JP7119328B2 - Chamber for pressure measurement - Google Patents

Description

The present disclosure relates to pressure measurement chambers.

In an extracorporeal blood circulation circuit such as a dialysis circuit, pressure measurement in the circulation line is indispensable. For example, in artificial dialysis, if the blood pressure deviates from the set pressure, the blood cells will be damaged.

For pressure measurement in an extracorporeal circulation circuit, the chamber is divided into two parts, a blood side chamber in which blood flows and an air side chamber filled with air, and the pressure is measured in the air side chamber. A chamber for pressure measurement is known (see, for example, Patent Document 1).

JP-A-61-143069

However, such pressure measurement chambers have the following problems. When the flexible membrane contacts and seals against the wall of the air side housing, air becomes trapped between the flexible membrane and the wall, creating an isolated air cell that is not vented to the pressure sensing port. The formation of isolated air cells reduces the pressure measurement range.

An object of the present disclosure is to reduce the formation of pressure sensing ports and isolated, unventilated air cells.

A first aspect of the pressure measuring chamber of the present disclosure comprises a housing having a cavity therein and a flexible membrane separating the cavity into a blood side chamber and an air side chamber, the side of the housing contacting the air side chamber being , a pressure-sensing port open to the interior surface and a step formed on the interior surface, the step forming a vent path between the housing and the flexible membrane.

According to one aspect of the pressure chamber of the present disclosure, a vent path can be secured even when the flexible membrane contacts the inner surface of the housing in the air side chamber, so that the pressure sensing port and the non-vented air cell are connected. can be made less likely to form. This makes it possible to make it difficult for the pressure measurement range to fluctuate.

A second aspect of the pressure measuring chamber of the present disclosure comprises a housing having a cavity therein and a flexible membrane separating the cavity into a blood side chamber and an air side chamber, the side of the housing contacting the air side chamber being , the flexible membrane has a pressure detection port open to the inner surface, and the side of the flexible membrane that contacts the air-side chamber has a step formed on the outer surface, the step forming an air passage between the housing and the flexible membrane. to form

By forming the stepped portion on the flexible film, the ventilation path can be formed easily and with a high degree of freedom.

In the first aspect and the second aspect of the pressure measurement chamber, it is preferable that the air passage is connected to the pressure detection port. With such a configuration, an air passage leading to the pressure detection port is ensured, and the risk of the pressure detection port being isolated from other regions in the chamber and blocked can be reduced.

In the first and second aspects of the pressure-measuring chamber, the flexible membrane is a dome-shaped membrane having a major axis and a minor axis, and the vent passage can extend longitudinally. By adopting such a configuration, it becomes easy to secure a ventilation path even when only one side of the flexible film is largely displaced in the longitudinal direction.

A third aspect of the pressure measuring chamber of the present disclosure includes a housing having a cavity therein, a flexible membrane separating the cavity into a blood side chamber and an air side chamber, and a housing and a flexible membrane in the air side chamber. and an air passage forming member that has a step and forms an air passage with the flexible membrane. have. By providing the air passage forming member provided between the housing and the flexible membrane, it is possible to suppress the occurrence of isolated air cells.

A fourth aspect of the pressure measuring chamber of the present disclosure includes a housing having a cavity therein, a flexible membrane separating the cavity into a blood side chamber and an air side chamber, and a housing and a flexible membrane in the air side chamber. and an air passage forming member made of an air-permeable material. It is possible to suppress the occurrence of isolated air cells by providing the air passage forming member made of a material having air permeability.

A fifth aspect of the pressure measuring chamber of the present disclosure comprises a housing having a cavity therein and a flexible membrane separating the cavity into a blood side chamber and an air side chamber, the side of the housing contacting the air side chamber being , has a pressure detection port that opens to the inner surface, and has an air passage between the housing and the flexible membrane in the air side chamber, through which gas passes when the flexible membrane contacts the housing. In the pressure measurement chamber of the fourth aspect, an air passage is formed through which gas passes when the flexible membrane contacts the housing, so that isolated air cells are less likely to occur.

According to the pressure measurement chamber of the present disclosure, pressure detection ports and unventilated air cells are less likely to occur.

FIG. 3 is an exploded perspective view showing the pressure measurement chamber according to the embodiment; FIG. 2 is a cross-sectional view taken along line II-II of FIG. 1; It is a top view which shows a 2nd frame. It is a top view which shows the modification of a 2nd frame. It is a sectional view showing a modification of the 2nd frame. FIG. 11 is a plan view showing a modification of the arrangement of air passage forming ribs; FIG. 11 is a plan view showing a modification of the arrangement of air passage forming ribs; FIG. 11 is an exploded perspective view showing a modification using an air passage forming member; FIG. 11 is an exploded perspective view showing a modification using a porous airway forming member;

As shown in FIGS. 1 to 3, the pressure measurement chamber of this embodiment includes a housing 101 having a cavity therein, and a flexible membrane 102 dividing the cavity into a blood side chamber 105 and an air side chamber 106. ing. A pressure detection port 119 that opens to the inner surface is provided on the side of the housing 101 that contacts the air side chamber 106 . In addition, when a part of the flexible membrane 102 contacts the inner surface of the housing 101 in the air side chamber 106, an air passage is formed to ensure ventilation at the contact point of the flexible membrane 102. It has ventilation path forming ribs 151 .

Although the pressure measurement chamber of this embodiment can be used in any orientation, the following describes a state in which the blood side chamber 105 is on the bottom side and the air side chamber 106 is on the top side.

The housing 101 is formed by a first frame body 111 and a second frame body 112 that face each other and are connected so as to provide a cavity inside. The first frame body 111 is provided at positions opposite to each other in the longitudinal direction of the first recess forming surface 113 forming the cavity and the first flange portion 114 surrounding the first recess forming surface 113 . It has a blood inlet 115 and a blood outlet 116 . The second frame 112 has a second recessed surface 117 forming a cavity together with the first recessed surface 113 and a second flange 118 surrounding the second recessed surface 117. . A pressure detection port 119 is provided so as to protrude from the outer surface of the second recess, and the pressure detection port 119 opens to the inner surface of the second recess forming surface 117 . In addition, the inner surface of the second concave portion forming surface 117 is provided with an air passage forming rib 151 projecting inward.

The flexible membrane 102 includes a dome-shaped membrane main body 121 and ribs 122 provided so as to surround the outer edge of the membrane main body 121 and sandwiched between a first flange portion 114 and a second flange portion 118 . have. By sandwiching the flexible membrane 102 between the first frame 111 and the second frame 112, the cavity is separated into two parts, and the first frame 111 side is the blood side through which blood flows. A chamber 105 is formed, and the second frame 112 side becomes an air-side chamber 106 filled with air. Pressure changes in blood side chamber 105 are transmitted to air side chamber 106 via membrane body 121 . A pressure change in the air side chamber 106 can be detected by a pressure sensor or the like connected to the pressure detection port 119 . It is preferable that a tube having a connector at its end be fixed to the pressure detection port 119, because the handleability of the pressure chamber is improved.

In this embodiment, the flexible membrane 102 has a membrane body 121 having a major axis and a minor axis, and has a three-dimensional elliptical dome shape. When the pressure in blood side chamber 105 increases, flexible membrane 102 bulges toward air side chamber 106 . When the flexible membrane 102 is maximally displaced toward the side of the housing 101 in contact with the air side chamber (the second concave portion forming surface 117), there is as much space between the flexible membrane 102 and the inner surface of the housing 101 as possible. It is formed so as to have approximately the same size as the second concave portion forming surface 117 so as not to create a space. Since the flexible membrane 102 is displaced in response to continuously varying blood pressure, it is difficult to reliably control the movement of the flexible membrane 102, and a portion of the flexible membrane 102 is recessed into the second recess. It may come into contact with the inner surface of forming surface 117 . Although the housing of the air side chamber 106 can be designed to be excessively large so that the flexible membrane 102 does not come into contact with the inner surface of the housing 101, the volume of the air side chamber 106 is increased accordingly. In this case, the amount of variation required for the flexible membrane 102 required to measure a predetermined range also increases, so the flexible membrane 102 also has to be made larger, resulting in an increase in the overall size of the pressure measurement chamber. put away.

If the entire second recessed surface 117 is smooth, the flexible membrane 102 may partially come into close contact with the housing, blocking air flow to the pressure sensing port 119 and forming isolated air cells. . The formation of isolated air cells leads to a reduction in pressure measurement range. In addition, the flexible film 102 may adhere to the inner surface of the housing 101 in the vicinity of the pressure detection port 119 , and the pressure detection port 119 may be isolated from other areas in the air side chamber 106 and blocked.

On the other hand, the pressure-measuring chamber of this embodiment has an air passage-forming rib 151 on the second concave portion forming surface 117 . Therefore, even when the flexible membrane 102 is in contact with the inner surface of the housing 101 , an air passage is formed between the flexible membrane 102 and the inner surface of the housing 101 . Therefore, even if the flexible membrane 102 is in contact with the inner surface of the housing 101, air can move beyond the portion where the flexible membrane 102 is in contact with the inner surface of the housing 101 through the ventilation path, forming an isolated air cell. hard to be In addition, the volume of the air side chamber 106 can be minimized, and the provision of the ventilation path forming ribs 151 is also advantageous from the viewpoint of downsizing the device.

The air passage forming rib 151 may be formed in any manner as long as it can form an air passage. For example, as shown in FIG. It can extend radially in a plurality of directions from the central portion. By providing the ventilation path forming ribs 151 radially, even if the flexible film 102 comes into contact with any position on the second concave portion forming surface 117, the flexible film 102 is prevented from coming into close contact with each other, thereby securing the ventilation path. easier to do. Moreover, even if the flexible film 102 contacts at a plurality of points, the air passage to the pressure detection port 119 can be secured.

FIG. 1 shows an example in which the linearly extending air passage forming ribs 151 extend in eight directions with a shift of 45 degrees. Well, for example, they can be extended in two directions with a 180 degree shift. However, the more directions the ventilation path forming ribs 151 extend, the higher the effect of suppressing the formation of air cells in which air is trapped. Considering the size and molding accuracy of the pressure measuring chamber, the maximum is about 48 directions. Considering ease of molding, 24 directions or less are preferable, and 16 directions or less are more preferable. Note that the ribs may be straight or curved.

When the ventilation path forming ribs 151 are provided radially, providing them at equal intervals enhances the effect of suppressing the formation of air cells, but they do not have to be provided at equal intervals.

Although the length of the ventilation path forming rib 151 is not particularly limited, it is preferable to provide it as far below the second concave portion forming surface 117 as possible.

The height of the ventilation path forming rib 151 is preferably 0.1 mm or more, more preferably 0.2 mm or more from the viewpoint of securing the ventilation path, and preferably 0.5 mm or less from the viewpoint of facilitating formation. More preferably, it is 0.4 mm or less. The width of the ventilation path forming rib 151 is preferably 0.1 mm or more, more preferably 0.2 mm or more, from the viewpoint of securing the ventilation path, and preferably 0.7 mm or less, more preferably 0.2 mm or more, from the viewpoint of facilitating formation. Preferably, it is 0.5 mm or less.

FIG. 1 shows an example in which a recess 155 formed by a gate at the time of molding exists in the central portion of the second recessed portion forming surface 117, and the vent path forming ribs 151 are independently provided around the recess. Concave portions and convex portions generated by gates, ejector pins, etc. during molding can also be used to form the air passages together with the air passage forming ribs 151 .

As shown in FIG. 4, if there is no gate at this position, the vent path forming rib 151 may be connected at the center. In addition, although an example in which the ventilation path forming ribs 151 are arranged radially from the central portion of the second recessed portion forming surface 117 has been shown, they may be arranged radially from any position in the air side chamber 106 without being limited to the central portion. can be done. Also, a pressure detection port can be formed in the central portion.

It is preferable that one of the air passage forming ribs 151 radially provided reaches the opening region 119 a of the pressure detection port 119 . Even if the air passage forming rib 151 does not reach the opening edge 119b of the pressure detection port 119, if it reaches the opening region 119a, the pressure detection port 119 is less likely to be blocked by the flexible film 102, and pressure detection is performed. Port 119 and the potential for unvented air cells can be greatly reduced. The opening area 119 a is preferably about three times, more preferably about twice the diameter of the pressure detection port 119 . However, the ventilation path forming rib 151 may reach the opening edge 119 b of the pressure detection port 119 .

Further, a point-like projection 154 may be provided between the ventilation path forming rib 151 and the opening of the pressure detection port 119 . By providing the convex portion 154 near the opening, it is possible to prevent the pressure detection port 119 from being blocked by the flexible film 102 . The convex portion 154 may be provided in the opening region 119 a , but is preferably provided on an extension line of the ventilation path forming rib 151 . In addition, the pressure detection port 119 can be made more difficult to be blocked by increasing the height of the protrusion from the air passage forming rib 151 . At least one protrusion 154 may be provided, but it is preferable to provide a plurality of protrusions 154 around the pressure detection port 119 in order to prevent the pressure detection port 119 from being blocked.

The ventilation path forming rib 151 may be formed by any method. For example, the second frame 112 may be formed using a mold designed to form projections on the second recess formation surface 117 . Further, after forming the second frame 112 having a smooth second concave portion forming surface 117, another member is fixed between the housing and the flexible film, and the vicinity of the second concave portion forming surface 117 is fixed. A vent path forming rib 151 can also be formed in the .

In the air-side chamber 106, an example in which the air passage forming ribs 151 are provided on the inner surface of the housing 101 is shown, but it is sufficient if the inner surface of the housing 101 is provided with a step that allows formation of an air passage. For example, as shown in FIG. 5, in place of the vent path forming rib 151, a recessed vent path forming groove 152 can be provided in the second concave portion forming surface 117. As shown in FIG. When the vent path forming grooves 152 are provided, all the vent path forming grooves 152 are connected to each other and reach the opening edge 119b of the pressure detecting port 119 in order to form the vent path leading to the pressure detecting port 119. is preferred. If the vent path forming groove 152 reaches the opening edge 119b of the pressure detection port 119, even if the flexible film is in close contact with the wall surface near the opening of the pressure detection port 119, the vent path to the pressure detection port is secured. possible and preferred. In addition, when providing the convex part 154 in the opening area|region 119a, the ventilation path formation groove|channel 152 should just reach the opening area|region 119a.

The depth of the ventilation path forming groove 152 is preferably 0.1 mm or more, more preferably 0.2 mm or more from the viewpoint of securing the ventilation path, and preferably 0.5 mm or less from the viewpoint of facilitating formation. More preferably, it is 0.4 mm or less. From the viewpoint of securing the ventilation path, the width of the ventilation path forming groove 152 is preferably 0.1 mm or more, more preferably 0.2 mm or more when the ventilation path forming groove 152 is linear, to facilitate formation. From the viewpoint, it is preferably 0.7 mm or less, more preferably 0.5 mm or less. The air passage forming groove 152 may have any shape such as a point shape, a linear shape, or a planar shape. Alternatively, the opening region 119a may be formed as a planar air passage forming groove having a dome-shaped groove.

FIG. 4 shows an example in which the air passage forming ribs 151 are provided radially extending in a plurality of directions from one location on the second recessed portion forming surface 117. A curved ventilation path forming rib 151A can also be provided so as to draw a loop from the opening region 119a. Even when the curved ventilation path forming ribs 151A are provided, the flexible membrane 102 is prevented from coming into contact with the flexible membrane 102 at any position of the housing 101, thereby securing the ventilation path. becomes easier. Moreover, even if the flexible film 102 contacts at a plurality of points, the air passage to the pressure detection port 119 can be secured.

If the vent path forming rib 151A is provided so as to draw a loop, it is preferable to further add the vent path forming rib 151B that divides the loop into a plurality of parts in order to ensure the formation of the vent path. It is preferable that the ventilation path forming rib 151B that divides the loop reaches the opening region 119a. By doing so, it becomes easier to secure the ventilation path. The air passage forming rib 151B that divides the loop may be integrated with or separate from the loop-shaped air passage forming rib 151A. Moreover, it is also possible to provide ventilation path forming ribs so that the loops are multiplexed. If the loops are multiplexed, all loops can start from open region 119a. Moreover, when the ventilation path forming ribs 151B that divide the loop are provided, they can be provided concentrically.

Instead of the loop shape, as in the modification shown in FIG. 7, a curved air passage forming rib 151C may be provided in a spiral shape with the opening region 119a as one end. The spiral ventilation path forming rib 151C also prevents the flexible film 102 from coming into close contact with the flexible membrane 102 at any position on the second concave portion forming surface 117, thereby securing the ventilation path. becomes easier. Moreover, even if the flexible film 102 contacts at a plurality of points, the air passage to the pressure detection port 119 can be secured. In addition to the spiral air passage forming rib 151C, air passage forming ribs may be combined so as to divide the spiral.

In these modified examples as well, the projections 154 can be provided in the opening regions 119a. Also, grooves can be used instead of ribs. Furthermore, the air passage-forming ribs and air passage-forming grooves of the embodiment and modifications can be combined with each other. For example, a loop-shaped air passage-forming rib and radial air passage-forming ribs can be provided. Also, the ventilation path forming rib and the ventilation path forming groove can be combined.

Although an example in which the steps for forming the ventilation paths are provided on the inner surface of the housing 111 is shown, they may be provided on the side of the flexible membrane 102 in contact with the air side chamber 106 . Moreover, both the housing 111 and the flexible membrane 102 can be provided with steps. In this case, if the steps provided on the housing 111 and the steps provided on the flexible membrane 102 intersect each other, it is possible to make it more difficult for air cells to occur.

Further, in the air side chamber 106, a separate air passage forming member 160 may be sandwiched between the inner surface of the housing 101 and the flexible membrane 102 and the air passage forming member 160. FIG. For example, in the modification shown in FIG. 8, an air passage forming member 160 having an X-shaped air passage forming rib is sandwiched between the second frame 112 and the flexible film 102 . With such a configuration, even if a step is formed in the vicinity of the second concave portion forming surface 117 and the flexible membrane 102 bulges unevenly toward the air side chamber 106, the flexible membrane will not 102 can be kept out of contact with the inner surface of the housing 101 to ensure a ventilation path. Since the air passage forming member 160 is independent of the housing 101 and the flexible membrane 102, it is possible to eliminate the need to increase the wall thickness of the housing. Moreover, it is preferable that the air passage forming member is made of a material that is so hard that it hardly deforms when pressed by the flexible film 102 .

Furthermore, as in the modification shown in FIG. 9, a dome-shaped air passage forming member 162 made of an air permeable material may be provided. Since the air passage forming member 162 has air permeability, even if the flexible membrane 102 swells toward the air side chamber 106 and comes into contact with the air passage forming member 162, the housing 101 and the flexible membrane 102 do not. A ventilation path can be secured between The air passage forming member 162 only needs to have air permeability, and can be made of, for example, a porous sintered body or a porous resin material such as sponge or mesh. It is preferable that the air passage forming member 162 have hardness to the extent that it is not crushed when pressed by the flexible film 102 . In addition, the outer surface of the air passage forming member 162 may be uneven so that a gap is formed between the inner surface of the housing 101 and the outer surface of the air passage forming member 162 .

In the air side chamber 106, when a part of the flexible membrane 102 is in contact with the inner surface of the housing 101, a vent path can be formed through which the gas can move beyond the contact part of the flexible membrane 102. However, as long as an air passage can be formed between the housing 101 and the flexible membrane 102, any configuration is possible without being limited to these configurations.

In the embodiment and modified example, the cavity formed by the first recessed surface 113 and the second recessed surface 117 has a planar elliptical shape and has a major axis and a minor axis. By making the planar shape of the cavity into a shape having a long axis, it is possible to make it difficult for blood to stagnate. The planar shape having a long axis and a short axis is not particularly limited, but a shape without corners is preferable from the viewpoint of suppressing the formation of thrombi. The shape is not limited to a shape having a long axis and a short axis, and an isotropic shape such as a circular shape can also be used.

When the cavity has a planar shape with a longitudinal axis, blood inlet 115 and blood outlet 116 are preferably provided at positions opposite to each other in the longitudinal direction of the cavity. As a result, the blood that has flowed in from the blood inlet 115 flows in almost one direction toward the blood outlet 116 in the blood side chamber 105, and is less likely to stagnate than in the blood side chamber 105, which has a flat circular shape, thereby preventing thrombus. It is possible to make it less likely to occur. However, the blood inlet 115 and the blood outlet 116 can also be provided at positions where blood flows in a U-shape or L-shape in the cavity.

If the cavity has a planar shape with a long axis and a short axis, and the membrane body 121 has a dome shape with a long axis and a short axis, a phenomenon in which only one side in the long axis direction is displaced upward easily occurs. For this reason, if the second concave portion forming surface 117 is provided with a step extending in the longitudinal direction, it is possible to make it more difficult for isolated air cells to occur.

In the present embodiment and modified example, the example of providing the flexible membrane having the dome-shaped membrane main body 121 functioning as a diaphragm has been shown. Such a dome-shaped membrane main body 121 has no irregularities, corners, or straight portions on its inner surface, and is formed entirely of curved surfaces. However, the flexible membrane only needs to be able to partition the interior of the chamber into two parts, and can be a tubular flexible membrane, for example, as described in WO2016/068213. However, by forming the membrane main body 121 into a dome shape, there is an advantage that the pressure measurement chamber can be made smaller than a cylindrical flexible membrane.

The flexible film 102 can be made of a flexible material such as silicone rubber, natural rubber, butyl rubber, isoprene rubber, butadiene rubber, and styrene-butadiene rubber, polyurethane, polyester, and the like. various thermoplastic elastomers such as elastomers, polyamides, olefins, and styrenes, as well as polyvinyl chloride, polyethylene, polypropylene, ethylene-propylene copolymers, ethylene-vinyl acetate copolymers, cross-linked ethylene-vinyl acetate copolymers Polyolefins such as coalesced, polyesters such as polyethylene terephthalate, polyurethanes, and soft resins such as polyamides can be used.

The material of the first frame 111 and the second frame 112 is not particularly limited as long as it has a certain degree of rigidity. For example, polyester-based resins such as polycarbonate, polyethylene terephthalate, glycol-modified polyethylene terephthalate, and glycol-modified polyester, olefin-based resins such as polyethylene and polypropylene, vinyl chloride-based resins, polystyrene resins, acrylic resins, acrylonitrile-styrene copolymer resins, Polyethersulfone resin, polysulfone resin, and the like can be used. Only one of the first frame 111 and the second frame 112 may be transparent, or a transparent window may be provided instead of making the whole transparent. Also, the first frame 111 and the second frame 112 may be opaque.

Blood circuit tubes are connected to blood inlet 115 and blood outlet 116 . Also, the pressure detection port 119 may be connected directly to the port of the pressure measurement device, or a tube is connected to the pressure detection port 119 and the connector at the end of the tube is connected to the port of the pressure measurement device. It may be a specification such as The pressure measuring device may be one incorporated in a hemodialysis device or the like, or may be a stand-alone device.

The pressure measurement chamber of this embodiment can be connected to an extracorporeal blood circulation circuit for artificial dialysis, heart-lung machine, or the like to measure blood pressure.

The pressure measurement chamber of the present disclosure is useful as a pressure measurement chamber connected to a blood circuit or the like.

101 housing 102 flexible membrane 105 blood side chamber 106 air side chamber 111 first frame 112 second frame 113 first recess forming surface 114 first collar 115 blood inlet 116 blood outlet 117 2 concave portion forming surface 118 second collar portion 119 pressure detecting port 119a opening region 119b opening edge 121 membrane main body 122 rib 151 air passage forming rib 151A air passage forming rib 151B air passage forming rib 151C air passage forming rib 152 air passage forming Groove 154 Protrusion 155 Recess 160 Ventilation path forming member 162 Ventilation path forming member

Claims (7)

a housing having a cavity therein and a flexible membrane separating the cavity into a blood side chamber and an air side chamber;
the housing in the air-side chamber has a pressure detection port opened on the inner surface and a step formed on the inner surface;
The step extends along the inner surface of the housing such that at least a portion of the step is spaced apart from the location of the pressure sensing port on the inner surface of the housing to form a vent path between the housing and the flexible membrane. blood circuit pressure measuring chamber. a housing having a cavity therein and a flexible membrane separating the cavity into a blood side chamber and an air side chamber;
The housing in the air-side chamber has a pressure detection port that opens on the inner surface,
The side of the flexible membrane that contacts the air side chamber has a step formed on the outer surface,
The step extends non-concentrically along the outer surface of the flexible membrane so that at least a portion of the step is spaced apart from a position corresponding to the pressure detection port on the outer surface of the flexible membrane. A blood circuit pressure-measuring chamber forming a vent path with a flexible membrane. 3. The blood circuit pressure measurement chamber according to claim 1, wherein said vent path is connected to said pressure detection port. the flexible membrane is a dome-shaped membrane having a major axis and a minor axis;
3. The blood circuit pressure measuring chamber according to claim 1, wherein the step extends in the longitudinal direction. a housing having a cavity therein; a flexible membrane that divides the cavity into a blood side chamber and an air side chamber; and the air side chamber provided between the inner wall surface of the housing and the flexible membrane, an air passage forming member that forms an air passage with the flexible membrane;
a side of the housing that contacts the air-side chamber has a pressure detection port that is open to the inner surface;
The air passage forming member extends along the inner wall surface of the housing such that at least a portion thereof is spaced apart from the position of the pressure detection port . a housing having a cavity inside; a flexible membrane that divides the cavity into a blood side chamber and an air side chamber; and a breathable membrane provided between the housing and the flexible membrane in the air side chamber. and an air passage forming member formed of a material,
A pressure-measuring chamber for a blood circuit, wherein the side of the housing that contacts the air-side chamber has a pressure detection port that is open to the inner surface. a housing having a cavity therein and a flexible membrane separating the cavity into a blood side chamber and an air side chamber;
a side of the housing that contacts the air-side chamber has a pressure detection port that is open to the inner surface;
an air passage between the housing and the flexible membrane in the air-side chamber, through which gas passes when the flexible membrane is in contact with the housing;
A blood circuit pressure-measuring chamber, wherein the vent path extends non-concentrically along an inner surface of the housing such that at least a portion of the vent is spaced from the pressure-sensing port.

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