JPWO2017069204A1 - Infusion tube and infusion set - Google Patents

Abstract

The drip tube is made of a transparent resin and has an inner wall surface covered with a coating agent, and a droplet attached to the inner wall surface gives a contact angle of 10 degrees or less.

Description

  The present invention relates to an infusion tube and an infusion set.

  In order to administer appropriate infusion solutions, the flow rate of the infusion solution is controlled by counting the number of droplets dropped in a drip tube or measuring the size (volume) of the droplets. Things have been done. For example, Japanese Patent Laid-Open No. 2008-161610 (Patent Document 1) discloses the following method in order to set the amount of infusion to a predetermined amount. That is, conditions such as the total amount of drip solution and the number of drops per milliliter are set. On the other hand, the light emitted from the light emitting diode is detected by a photosensor for detection, and the actual number of drops is counted. In this method, the opening degree of the conduit connected to the drip tube is adjusted using a linear stepping motor (actuator) according to the difference between the counted number of drops and the above condition.

  Japanese Unexamined Patent Application Publication No. 2011-062371 (Patent Document 2) discloses a drip detection apparatus that can measure not only the number of drops but also the size (volume) of a drop using a two-dimensional image sensor. Has been.

JP 2008-161610 A JP 2011-062371 A

  However, the droplet dropped from the lower end of the nozzle may bounce off and adhere to the inner wall surface of the drip tube, and may remain in place without dropping. In this case, the droplet remaining on the inner wall surface of the drip tube becomes a lens, and the light from the light emitting diode is refracted and does not reach the photosensor for detection, which may hinder accurate counting of the number of drops. Actually, when the drip tube is rotated around the vertical axis while the droplet stays on the inner wall, depending on the angle, the droplet on the inner wall interferes with the light from the light-emitting diode, and the photo for detection The voltage value output from the sensor greatly fluctuates. In such a case, it is difficult to accurately count the number of drops.

  Further, the liquid droplet remaining on the inner wall surface of the drip tube may enter the field of view of the two-dimensional image sensor, which may cause a problem in measuring the volume of the liquid droplet.

  Furthermore, there is a known technique for preventing water droplets from adhering to the vehicle by coating the windows and mirrors of the vehicle, but the coating agent used for these is diverted to the inner wall of the drip tube. In order to do so, it is necessary to be cautious when considering the effects on the living body. For this reason, the problem regarding the droplet adhesion of the drip tube is a problem peculiar to the technical field related to drip.

  The present invention has been made in view of the above circumstances, and a drip tube and an infusion set that can prevent droplets from staying in place while adhering to the inner wall surface and can accurately count the number of droplets and measure the volume of the droplets. The purpose is to provide.

In order to achieve the above object, the present invention has the following features.
[1]
A drip tube having an inner wall surface made of a transparent resin and coated with a coating agent, and a droplet attached to the inner wall surface gives a contact angle of 10 degrees or less.

[2]
The drip tube according to [1], wherein the resin includes any one of polypropylene, polyethylene, and an ethylene-propylene copolymer.

[3]
The coating agent includes polyoxyethylene sorbitan monooleate, polymer brush containing carboxybetaine monomer, polyoxyethylene (10) octylphenyl ether, sodium di (2-ethylhexyl) sulfosuccinate, sorbitan monolaurate and 3-[( [3] The drip tube according to [1] or [2], comprising one or more selected from the group consisting of 3-colamidopropyl) dimethylammonio] -1-propanesulfonate.

[4]
The drip tube according to any one of [1] to [3], wherein the inner wall surface has a plasma-modified portion, and the coating agent is applied to the plasma-modified portion.

[5]
The said inner wall surface has a silica layer, The said coating agent is a drip cylinder in any one of [1]-[3] currently apply | coated on the said silica layer.

[6]
The drip tube according to any one of [1] to [5], and a nozzle that is inserted from above the drip tube and has a hydrophobic drip port at the lower end for dropping the droplet into the drip tube. An infusion set.

  According to the present invention, it is possible to provide a drip tube and an infusion set that can prevent droplets from staying in place while adhering to the inner wall surface, and can accurately count the number of droplets and measure the volume of the droplets. it can.

It is explanatory drawing explaining schematic structure of the infusion set in a present Example, Comprising: It is a top view of the infusion set which abbreviate | omitted and represented the nozzle. It is explanatory drawing explaining schematic structure of the infusion set in a present Example, Comprising: It is a front view of an infusion set. In the infusion set shown in FIGS. 1A and 1B, a liquid reservoir is formed in the lower part of the drip tube, and droplets are dropped intermittently into the liquid reservoir, and the dropped droplets rebound and adhere to the inner wall surface of the drip tube. 5 is a graph comparing the sensor voltage values output from the five detection photosensors [channels (CH) 1 to 5] constituting the photointerrupter in the embodiment and the comparative example.

  Embodiments according to the present invention will be described below. The embodiment described below is an exemplification, and partial replacement or combination with configurations shown in different embodiments or examples is possible. The same effect by the same configuration will not be sequentially described for each embodiment or for each example.

<Drip tube>
The drip tube according to the present invention has an inner wall surface made of a transparent resin and covered with a coating agent, and a droplet attached to the inner wall surface gives a contact angle of 10 degrees or less. Here, the contact angle given by the droplet of 10 degrees or less indicates an angle after wetting and spreading. That is, it means that the contact angle given by the droplet after wetting and spreading after a predetermined time has elapsed is 10 degrees or less, not the contact angle given by the droplet immediately after adhering to the inner wall surface.

  In the present specification, “transparent” in the case of a transparent resin means that at least one of visible light and infrared light passes through the resin. In other words, when the inside of the drip tube can be visually recognized from the outside under visible light or infrared light, the drip tube is made of “transparent” resin. That is, the drip tube according to the present embodiment is made of a resin that transmits at least one of visible light and infrared light. In particular, the “transparent resin” constituting the drip tube in the present specification preferably exhibits 80% or more in the total light transmittance measured in accordance with the provisions of JIS K 7361 (1997).

  The resin constituting the drip tube preferably contains any of polypropylene (PP), polyethylene (PE), and ethylene-propylene copolymer. Thereby, while providing the intensity | strength calculated | required by an infusion tube, it becomes transparent with respect to at least one of visible light and infrared light. Moreover, these resins show hydrophobicity.

  The coating agent that coats the inner wall surface of the drip tube is preferably a compound having a hydrophilic functional group and biocompatibility, and reduces the contact angle given by the droplets attached to the inner wall surface of the drip tube. Suitable for Examples of the hydrophilic functional group possessed by the coating agent include a hydroxyl group, an amino group, a carboxyl group, an aldehyde group, an oxyethylene group, and a sulfo group, but are not particularly limited as long as the effects of the present invention are exhibited.

  Specifically, the coating agent for coating the inner wall surface of the drip tube includes polyoxyethylene sorbitan monooleate, polymer brush containing carboxybetaine monomer, polyoxyethylene (10) octylphenyl ether, di (2-ethylhexyl) sulfosuccinate. It is preferable to include one or more selected from the group consisting of sodium acid, sorbitan monolaurate and 3-[(3-colamidopropyl) dimethylammonio] -1-propanesulfonate. The coating agent is preferably used as a preparation liquid diluted in a solvent. Water or ethanol can be used as the solvent.

  The coating area of the coating agent may be covered on the entire inner wall surface of the drip tube, but is limited to the area of the inner wall surface affected by either or both of the two-dimensional image sensor and the photo interrupter. It is preferable. This is because the range is usually a range where there is no liquid stored in the drip tube. Depending on the resin constituting the drip tube, the type of coating agent, and the coating method, the liquid stored in the drip tube may come into contact with the coating agent for a long time, so that the coating component may be eluted into the liquid. On the other hand, this possibility can be reduced in the form in which the coating agent is coated only on a part of the inner wall surface as described above.

  The thickness of the coating agent coated on the inner wall surface is preferably 1 nm or more and 1 μm or less. If the thickness of the coating agent exceeds 1 μm, the visibility may be affected. Moreover, there exists a possibility that sufficient wettability may not be exhibited as the thickness of a coating agent is less than 1 nm.

  The contact angle with the inner wall surface of the drip tube is desirably 10 degrees or less. That is, by defining the contact angle of the liquid droplets adhering to the inner wall surface to be 10 degrees or less, even if the liquid droplets dripping from the nozzle drip port bounce off the liquid reservoir and adhere to the inner wall surface, for example, This is because it means that it spreads along the inner wall without staying. Note that the minimum contact angle given by the droplets adhering to the inner wall surface is ideally 0 degree.

  Here, the contact angle can be calculated by the following equation (1) using a so-called θ / 2 method. In the following formula (1), r is the radius of the droplet, h is the height of the droplet, and θ is the contact angle of the droplet.

<Modification method of inner wall surface of drip tube>
It is preferable that the inner wall surface of the drip tube has a plasma modified portion, and the coating agent is applied to the plasma modified portion. The plasma modified portion refers to a portion of the inner wall surface whose surface has been modified by plasma treatment. In addition, oxygen plasma is preferably used for the plasma treatment.

  As described above, the inner wall surface of the drip tube is covered with the coating agent. The plasma treatment can modify the inner wall surface as a plasma modification portion by plasma and form a surface that is easily covered with a coating agent, so that the above configuration can be achieved easily and reliably. Further, the plasma treatment can modify only the surface of a resin molded product such as a drip tube without affecting the inside or the deep part thereof. Furthermore, since it is a dry process, the problem of waste liquid does not occur. And by carrying out plasma processing with oxygen plasma, the surface dirt can be removed or a hydrophilic functional group can be given.

  On the other hand, when only the plasma treatment is performed, the inner wall surface of the drip tube can be temporarily modified to be hydrophilic. However, after plasma treatment, there is a problem that the hydrophilic effect by modification is faded over time.

  For this reason, in the present embodiment, the inner wall surface of the drip tube made of a transparent resin is first activated by being irradiated with oxygen plasma to form a plasma-modified portion. After that, a preparation solution prepared by dissolving the above coating agent in a solvent such as ethanol or water is applied to the plasma reforming portion of the drip tube, and further dried to obtain a plasma reforming portion of the drip tube. Can be coated with a coating agent. As a result, it is possible to produce a drip tube that can be evaluated when the droplets adhering to the inner wall surface give a contact angle of 10 degrees or less and sufficiently exhibit wettability.

  In the present embodiment, since the coating agent is applied to the plasma modified portion as described above, it is preferable that the plasma modified portion is formed on the entire inner wall surface of the drip tube. However, even if the plasma modified portion is not formed on a part of the inner wall surface, it does not depart from the scope of the present invention as long as the effect of the present invention is exhibited. For example, the plasma-modified portion does not have to be formed at least in the range of the inner wall surface that is not affected by the photo interrupter, which is a configuration added to an infusion set described later.

  Plasma treatment of the inner wall surface of the drip tube with oxygen plasma can be performed as follows. For example, a plasma apparatus (trade name: “FEMTO”, manufactured by Diener electronic) is used. By placing a drip tube in the chamber of this plasma apparatus and irradiating it with oxygen plasma at a pressure of 0.2 to 0.3 mbar for 5 minutes, a plasma-modified portion can be formed.

  In order to confirm whether or not the plasma reforming portion is appropriately modified by oxygen plasma, it is only necessary to drop a droplet on the plasma-treated inner wall surface. If it is appropriately modified by oxygen plasma, the dropped droplets are spherical and do not stay in place but spread out.

  In the present invention, the plasma-modified portion is not limited to being formed by irradiating oxygen plasma, but may be formed by other types of plasma. Further, instead of using plasma, an inner wall surface may be primed using a primer instead, and the primer may be coated with the coating agent. The primer is a substance that is directly applied to the inner wall surface and serves as a base for coating the coating agent. As an example of the primer, a primer (trade name: “AQUAMICA NL120A”, manufactured by Merck Performance Materials LLC) can be used.

  Here, it is also preferable that the inner wall surface of the drip tube has a silica layer, and the coating agent is applied on the silica layer. Specifically, instead of forming the plasma modification portion by the plasma treatment described above, the silica wall is formed on the inner wall surface of the drip tube by covering the inner wall surface of the drip tube with silica. By applying the coating agent on this silica layer, the inner wall surface of the drip tube can be provided with sufficient wettability to give the droplet a contact angle of 10 degrees or less.

  This silica layer is also preferably formed on all or part of the inner wall surface of the drip tube. The silica layer does not need to be formed at least in the range of the inner wall surface that is not affected by the photo interrupter, which is a configuration added to the infusion set described later.

  The treatment of the inner wall surface of the drip tube with silica can be performed as follows. For example, a silica layer can be formed on the inner wall surface of the drip tube by applying a solution obtained by diluting Aquamica NL120A with dibutyl ether to the inner wall surface of the drip tube and drying the solution.

  In order to confirm whether or not the inner wall surface of the drip tube is properly coated with the silica layer, a droplet may be dropped on the coated inner wall surface. If the silica layer is appropriately formed, the dropped liquid droplet is spherical and does not stay in place, but spreads wet.

<Infusion set>
The infusion set according to the present invention includes the above-described infusion tube and a nozzle that is inserted from above the infusion tube and has a hydrophobic infusion port at the lower end for dropping the droplet into the inside of the infusion tube. In the present embodiment, as an example, an infusion set is constituted by the drip tube and a nozzle made entirely of a hydrophobic resin as well as the drip port at the lower end. As the resin constituting the nozzle, it is preferable to use a resin in which the size of the droplet that grows at the lower end of the drip inlet is stable without the droplet spreading wet.

  Here, in this specification, it is assumed that the resin constituting the nozzle is “hydrophobic” when the droplet that is growing at the instillation port of the nozzle does not wet around the nozzle. Examples of the resin constituting the nozzle include polypropylene (PP), polyethylene (PE), and ethylene-propylene copolymer. Further, since the droplet inlet of the nozzle is hydrophobic, the droplet that is growing at the nozzle does not get wet around the nozzle, and the measurement of the size of the droplet by the two-dimensional image sensor may be hindered. This is preferable because there is no inconvenience.

  Such an infusion set is used in the following form. First, an infusion tube is disposed in the middle of an infusion line from an infusion bag suspended on a stand at a position higher than the human body to the human body. Moreover, the upper end of a nozzle is connected to the tube which comprises the infusion line by this infusion bag side. The inside of the nozzle communicates with the inside of the infusion tube, and at the lower end thereof, an infusion port for dropping the infusion droplet into the infusion tube is formed. In the lower part of the drip tube, a liquid reservoir is generally formed in which an infusion solution (chemical solution) is accumulated. And the lower end of a drip tube is connected to the tube which comprises the infusion line by the side of a human body.

  The infusion in the infusion bag flows downward in the tube by gravity and reaches the inside of the nozzle. When the droplet of the infusion grows at a drip port at the lower end of the nozzle and reaches a predetermined size, the droplet drops into the drip tube and accumulates in a liquid reservoir below it. Thereafter, the infusion flows through the tube constituting the infusion line on the human body side and reaches the human body.

  In the infusion set according to the present invention, one or more light-emitting elements that emit light and one or more light-receiving elements that receive this light at positions opposed or substantially opposed to each other across the drip tube below the drip port of the nozzle. It is possible to provide a photo interrupter that arranges elements and counts the number of drops. Furthermore, an imaging unit (two-dimensional image sensor) that captures a growing droplet at the lower end of the nozzle and an illumination unit that illuminates the droplet may be arranged at positions facing or substantially facing each other across the infusion tube. it can.

  An example of the light emitting element is an infrared light emitting diode (infrared LED). As the light receiving element, a phototransistor (photosensor) as a photodetector can be exemplified. As the imaging unit, a CMOS image sensor or a CCD image sensor can be exemplified. As an illumination part, the surface emitting infrared illumination which combined infrared LED and the light-guide plate can be illustrated.

  In the infusion set, even if a droplet dropped from the drip port of the nozzle bounces off the liquid reservoir and adheres to the inner wall surface of the drip tube, for example, the inner wall surface is covered with the coating agent. It spreads along the inner wall without staying in place, giving a contact angle of 10 degrees or less to the inner wall. Thereby, the visibility inside an infusion tube is maintained. For this reason, there is no problem in counting the number of droplets dropped by the photo interrupter. In addition, there is no problem in measuring the volume of the droplet using the two-dimensional image sensor. Therefore, according to the configuration of the present invention, the number of droplets dropped can be accurately counted, and the volume of the droplets can be appropriately measured. For example, the amount of liquid per drip can be appropriately set. Can be controlled.

  EXAMPLES Hereinafter, although an Example is given and this invention is demonstrated in detail, this invention is not limited to these.

<Example 1>
In Example 1, eight kinds of coating agents were respectively coated on the outer wall surface of the drip tube, and the contact angle given when droplets (water) were adhered to the outer wall surface was measured. Further, the contact angle given when the liquid droplet (water) was adhered to the outer wall surface of the drip tube not covered with the coating agent was also measured.

  In Example 1, since the material is common to the inner wall surface and the outer wall surface of the drip tube, the contact angle of water measured on the outer wall surface is equivalent to the contact angle of water measured on the inner wall surface. It was considered a thing.

<Preparation of drip tube>
Eight infusion tubes made of a substantially cylindrical ethylene-propylene copolymer having a diameter of 15 mm and a total length of 50 mm were prepared. Seven of these are each coated with various coating agents, as will be described later. The remaining one is not covered with the coating agent as described later.

<Plasma reforming>
First, on the outer wall surface of the seven drip cylinders excluding the drip cylinders not covered with the coating agent, a pressure of 0.2 to 0.3 mbar is applied by a plasma apparatus (trade name: “FEMTO”, manufactured by Diener electronic). The plasma treatment with oxygen plasma was performed for 5 minutes.

  Next, each of the 7 drip tubes subjected to the above plasma treatment was coated with 7 types of coating agent preparation liquids, and then dried at 70 ° C. for 10 minutes, so that the outside of each drip tube was removed. The wall surface was covered with a coating agent. Hereinafter, these seven drip cylinders are referred to as Sample 1 to Sample 7 for each type of coating agent. The above-mentioned preparation liquid is a liquid prepared by diluting and dissolving the coating agent in water or ethanol.

<Measurement of contact angle>
A total of eight drip cylinders of Sample 1 to Sample 7 and drip cylinders (referred to as Sample 8) that were not coated with the coating agent were arranged in a plane, and water was dropped from the tip of the injection needle onto each outer wall surface. Their contact angles were measured.

  The contact angle was measured on the first day of the measurement date and after 15 days from the measurement date. During the period, 8 drip cylinders were stored at 70 ° C. for an accelerated test.

  In Table 1, the name of the coating agent used in Sample 1 to Sample 8, and the first day of the measurement date, and 15 days after the measurement date (represented as “the first day of measurement day” and “after 15 days” in the table), respectively) The measured contact angle is shown.

<Results and discussion>
As is apparent from Table 1, excellent wettability was shown in the drip tubes of Samples 1 to 7. Moreover, since it was an acceleration test, it turned out that the drip tube of the samples 1-7 is maintained favorable for a long time. In Table 1, 10 or less in the column of contact angle (°) means that when water was dropped onto the outer wall surface of the drip tube with an injection needle, it immediately wetted and spread on the outer wall surface, and the contact angle could not be measured. This indicates that it was determined that a contact angle of 10 degrees or less was given.

  In Table 1, 90 or more in the column of contact angle (°) means that when water was dropped onto the outer wall surface of the drip tube with an injection needle, it remained on the outer wall surface while maintaining the spherical shape of the droplet. Indicates that it was determined that a contact angle greater than 1 degree was given.

<Example 2>
In Example 2, the effect of coating the inner wall surface of the drip tube with a coating agent was examined using the infusion set having the configuration shown in FIGS. 1A and 1B.

  Specifically, as shown in FIG. 1A and FIG. 1B, an infusion set is inserted into a drip tube 1 whose entire inner wall surface is coated with a coating agent to be described later, and the drip tube 1 from above, and a droplet is A drip port 21 for dropping into the inside of the drip tube 1 is provided at the lower end, and the nozzle 2 is entirely made of an ethylene-propylene copolymer as a raw material.

  Further, below the infusion port 21, one light emitting diode 31 that irradiates light and five detection photosensors 32 that receive the light are disposed at positions opposed or substantially opposed to each other with the infusion tube 1 interposed therebetween. The photo interrupter 3 provided is arranged. This photo-interrupter 3 detects the liquid level of the liquid pool formed in the lower part of the drip tube below the detection photosensor 32 by detecting the light from the light emitting diode 31. A photosensor 33 is also provided.

  Here, the photointerrupter 3 is blocked from the voltage from the detection photosensor 32 by being blocked by a drop of light to be detected, that is, the light from the light emitting diode 31 does not reach the detection photosensor 32. (Also referred to as “sensor voltage”) is not output. Thereby, the dropped droplet can be detected. There are five detection photosensors 32 because, when the drip tube is tilted or the like, even if the path of the droplet dropped from the drip port 21 of the nozzle 2 is different, the droplet dropped by any one of the five. It is for catching. However, at this time, if a droplet adheres to the inner wall surface of the drip tube 1 and stays there, the droplet becomes a lens and refracts the light of the light emitting diode 31, so that the dropped droplet is detected by a photosensor for detection. 32 may not be detected correctly.

  Further, in FIG. 1B, since the liquid level of the liquid pool is high, the light of the light emitting diode 31 (shown by a broken line in the figure) is refracted at the gas-liquid interface and does not reach the liquid level height detection photosensor 33. However, when the liquid level in the liquid pool is sufficiently low, the light from the light emitting diode 31 reaches the photosensor 33 for detecting the liquid level. At this time, if a droplet adheres to the inner wall surface of the drip tube 1 and stays there, the droplet becomes a lens and refracts the light of the light emitting diode 31. There is a possibility that the liquid level cannot be detected correctly.

  As shown in FIGS. 1A and 1B, in the photo interrupter 3, the optical path from the light emitting diode 31 to each detection sensor (detection photosensor 32, liquid level detection photosensor 33) is limited to a narrow path. Has been. This is to eliminate the influence of disturbance light such as sunlight as much as possible. However, when a droplet adheres to the inner wall surface of the drip tube 1 and stays there, the droplet acts as a lens to refract the light from the light emitting diode 31, so that the light from the light emitting diode 31 to each detection sensor Tend to be hard to reach correctly.

  Thus, since it is necessary to take measures to prevent droplets from adhering to the inner wall surface of the drip tube 1 and staying there, the inner wall surface of the drip tube 1 can be coated with a coating agent in the second embodiment. The effect was investigated.

<Preparation of the drip tube constituting the infusion set>
In Example 2, an infusion set constituting the infusion set was made of a substantially cylindrical ethylene-propylene copolymer having a diameter of 15 mm and a total length of 50 mm. First, with respect to the drip tube constituting the infusion set according to the example, oxygen plasma was reduced to 5 at a pressure of 0.2 to 0.3 mbar using the above plasma device (trade name: “FEMTO”, manufactured by Diener electronic). Irradiation was performed under conditions of minutes, and plasma treatment was performed. By this operation, the plasma modified portion was formed on the entire inner wall surface.

  Thereafter, a preparation solution of a coating agent (trade name “LAMBIC-400EP”, manufactured by Osaka Organic Chemical Industry Co., Ltd.) was applied to the drip tube having the plasma-modified portion, followed by drying at 70 ° C. for 10 minutes. As a result, the plasma-modified portion was coated with a thickness of 1 μm or less, and the droplets adhering to the inner wall surface gave a contact angle of 10 degrees or less so that sufficient wettability was exhibited. For such an example, an infusion tube that was not coated with any coating agent was prepared as an infusion tube constituting an infusion set according to a comparative example.

  Then, a liquid reservoir is formed in the lower part of the infusion tube of the infusion set of the example and the comparative example, and droplets are intermittently dropped into the liquid reservoir, and the inner surface of the infusion tube is bounced back by rebounding. A droplet was adhered to the surface. However, in the drip tube of the embodiment, the droplet (water droplet) quickly wets and spreads, so that the droplet does not remain on the inner wall surface. In this example and comparative example, the value of the sensor voltage (V) output from the five detection photosensors (CH1 to CH5) was recorded. The result is shown in FIG. In addition, in the drip tube of the comparative example, it was recognized that the droplets adhering to the inner wall surface remained in a spherical shape while recording the sensor voltage.

<Results and discussion>
As apparent from FIG. 2, in the drip tube of the comparative example that is not coated with the coating agent, the five detection photosensors [channel (CH) 1] constituting the photointerrupter due to the influence of the droplets adhering to the inner wall surface. The variation of the sensor voltage value output by [5 to 5] has increased. Specifically, the droplets attached to the inner wall surface act as a lens and refract the light from the light emitting diode, so that the outputs of CH1 and CH4 out of five detection photosensors showed abnormal values. . That is, in the comparative example, since the droplets are present on the inner wall surface, it may be difficult to accurately count the number of drops.

  In contrast, in the example, the output values of the five photosensors for detection were stable without greatly differing. More specifically, CH3, which is a photosensor facing in front of the light emitting diode, showed the maximum output value. That is, in the drip tube of the embodiment, it is understood that there is no liquid droplet on the inner wall surface of the area where the photo interrupter acts, and the output of the detection photosensor is stabilized, so that the accurate number of drops can be counted.

  Here, in Examples 1 and 2 described above, a drip tube using an ethylene-propylene copolymer as an example has been described. However, as described above, the drip tube material is a hydrophobic resin, and ethylene-propylene. In addition to the copolymer, polyethylene (PE), polypropylene (PP), or the like can be used. Thereby, it can be ensured that it is transparent to visible light and infrared light together with the strength required for the drip tube.

  As described above, the embodiments and examples of the present invention have been described, but it is also planned from the beginning that the configurations of the above-described embodiments and examples may be appropriately combined and variously modified.

  The embodiments and examples disclosed herein are illustrative in all aspects and should not be construed as being restrictive. The scope of the present invention is shown not by the above-described embodiments and examples but by the scope of claims, and is intended to include meanings equivalent to the scope of claims and all modifications within the scope.

  1 drip tube, 2 nozzles, 21 drip port, 3 photo interrupter, 31 light emitting diode, 32 photosensor for detection, 33 photosensor for liquid level detection.

Claims (6)

  A drip tube having an inner wall surface made of a transparent resin and coated with a coating agent, and a droplet attached to the inner wall surface gives a contact angle of 10 degrees or less.   The drip tube according to claim 1, wherein the resin includes any one of polypropylene, polyethylene, and an ethylene-propylene copolymer.   The coating agent includes polyoxyethylene sorbitan monooleate, polymer brush containing carboxybetaine monomer, polyoxyethylene (10) octylphenyl ether, sodium di (2-ethylhexyl) sulfosuccinate, sorbitan monolaurate and 3-[( The infusion tube according to claim 1 or 2, comprising one or more selected from the group consisting of (3-colamidopropyl) dimethylammonio] -1-propanesulfonate. The inner wall surface has a plasma modified portion,
The drip tube according to claim 1, wherein the coating agent is applied to the plasma modification portion. The inner wall surface has a silica layer,
The drip tube according to any one of claims 1 to 3, wherein the coating agent is applied on the silica layer. An infusion tube according to any one of claims 1 to 5;
An infusion set comprising: a nozzle that is inserted from above the drip tube and has a hydrophobic drip port at the lower end for dropping the droplet into the drip tube.

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