug nebulizer 100, characterized in that installed on the inside of the drug delivery unit (130). 5. A drug treatment system comprising the drug nebulizer 100 of any one of claims 1 to 4,
The drug treatment system includes a drug intake derivation unit 300 for outputting a drug intake amount through the patient's respiration information;
The drug intake derivation unit 300,
Respiratory information conversion unit 310 for converting the signal received from the respiration measurement unit 140 into respiration information and;
a display unit 330 visually showing the patient's drug intake;
Obtains the patient's respiration information from the respiration information conversion unit 310, derives the patient's drug intake based on the acquired respiration information of the patient, and transmits the respiration information control unit 320 to the display unit 330. A drug treatment system comprising: 6. The method of claim 5,
The breathing information is
Drug treatment, characterized in that at least one of the patient's respiration rate, the patient's respiratory pressure, the patient's respiratory flow, the patient's expiratory volume, the patient's inspiratory volume, the patient's expiration time, the patient's inspiration time, the patient's expiration, and the inspiratory interval system. 6. The method of claim 5,
The respiration information control unit 320,
The patient's respiration information, the compressed air pressure of the main body 200 and the size and volume of the drug nebulizer 100, the amount of the drug, the drug injection rate and time to derive the patient's drug intake in consideration of at least any one A drug treatment system, characterized in that. 6. The method of claim 5,
The display unit 330,
A drug treatment system, characterized in that the patient's inspiratory and expiratory curves and the drug intake curve corresponding to the inspiratory and expiratory curves are output. 6. The method of claim 5,
The drug treatment system, the noise sensor 400 for measuring the noise generated when the motor is driven;
and a noise reducing unit 500 for purifying the noise detected by the noise sensor 400 into music;
The noise alleviation unit 500,
a noise information conversion unit 510 for converting the noise detected by the noise sensor 400 into noise information;
a sound output unit 530 for outputting music;
Drug treatment system comprising a sound control unit (520) for controlling the sound output unit (530) to output music based on the noise information provided from the noise information conversion unit (510). 10. The method of claim 9,
The noise information is a drug treatment system, characterized in that the decibel of the motor noise. 11. The method of claim 10,
The sound control unit 520,
A drug treatment system, characterized in that the sound output unit (530) is controlled so that the music output from the sound output unit (530) is output in decibels greater than decibels of motor noise. As a drug treatment method for performing respiratory treatment of a patient,
The drug treatment method is a drug treatment method, characterized in that it is performed using the drug treatment system according to any one of claims 9 to 11.

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