JP4484669B2 - Puncture device - Google Patents

Description

  The present invention relates to a puncture device used when collecting body fluid such as blood from a fingertip.

  When blood is collected from the skin, a puncture device configured to pierce the skin with a needle is used. In the puncture device, various methods are employed in order to promote blood discharge. As a typical example, there is a method in which negative pressure is applied to the skin using a pump incorporated in the puncture device, and the blood is raised to collect blood (see, for example, Patent Document 1), or a method in which a finger is pressed to cause congestion. (For example, see Patent Documents 2-4).

  However, in the method of applying a negative pressure, it is necessary to incorporate an electric or manual pump in the puncture device. Therefore, in the method using an electric pump, the apparatus is increased in size and weight by the pump and the drive source of the pump. As a result, the puncture device employing the electric pump is not portable. Moreover, if the pump is driven by a drive source, the power consumption increases and the running cost increases. On the other hand, in the method using a manual pump, the construction of the apparatus becomes complicated by providing a pump mechanism for generating negative pressure, resulting in an increase in manufacturing cost, and it is troublesome for the user to operate the pump mechanism. Forced to operate.

  In the method of applying a negative pressure, air flows into the distal end portion of the puncture device unless the state where the distal end portion of the puncture device is properly pressed against the skin is maintained regardless of the electric type or the manual type. In addition, air flows into the tip of the puncture device due to the presence of hair between the tip of the puncture device and the skin. As a result, the method of applying a negative pressure has a problem that the negative pressure cannot be appropriately applied to the skin unless any measures are taken.

  On the other hand, as a method of pressing a finger, a method is used in which a cuff and a driving source are provided in the puncture device, and the finger is pressed by injecting air into the cuff by the driving source. For this reason, the cuff and the drive source increase the size and weight of the device, resulting in poor portability. Further, since power for driving the cuff is necessary, power consumption and thus running cost increase.

JP-T-2001-515377 JP-A-9-89885 Japanese Patent Laid-Open No. 9-313465 Japanese Patent Laid-Open No. 10-5199

  An object of the present invention is to be able to produce a bodily fluid such as blood appropriately by a simple operation with a low running cost, which can be advantageously manufactured in terms of cost.

In the present invention, a puncture device for piercing a puncture element into a puncture target site of a fingertip and discharging blood from the puncture target site, the puncture element being opened in a moving direction, and at the time of puncturing The body part having an opening sealed by the fingertip, and a state of covering the opening part and a state of not covering the opening part can be selected, and the fingertip is placed between the body part in the state of covering the opening part. A lid for forming an accommodation space for insertion, and the lid is a compression means for pressing a fingertip of a finger inserted into the accommodation space toward the opening, and the accommodation space characterized by comprising either one or both of the restraining means, for causing congestion fingertip is pressed while restraining the root side than the puncture target site in the inserted finger, providing puncture device It is.

  The puncture device of the present invention preferably further includes one or more lock mechanisms for maintaining the state where the opening is covered by the lid.

  The one or more lock mechanisms include, for example, first and second lock mechanisms. In this case, the puncture device can rotate the lid around the first lock mechanism by selecting a state in which the lid is locked in the first lock mechanism and the lid is not locked in the second lock mechanism. On the other hand, by selecting a state in which the lid is locked in the second locking mechanism and the lid is not locked in the first locking mechanism, the lid can be rotated about the second locking mechanism. The

  For example, when the opening is closed by the fingertip, the lid is configured to include a pressing means for pressing the fingertip toward the opening when the opening is covered by the lid.

  The compression means is configured to have a pair of compression pieces having a form following the surface shape of the fingertip, for example.

  It is preferable that the main body is configured to include a close contact member for closely contacting around the puncture target site in the fingertip when the opening is covered with the lid. The contact member is configured to have, for example, a through hole that defines the shape of the opening, and is preferably formed of an elastic body. In this case, the contact member has, for example, a flange portion in which the through hole is formed, and a cylindrical portion extending upward from the flange portion. The cylindrical portion is preferably formed in a tapered shape with an outer diameter increasing toward the top.

Captive unit, for example is swingably supported with respect to the lid. For example, the restraining means includes a leaf spring .

  The puncture apparatus of the present invention may further include a squeezing means for sending blood from the base side of the finger toward the puncture target site relative to the puncture target site and squeezing the blood from the puncture target site. The squeezing means is configured, for example, as having an action member for applying a force toward the fingertip to a portion of the finger closer to the base than the puncture target site. This action member is configured, for example, as a rotating body or a movable body that can move in the direction from the root side portion toward the puncture target site, and is configured to contact the finger via a sheet material as necessary. The

  The squeezing means is, for example, an action part for applying a force toward the puncture target site to the fingertip by applying a force to the fingertip inserted into the accommodation space in a direction to remove the fingertip from the accommodation space. It can also comprise as what has. This action part is comprised, for example as a leaf | plate spring which protrudes in accommodation space.

  The puncture device of the present invention is configured to include, for example, a puncture mechanism for moving a puncture element to puncture a puncture target site in a fingertip, and a control unit that controls timing for moving the puncture element in the puncture device. Is done. In this case, the control unit is preferably configured to move the puncture element by the puncture mechanism when it is confirmed that the opening is covered by the lid.

  The puncture device of the present invention can be configured to analyze a specific component in blood based on blood drawn from the skin.

  The present invention will be described below as first and second embodiments with reference to the drawings.

  First, a first embodiment of the present invention will be described with reference to FIGS.

  The puncture device 1 shown in FIGS. 1 to 3 is used with a lancet 2 attached thereto, and an accommodation space 11 for inserting a fingertip 10 between the device body 3 and the device body 3 (FIG. 1). 4).

  As shown in FIG. 2, the apparatus main body 3 includes a puncture mechanism 5 and a squeezing mechanism 6.

  As shown in FIGS. 2 and 3, the puncture mechanism 5 is for puncturing the fingertip 10 (see FIG. 4) held in the accommodation space 11, and includes the housing 50, the lancet holder 51, and the action portion 52. Have.

  The housing 50 is for housing the lancet 2 and the lancet holder 51. The housing 50 has an opening 53, a through hole 54, and a pair of stepped portions 55.

  The opening 53 is used when the lancet 2 is inserted, and has a notch 53a. The notch 53a is for engaging a convex portion 22C of the lancet 2 described later (see FIG. 16). A contact member 56 is disposed above the opening 53. The contact member 56 is used for closely contacting the fingertip 10 in a state where the fingertip 10 is inserted into the accommodation space 11 (see FIG. 4). A through hole 56 a is formed in the contact member 56. The through hole 56 a has a larger diameter than the opening 53 of the housing 50. Such a close contact member 56 is formed of an elastic body such as rubber or foam, for example, in order to ensure a large contact with the fingertip 10.

  The through hole 54 is a part for allowing movement of an engaging portion 51a of the lancet holder 51 described later and locking the engaging portion 51a at the peripheral portion 54a.

  The pair of step portions 55 is for applying a pressing force to the accommodating portion 22 of the lancet 2 described later, and protrudes toward the inside of the housing 50. The pair of stepped portions 55 are formed such that upper portions in FIGS. 2 and 3 are tapered.

  The lancet holder 51 is for holding the lancet 2. The lancet holder 51 is provided with an engaging portion 51a and a flange portion 51b. The engaging portion 51 a is formed in a hook shape that can be engaged with the peripheral portion 54 a of the through hole 54 in the housing 50. A coil spring 57 is disposed between the flange portion 51 b and the peripheral portion 54 a of the through hole 54. The coil spring 57 is in a compressed state when the engaging portion 51 a is engaged with the peripheral portion 54 a of the through hole 54. Therefore, if the state where the engaging portion 51a is engaged with the peripheral portion 54a of the through hole 54 is released, the elastic force of the coil spring 57 acts on the flange portion 51b, and the lancet holder 51 is moved in the arrow N1 direction. A coil spring 58 is disposed between the flange portion 51 b and the step portion 55. The coil spring 58 is compressed when the lancet holder 51 is moved in the direction of the arrow N1, and is used to move the lancet holder 51 in the direction of the arrow N2 by applying the elastic force at that time to the flange portion 51b. Is. However, the coil spring 58 may be omitted.

The action part 52 is for releasing the state in which the engaging part 51a of the lancet holder 51 is engaged with the peripheral part 54a of the through hole 54, and is movable in the directions of arrows N3 and N4.
That is, when the action part 52 is moved in the direction of the arrow N3, the action part 52 interferes with the engagement part 51a to apply a pressing force to the engagement part 51a, and the engagement part 51a is engaged with the peripheral part 54a of the through hole 54. The combined state can be canceled. This action part 52 is controlled by arrows N3 and N4 by control means not shown.
Movement in the direction is controlled. The control means is configured to move the action portion 52 in the direction of the arrow N3 by the actuator 59 in conjunction with the opening / closing operation of the lid 4, for example, to release the engagement state of the engagement portion 51a. Confirmation of the opening / closing of the lid 4 is performed by, for example, confirming that a concave portion 40b of the lid 4 described later is engaged with the convex portion 31 of the apparatus main body 3, or by providing a sensor in the accommodating space 11 to confirm the presence of the fingertip 10. This can be done by checking. Of course, the action part 52 can also be configured to be moved manually.

  As shown in FIG. 2 and FIG. 4, the squeezing mechanism 6 sends blood from the portion of the fingertip 10 closer to the puncture target site 10a toward the puncture target site 10a and sends blood from the puncture target site 10a. It is for squeezing out. The squeezing mechanism 6 has a rotating body 60 configured as a gear. The rotating body 60 is rotatable in the direction of the arrow N5 and is disposed so as to contact the fingertip 10 accommodated in the accommodating space 11 via the sheet material 61.

  As shown in FIGS. 4 and 5, the lid 4 has a configuration in which a pair of pressing portions 41 and a restraining portion 42 are supported with respect to the main body portion 40.

  The main body 40 is for forming the accommodating space 11 for inserting the fingertip 10 between the main body 40, and covers and does not cover the through hole 56 a of the contact member 56 in the main body 3. Can be selected (see FIG. 1). The main body 40 is opened downward so as to cover the apparatus main body 3 and is opened laterally so that the fingertip 10 can be inserted into the accommodation space 11. As shown in FIGS. 1 and 2, the main body portion 40 is provided with a shaft portion 40 a at an end portion. The shaft portion 40a is for fitting into the through hole 30 of the apparatus main body 3, and the main body portion 40 is rotatably supported with respect to the device main body 3 with the shaft portion 40a as a fulcrum. The main body 40 is further provided with a recess 40b at the end. The concave portion 40b constitutes a lock mechanism. When the device main body 3 is covered with the lid 4, the concave portion 40b engages with the convex portion 31 (which constitutes the lock mechanism together with the concave portion 40b) and covers the lid. 4 is for maintaining the closed state. In this state, as shown in FIG. 4, the accommodation space 11 is open to the side.

  As shown in FIGS. 4 and 6, the pair of compression parts 41 is configured so that the puncture target site 10 a in the fingertip 10 is inserted into the through hole 56 a of the contact member 56 in the apparatus main body 3 in a state where the fingertip 10 is inserted into the accommodation space 11. It is for pressing. Each compression portion 41 is supported on the inner surface of the main body portion 40 so as to be positioned immediately above the contact member 56 in a state where the main body portion 40 covers the apparatus main body 3. In this state, the surfaces of the two pressing portions 41 are in accordance with the surface shape of the fingertip 10.

  As shown in FIGS. 4, 5, and 7, the restraining portion 42 is for restraining the root portion of the finger rather than the puncture target site 10 a and causing the fingertip 10 to be congested. The restraining portion 42 is supported by the main body portion 40 via a leaf spring 43 and can swing with respect to the main body portion 40. In a state where the fingertip 10 is inserted into the accommodation space 11, the restraining portion 42 is disposed so as to face the rotating body 60 of the squeezing mechanism 6. Therefore, the spring force of the leaf spring 43 acts on the root portion of the finger inserted into the accommodation space 11 via the restraining portion 42, and the finger root portion is pressed toward the rotating body 60. Thereby, the fingertip 10 is made congested by the restraining part 42.

  As shown in FIG. 3, the lancet 2 includes an element (puncture needle 20a) for puncturing the fingertip 10 (see FIG. 22C), and is used by being inserted into the housing 50 in the apparatus main body 3. Is. As shown in FIGS. 8 to 10, the lancet 2 includes a lancet body 20, a cap portion 21, a housing portion 22, and a biosensor 23.

  The lancet body 20 includes a puncture needle 20a, a protection portion 20b that covers the end of the puncture needle 20a on the needle tip side, and a holding portion 20c in which an end opposite to the needle tip of the puncture needle 20a is embedded. . A notch 20d is formed between the protection part 20b and the holding part 20c, and the protection part 20b and the holding part 20c can be separated at the notch 20d. A recess 20e is formed in the protection part 20b. The recess 20e is for fitting an engagement support portion 21a of the cap portion 21 described later.

  As shown in FIGS. 9 to 11, the cap portion 21 is detachably held with respect to the housing portion 22, and supports the lancet body 20 on the protection portion 20b via the engagement support portion 21a. ing. Therefore, when the cap part 21 is separated from the housing part 22, the puncture needle 20 a can be exposed by separating the protective part 20 b in the lancet body 20.

As shown in FIGS. 8 to 10, the accommodating portion 22 is for holding the lancet body 20 and the biosensor 23, and is formed in a cylindrical shape as a whole. The accommodating portion 22 has three pairs of convex portions 22Aa, 22Ab, 22B, and 22C.

  As shown in FIG. 10 and FIG. 12, the pair of convex portions 22Aa and 22Ab are for bringing the lancet body 20 into close contact with the holding portion 20c, and the first diameter axis D1 from the inner surface 22a of the accommodating portion 22 is provided. It protrudes in the direction along the line. A support portion 22E for supporting the biosensor 23 extends from the convex portion 22Aa, as shown well in FIGS. The support portion 22E includes a spring portion 22Ea that functions as a leaf spring and a placement portion 22Eb on which the biosensor 23 is placed. The mounting portion 22Eb is provided with a notch 22Ec. As indicated by phantom lines in FIG. 14, the inner surface 22Ed of the notch 22Ec is in contact with the protective portion 20b of the lancet body 20 with the placement portion 22Eb positioned slightly outward from the natural state. . Further, the inner surface 22Ed of the notch 22Ec is positioned in a natural state when the puncture needle 20a is exposed by separating the protective portion 20b in the lancet body 20. At this time, a gap is provided between the inner surface 22Ed of the notch 22Ec and the puncture needle 20a.

  As shown in FIGS. 3 and 9, the pair of convex portions 22 </ b> B is for interfering with the step portion 55 of the housing 50 in the apparatus main body 3, and at a lower position of the outer surface 22 b of the housing portion 22, FIG. As shown in FIG. 4, the first diameter axis D1 is provided at a position along the second diameter axis D2.

  As shown in FIGS. 12 and 16, the pair of convex portions 22 </ b> C is provided on the first diameter axis D <b> 1 at the upper position of the outer surface 22 b of the housing portion 22. The convex portion 22 </ b> C is for engaging with the notch 53 a in the opening 53 when the lancet 2 is inserted into the housing 50 of the apparatus body 3. That is, the convex portion 22 </ b> C is used for positioning when the lancet 2 is inserted into the housing 50.

Such an accommodating part 22 is formed so that the whole can be elastically deformed by resin molding, for example. Therefore, as shown in FIG. 15 and FIG. 16, when a force directed inward along the second diameter axis D2 is applied to the pair of convex portions 22B, at least a pair of The accommodating part 22 deform | transforms in the part in which the convex part 22B was provided. Thereby, while the distance between the pair of protrusions 22B is reduced, the distance between the pair of protrusions 22Aa and 22Ab is increased and a gap is formed between the pair of protrusions 22Aa and 22Ab and the lancet body 20. As a result, the lancet body 20 can move relative to the accommodating portion 22 in the directions of arrows N1 and N2.

  The biosensor 23 shown in FIGS. 17 to 20 is configured to move blood by capillary force and to measure the concentration of a specific component (for example, glucose) in the blood by an electrode method. More specifically, the biosensor 23 includes a substrate 23a, a pair of spacers 23b, and a cover 23c, and includes a capillary 23d defined by these elements 23a to 23c.

On the surface of the substrate 23a, the working electrode 23e, pairs of poles 23f and the reagent portion 23g is provided. Working electrode 23e and counter electrode 23f, as can be seen from reference to Figure 17, the analysis circuit (not shown) in the apparatus main body 3 is a portion for conducting through the terminal 35. The reagent part 23g is formed so as to connect the working electrode 23e and the counter electrode 23f, and includes, for example, an oxidoreductase and an electron transfer substance.

  The pair of spacers 23b are for defining the width dimension and the height dimension of the capillary 23d, and are arranged on the surface of the substrate 23a at intervals so as to sandwich the reagent part 23g. These spacers 23b are made of double-sided tape, for example.

  The biosensor 23 is provided with a semicircular cutout 23h, as clearly shown in FIGS. This notch 23h is for allowing the puncture needle 20a to move when the lancet body 20 is moved in the direction of the arrow N1, and in this notch 23h, an opening 23j for introducing blood into the capillary 23d is opened. is doing. The biosensor 23 is fixed to the mounting portion 22Eb at a position where the notch 23h corresponds to the notch 22Ec in the mounting portion 22Eb. Therefore, when the mounting portion 22Eb is in a natural state, a gap is provided between the notch 23h and the puncture needle 20a.

  As shown in FIGS. 2 and 3, when performing a puncturing operation using the puncture device 1, the lancet 2 is inserted into the housing 50 through the through hole 56 a of the contact member 56 with the lid 4 first opened. To do. As shown in FIGS. 21 (a) and 21 (b), the insertion of the lancet 2 is performed while the convex portion 22C of the lancet 2 is aligned with the notch 53a of the housing 50 (see FIG. 16). This can be done by pushing the lancet 2 into 50.

  When the lancet 2 is pushed into the housing 50, the holding portion 20 c of the lancet body 20 is fitted into the lancet holder 51, while the convex portion 22 </ b> B of the housing portion 22 interferes with the step portion 55 of the housing 50. As a result, as shown in FIGS. 15 and 16, the housing portion 22 is deformed, and the lancet body 20 can be moved relative to the housing portion 22. At this time, since the holding portion 20 c of the lancet body 20 is fitted into the lancet holder 51, the lancet body 20 can move together with the lancet holder 51. Further, when the lancet 2 is inserted into the housing 50, the lancet holder 51 can be moved in the direction of the arrow N2, and the engaging portion 51a of the lancet holder 51 can be engaged with the peripheral portion 54a of the through hole 54 in the housing 50. . As a result, the coil spring 57 is compressed, and an elastic force is stored in the coil spring 57. Of course, the engaging portion 51 a of the lancet holder 51 may be engaged with the peripheral portion 54 a of the through hole 54, separately from the operation of holding the lancet 2. That is, before the lancet holder 51 holds the lancet 2, the engaging portion 51 a may be engaged with the peripheral portion 54 a of the through hole 54.

Next, as shown in FIGS. 11, 21 (b) and 21 (c), the cap portion 21 is removed from the lancet 2. At this time, as clearly shown in FIG. 11, the engagement support portion 21 a of the cap portion 21 is fitted in the recess 20 e of the protection portion 20 b in the lancet body 20, so when removing the cap portion 21, In the lancet 2, the protection part 20b is pulled out. As a result, the needle tip of the puncture needle 20a is exposed. At this time, as shown in FIG. 14, the biosensor 23 is displaced to a notch 23h, that is, a position with a slight gap between the opening 23j and the needle tip of the puncture needle 20a, and see FIG. As can be seen, the working electrode 23 e and the counter electrode 23 f of the biosensor 23 are in contact with a terminal 35 provided on the apparatus main body 3. In this state, a voltage can be applied between the working electrode 23e and the counter electrode 23f, and the amount of electrons supplied to the working electrode 23e can be measured as a current value.

Next, as shown in FIG. 4, the fingertip 10 is placed on the upper part of the apparatus body 3 so as to close the through hole 56 a of the contact member 56, and the lid 4 is closed. The state in which the lid 4 is closed is maintained by engaging the concave portion 40b of the lid 4 with the convex portion 31 of the apparatus main body 3 (see FIG. 2). In this state, an accommodation space 11 is formed between the lid 4 and the apparatus body 3, and the fingertip 10 is held in the accommodation space 11. As shown in FIGS. 4 and 6, in the accommodating space 11, the compression portion 41 presses the periphery of the puncture target site 10 a in the fingertip 10 against the contact member 56. In this state, the puncture target site 10 a protrudes from the through hole 56 a of the contact member 56 and enters the housing portion 22 of the lancet 2. Thereby, the puncture target site 10a is congested, blood is collected in the puncture target site 10a, and the puncture target site 10a comes into contact with the biosensor 23 in the accommodating portion 22 as shown in FIG. Further, in the accommodating space 11, as shown in FIGS. 4 and 7, the restraint portion 42 presses the root portion of the finger against the rotating body 60. In this state, the fingertip 10 is congested and the state in which the blood is retained at the fingertip 10 is maintained.

  Next, as shown in FIGS. 22A to 22C, the lancet body 20 is moved in the direction of the arrow N1, and the puncture needle 20a is pierced into the puncture target site 10a in the fingertip 10. The movement of the lancet body 20 is performed by moving the action portion 52 to cause the engagement portion 51 a to interfere with the action portion 52 and releasing the state where the lancet holder 51 is engaged with the housing 50. When the engagement state of the lancet holder 51 is released, the lancet holder 51 moves in the direction of the arrow N1 together with the lancet body 20 by the elastic force of the coil spring 57, and the puncture needle 20a of the lancet body 20 pierces the puncture target site 10a. .

As shown in FIG. 22 (c), when the puncture needle 20a is pierced into the puncture target site 10a, the puncture target site 10a in the fingertip 10 is incised, and blood is discharged. At this time, since a slight gap is provided between the puncture needle 20a and the opening 23j of the biosensor 23, the biosensor 23 does not impede blood outflow. Blood is collected at the fingertip 10 and thus at the puncture target site 10 a by the action of the compression part 41, the restraint part 42 (see FIGS. 4, 6, and 7) and the contact member 56. Therefore, blood can be appropriately discharged from the puncture target site 10a.

  As shown in FIGS. 22C and 22D, after the puncture needle 20a is pierced into the puncture target site 10a, the lancet holder 51 is retracted by the elastic force of the coil springs 57 and 58, and the puncture needle 20a. Is immediately withdrawn from the fingertip 10. At the same time, the rotating body 60 shown in FIG. 4 is rotated in the direction of arrow N5. As a result, the finger base portion is rubbed against the fingertip 10 via the sheet material 61, and blood is collected on the fingertip 10. Also by the action of the rotating body 60, blood can be more appropriately drained from the puncture target site 10a. The timing of rotating the rotator 60 is not limited to after the puncture needle 20a is pierced into the puncture target site 10a, but may be performed before the puncture needle 20a is pierced, or continuously before and after the puncture needle 20a is pierced. May be.

As shown in FIG. 23 (a), the blood B discharged from the puncture target site 10a reaches the opening 23j of the biosensor 23. Since a slight gap is provided between the puncture needle 20a and the opening 23j of the biosensor 23, the blood B drained from the skin can be appropriately applied to the opening 23j without being blocked by the puncture needle 20a. be introduced. In the biosensor 23, as shown in FIGS. 23A to 23C, the blood B moves inside the capillary 23d by the capillary force generated in the capillary 23d. At this time, the reagent part 23g is dissolved by the blood B, and a liquid phase reaction system is constructed inside the capillary 23d. In the liquid phase reaction system, electrons are taken out from a specific component in blood, such as glucose, and supplied to the working electrode 23e. In the apparatus main body 3, a voltage is applied between the working electrode 23e and the counter electrode 23f via the terminal 35 (see FIG. 17), and the amount of movement of electrons with respect to the working electrode 23e is the current value as the terminal 35 (see FIG. 17). Measured by. Further, the apparatus main body 3 analyzes a specific component based on the measured current value, for example, calculates a glucose concentration.

  The puncture device 1 is not limited to the embodiment described above, and various design changes can be made. For example, the means shown in FIGS. 24 (a) to 24 (c) and FIG. 25 can be adopted as means for collecting blood at the fingertip, and the base side of the finger is constrained to congest the fingertip. The means shown in FIG. 26 (a) and FIG. 26 (b) can be adopted as the means for achieving this, and the contact member shown in FIG. 27 (a) and FIG. 27 (b) is used. Can be adopted.

  The configuration shown in FIG. 24A employs a rotating body 60A having a peripheral edge formed in a sawtooth shape. The configuration shown in FIG. 24B employs a rotating body 60B having an outer peripheral member 62B having a relatively large surface frictional resistance. The outer peripheral member 62B is formed of rubber or the like, for example. When relatively increasing the frictional resistance of the surface of the rotating body 60B, the sheet material 61 (see FIG. 4) is omitted, and a part of the rotating body 60B is exposed from the apparatus main body 3. In the configuration shown in FIG. 24C, a moving body 60C capable of reciprocating in the N3 and N4 directions is provided in place of the rotating bodies 60, 60A and 60B. Of course, the form of the moving body is not limited to the illustrated example. Further, in the illustrated example, a part of the moving body 60C protrudes directly from the apparatus main body 3, but a configuration in which the moving body 60C is covered with the sheet material 61 (see FIG. 4) can also be employed.

  The configuration shown in FIG. 25 collects blood on the fingertip 10 by the action part 62 configured as a leaf spring. The action part 62 acts on the fingertip 10 in a direction (N3 direction) toward the puncture target site 10a by applying a force in a direction (N4 direction) in which the user pulls out the fingertip 10 from the accommodation space 11. It is for making it happen. This action part 62 can be formed, for example, by bending a metal plate. Moreover, the action part 62 is integrated with the main-body part 40 by insert molding, for example. Of course, the action portion 62 as a leaf spring may be integrally molded with the apparatus main body 3.

  In the configuration shown in FIGS. 26A and 26B, the restraint portion 42 </ b> A is provided on the lid 4, while the restraint portion 42 </ b> B is also provided on the apparatus main body 3. When the illustrated configuration is employed, at least one of the restraining portions 42A and 42B is preferably formed as having notches 42a and 42b corresponding to the shape of the portion to be restrained.

  27 (a) and 27 (b) includes a taper portion 56A ', a flange portion 56B', and an insertion portion 56C '. For example, an elastic member such as rubber or foam is used. By being formed by the body, the whole has elasticity.

  The taper portion 56A ′ protrudes upward from the peripheral edge portion of the flange portion 56B ′, and is formed in a taper shape whose outer diameter increases toward the upper side. The tapered portion 56A ′ is configured to be elastically deformable outward.

  The flange portion 56B ′ protrudes inward between the tapered portion 56A ′ and the insertion portion 56C ′, and defines a through hole 56D ′.

  The insertion portion 56 </ b> C ′ is a portion that is inserted into the opening 53 of the apparatus main body 3 in order to fix the adhesion member 56 ′ to the apparatus main body 3.

  In the contact member 56 ′ described above, when the fingertip 10 is pressed against the tapered portion 56A ′ and the flange portion 56B ′, the puncture target portion 10a of the fingertip 10 can be appropriately congested. That is, when the fingertip 10 is pressed against the contact member 56 ', the tapered portion 56A' is elastically deformed outward. At this time, a force directed inward or upward acts on the peripheral edge of the flange portion 65B ′ (peripheral portion of the through hole 56D) on the flange portion 56B ′. On the other hand, the flange portion 56B ′ is pressed downward by the fingertip 10. Therefore, a force to pinch the puncture target site 10a by the through hole 56D ′ acts on the fingertip 10. Further, when the fingertip 10 is pressed against the flange portion 65B ′, the puncture target portion 10a advances into the through hole 65D ′ by the pressing force, and this also sandwiches the puncture target portion 10a with the through hole 56D ′. Applying force acts. By these actions, the puncture target site 10a is appropriately congested by the contact member 56 ′. Further, when an inward or upward force is applied to the peripheral edge of the flange portion 65B ′ (peripheral portion of the through hole 56D), air is discharged from the inside of the housing 50 and negatively flows into the housing 50. A pressure is expected to be generated, and in this case, the puncture target site 10a is congested by the action of the negative pressure. Therefore, in the contact member 65 ', the puncture target site 10a can be appropriately congested.

  Next, a second embodiment of the present invention will be described with reference to FIGS. However, in these drawings, the same elements as those described in the first embodiment of the present invention are denoted by the same reference numerals, and the redundant description below will be omitted.

  The puncture apparatus 1A shown in FIGS. 28 and 29 has the basic configuration according to the first embodiment of the present invention described above except for the lid 4A and the first and second lock mechanisms 7A and 8A. This is the same as the puncture device 1 (see FIGS. 1 to 3).

  The lid 4A is for forming an accommodation space 11 for inserting a fingertip between the device main body 3A and selects a state in which the through hole 56a of the contact member 56 in the device main body 3A is covered or not covered. It is configured to be able to. The lid 4A is opened downward so as to cover the apparatus body 3A, and is opened on both sides (N3 and N4 directions) so that a fingertip can be inserted into the accommodation space 11. That is, the lid 4A is configured to achieve a state in which the fingertip is inserted from both sides (N3 and N4 directions) with respect to the accommodation space 11.

  The lid 4A has concave portions 42A and 43A provided on the inner surface side of the end pieces 40A and 41A and convex portions 44A and 45A provided on the outer surface side of the end piece pieces 40A and 41A. The recesses 42A and 43A are for engaging locking members 71A and 81A of biasing means 70A and 80A described later, and are formed in a circular cross section. Each recess 42A, 43A constitutes the first and second lock mechanisms 7A, 8A. On the other hand, the convex portions 44A and 45A are portions operated by the user when releasing the lock state when the lid 4A is in the lock state in the first and second lock mechanisms 7A and 8A. The convex portions 44A and 45A are provided at positions slightly offset from the concave portions 42A and 43A. The convex portions 44A and 45A also constitute the first and second lock mechanisms 7A and 8A.

  The first and second lock mechanisms 7A and 8A are for enabling selection of a state in which the lid 4A is closed and a state in which the lid 4A is rotatable, and the first and second lock mechanisms 7A and 8A are respectively provided at the end pieces 40A and 41A of the lid 4A. The cover 4A is configured to be kept closed. Therefore, in puncture device 1A, in one lock mechanism 7A, 8A of first and second lock mechanisms 7A, 8A, lid 4A is opened from device body 3 (unlocked state), The lid 4A can be rotated using the other lock mechanisms 7A and 8A as fulcrums. That is, puncture apparatus 1A can select the rotation state indicated by the solid line in FIG. 28 and the rotation state indicated by the phantom line in FIG.

  Each lock mechanism 7A, 8A has urging means 70A, 80A provided in the apparatus main body 3A in addition to the concave portions 42A, 43A and the convex portions 44A, 45A provided in the lid 4A. The urging means 70A and 80A include a pair of rod-like members 71A and 81A and coil springs 72A and 82A.

  As shown in FIG. 29A, the pair of rod-like members 71A (81A) is engaged with the recess 42A (43A) of the lid 4A when the apparatus body 3A is covered by the lid 4A, and the lid 4A is engaged with the apparatus body. It is for achieving the state locked to 3A. These rod-shaped members 71A (81A) are formed in a rod shape whose appearance is a substantially cylindrical shape, and with one end 71Aa (81Aa) protruding from the device main body 3A, the through-hole 32A of the device main body 3A. Are inserted in the N6 and N7 directions so as to be reciprocally movable. Each rod-like member 71A (81A) is chamfered at one end 71Aa (81Aa), while a recess 71Ac (81Ac) is provided at the other end 71Ab (81Ab). The recess 71Ac (81Ac) is for fixing the coil spring 72A (82A). Each rod-like member 71A (81A) is further provided with a stopper portion 71Ad (81Ad). This stopper portion 71Ad (81Ad) restricts each rod-like member 71A (81A) from moving toward the outside of the apparatus main body 3A, and defines the maximum protrusion amount of the rod-like member 71A (81A) from the apparatus main body 3A. Is to do.

  On the other hand, the coil spring 72A (82A) is for applying an urging force to the rod-shaped member 71A (81A), and ends thereof are rod-shaped members so as to connect the pair of rod-shaped members 71A (81A) to each other. It is fixed in the recess 71Ac (81Ac) of 71A (81A).

In lancing device 1A, the first and second locking mechanism 7A, the lock state in 8A, the end piece 40A, 41A recess 42A of, 43A and the rod-shaped member 71A, 81A of the end portion 71Aa, more accomplished engagement with 81Aa can do. On the other hand, the locked state can be released by applying a force directed toward the inner side of the apparatus main body 3A by the user on the convex portions 44A and 45A of the end pieces 40A and 41A. That is, when a force directed inward is applied to the convex portions 44A and 45A, the convex portions 44A and 45A are offset with respect to the concave portions 42A and 43A. The end pieces 40A and 41A are bent as shown in FIG. Accordingly, the recesses 42A and 43A are displaced outward of the apparatus main body 3A. On the other hand, the rod-shaped members 71A and 81A cannot move outward because the movement of the apparatus main body 3A toward the outside is restricted. As a result, the engaged state between the recesses 42A and 43A and the one end portions 71Aa and 81Aa of the rod-like members 71A and 81A is released, and the locked state is released.

  As can be seen from FIG. 28, the puncture device 1A can be opened both left and right in the figure, and can achieve a state in which the fingertip is inserted from both the left and right sides of the accommodation space 11 (see FIG. 29). Therefore, in puncture apparatus 1A, a hand that is convenient for the user can be selected and blood can be drained from the finger of the hand, which is convenient and easy to use. Further, when the locked state in the first and second lock mechanisms 7A, 8A is released, the lid 4A can be removed from the apparatus main body 3A. Thereby, for example, the apparatus main body 3A and the lid 4A can be easily cleaned, and the apparatus main body 3A and the lid 4A can be used hygienically.

The first and second lock mechanisms 7A and 8A , for example, apply a force directed inward to the convex portions 44A and 45A, and apply the force to the one end portions 71Aa and 81Aa of the rod-shaped members 71A and 81A. May be configured to release the locked state. That is, the rod-shaped members 71A, 81A are moved inward by acting on the one end portions 71Aa, 81Aa of the rod-shaped members 71A, 81A, and the engagement between the concave portions 42A, 43A and the one end portions 71Aa, 81Aa of the rod-shaped members 71A, 81A. You may comprise so that a joint state may be cancelled | released.

  In puncture apparatus 1A, the structure shown in FIGS. 30 and 31 may be employed as the lock mechanism.

The locking mechanism 9A shown in these drawings is similar to the locking mechanisms 7A and 8A (see FIGS. 28 and 29) in the second embodiment described above, and the recesses 42A and 43A provided in the lid 4A and Urging means 90A provided in the apparatus main body 3A. The lock mechanism 9A further includes an operation unit 99A provided in the apparatus main body 3A.

As shown in FIGS. 31 (a) and 31 (b), the urging means 90A includes a pair of rod-shaped members 91A and a coil spring 92A in the same manner as the lock mechanisms 7A and 8A (see FIGS. 28 and 29). The rod-shaped members 91A are connected to each other by a coil spring 92A.

  The pair of rod-shaped members 91A are inserted so as to be capable of reciprocating in the N6 and N7 directions with respect to the through holes 32A of the apparatus main body 3A with one end portion 91Aa protruding from the apparatus main body 3A. A pin 91Ac is provided at the other end 91Ab of each rod-shaped member 91A. Pin 91Ac is a part for making it interfere with taper part 99Ab of the operation part 99A mentioned later.

  The operation unit 99A is for applying a force for moving the rod-shaped member 91A in the N6 and N7 directions to the rod-shaped member 91A. The operation portion 99A is inserted so as to be capable of reciprocating in the N3 and N4 directions with respect to the through hole 33A of the apparatus main body 3A in a state where the one end 99Aa protrudes from the apparatus main body 3A. The operation part 99A has a pair of taper parts 99Ab. These taper portions 99Ab are portions for causing interference with the pins 91Ac of the rod-shaped member 91A, and have a cam surface 99Ac. The cam surface 99Ac moves the rod-shaped member 91A inward when the operation part 99A is moved inward of the apparatus main body 3A, while moving the operation part 99A outward of the apparatus main body 3A. The rod-shaped member 91A is sometimes formed to move outward.

  In the lock mechanism 9A, the locked state can be released by applying a force directed to the inner side of the apparatus main body 3A by the user on the operation unit 99A. That is, when a force directed inward is applied to the operation portion 99A, the pin 91Ac relatively moves along the cam surface 99Ac. That is, the pins 91Ac move inward so as to approach each other. As a result, the rod-shaped member 91A moves inward, the engagement between the one end 99Aa of the rod-shaped member 91A and the recesses 42A and 43A of the lid 4A is released, and the locked state is released.

  In the lock mechanism 9A, for example, a portion that interferes with the operation portion 99A when the lid 4A is opened more than a certain amount may be provided on the lid 4A. In that case, if one lock mechanism 9A is released and the lid 4A is opened more than a certain amount, the lid 4A interferes with the operation portion 99A, and the operation portion 99A moves inward. Thereby, the lock state of the other lock mechanism 9A is released, and the lid 4A can be removed from the apparatus main body 3A.

  The lock mechanisms 7A, 8A, 9A (see FIG. 28 and FIG. 29, or FIG. 30 and FIG. 31) employed in the puncture device 1A according to the second embodiment of the present invention are the same as those described above. The lock mechanism 31, 40b (see FIGS. 1 to 3) of the puncture apparatus 1 according to the first embodiment can be employed instead, and conversely, the lock mechanism according to the second embodiment of the present invention. As an alternative, the lock mechanisms 31 and 40b (see FIGS. 1 and 2) employed in the first embodiment may be employed. In addition, the structure in which the lid 4 is rotatably supported with respect to the apparatus main body 3 in the puncture apparatus 1 according to the first embodiment of the present invention (the through hole 30 of the apparatus main body 3 and the shaft portion 40a of the lid) (FIG. 1 and FIG. 2), the lock mechanisms 7A, 8A, and 9A (see FIGS. 28 and 29, or FIGS. 30 and 31) in the second embodiment may be employed. In that case, the portions (lock mechanisms 7A, 8A, 9A) that support the lid 4A can be easily released. Therefore, since the lid 4A can be easily removed from the apparatus main body 3A, the apparatus main body 3A and the lid 4A can be easily and appropriately cleaned. Furthermore, in the puncture apparatus 1 according to the first embodiment of the present invention, when the lock mechanism 9A described with reference to FIGS. 30 and 31 is employed, for example, the lid 4A is attached to the lid 4A. A portion that interferes with the operation unit 99A when opened more than a certain amount may be provided so that the lid 4A can be removed from the apparatus main body 3A by causing the lid 4A to interfere with the operation unit 99A.

It is a front view which shows the puncture apparatus which concerns on the 1st Embodiment of this invention. It is sectional drawing of the puncture apparatus shown in FIG. It is sectional drawing to which the principal part for demonstrating the puncture mechanism in the puncture apparatus shown in FIG. 1 was expanded. It is sectional drawing to which the principal part for demonstrating the squeezing mechanism in the puncture apparatus shown in FIG. 1 was expanded. It is the perspective view which showed the lid | cover in the puncture apparatus shown in FIG. 1 seeing through the main-body part of this lid | cover. It is sectional drawing which follows the VI-VI line of FIG. It is sectional drawing which follows the VII-VII line of FIG. FIG. 2 is an overall perspective view of a lancet used in the puncture device shown in FIG. 1. It is sectional drawing which follows the IX-IX line of FIG. It is sectional drawing which follows the XX line of FIG. It is sectional drawing which shows the state which removed the cap in the lancet shown in FIGS. It is sectional drawing which follows the XII-XII line | wire of FIG. It is the principal part perspective view which notched and showed a part for demonstrating the internal structure of a lancet. It is a top view of the lancet of the state shown in FIG. It is sectional drawing for demonstrating operation | movement of a lancet. It is sectional drawing for demonstrating operation | movement of a lancet. It is a whole perspective view of the biosensor integrated in the lancet. It is a disassembled perspective view of the biosensor shown in FIG. It is sectional drawing which follows the XIX-XIX line | wire of FIG. It is sectional drawing which follows the XX-XX line of FIG. It is principal part sectional drawing for demonstrating operation | movement of a puncture mechanism. It is principal part sectional drawing for demonstrating operation | movement of a puncture mechanism. It is principal part sectional drawing for demonstrating the process in which the blood is introduce | transduced in a biosensor. It is principal part sectional drawing which shows the other example of a squeezing mechanism. It is sectional drawing which shows the other example of the structure for collecting the blood at a fingertip. It is principal part sectional drawing which shows the other example (restraint means) for restraining the base side of a finger | toe. It is principal part sectional drawing of the puncture apparatus for demonstrating the other example of a contact | adherence member. It is a front view which shows the puncture apparatus which concerns on the 2nd Embodiment of this invention. FIG. 29 is a cross-sectional view for explaining the first and second locking mechanisms in the puncture device shown in FIG. 28 and corresponding to a cross section taken along line XXIX-XXIX in FIG. 28. It is a front view of the puncture device for demonstrating the other example of a locking mechanism. FIG. 31 is a cross-sectional view for explaining a locking mechanism in the puncture device shown in FIG. 30 and corresponding to a cross section taken along the line XXXI-XXXI in FIG. 30.

Explanation of symbols

1, 1A Puncture device 10 Fingertip 11 Storage space 20a Puncture needle (puncture element)
3,3A Main unit (main unit)
31 Convex part (of the device body) (constituting a lock mechanism)
4, 4A Lid 40b (Lid of the lid) (constituting the lock mechanism)
41 Pressure part (pressure piece)
42 Restraint part (restraint means)
42A Restraint part (second clamping part)
42B Restraint part (first clamping part)
43 Leaf spring 5 Puncturing mechanism 56, 56 'Contact member 56a, 56D' (Close contact member) Through hole (opening of main body)
56A 'taper part (cylindrical part)
56B 'flange part (adhesion member) 6 squeezing mechanism (squeezing means)
60, 60A, 60B Rotating body (action member)
60C moving body (action member)
61 Sheet material 62 Action part (squeezing means)
7A First lock mechanism 8A Second lock mechanism 9A Lock mechanism

Claims (21)

A puncture device for piercing a puncture element into a puncture target site of a fingertip and discharging blood from the puncture target site,
The puncture element is open in the direction of movement, and at the time of puncture, a main body having an opening sealed by a fingertip;
A lid for forming an accommodation space for inserting a fingertip between the body part and the body part in a state where the state covering the opening and the state not covering can be selected. equipped with a,
The lid is a pressing means for pressing a fingertip of a finger inserted into the accommodation space toward the opening, and is pressed while constraining a root side from the puncture target site in the finger inserted into the accommodation space. And / or a restraining means for congesting the fingertip .   The puncture device according to claim 1, further comprising one or more lock mechanisms for maintaining a state where the opening is covered with the lid. The one or more locking mechanisms include first and second locking mechanisms,
By selecting a state in which the lid is locked in the first lock mechanism and the lid is not locked in the second lock mechanism, the lid can be rotated with the first lock mechanism as a fulcrum. ,
By selecting a state in which the lid is locked in the second lock mechanism and the lid is not locked in the first lock mechanism, the lid can be rotated with the second lock mechanism as a fulcrum. The puncture device according to claim 2, which is configured. The puncture apparatus according to any one of claims 1 to 3, wherein the compression means includes a pair of compression pieces having a form following the surface shape of a fingertip . The puncture device according to any one of claims 1 to 4 , wherein the main body portion includes an adhesion member for bringing the body into close contact with a puncture target site in the fingertip when the opening is covered with the lid. . The puncture apparatus according to claim 5 , wherein the contact member has a through hole that defines a shape of the opening . The puncture apparatus according to claim 5 or 6, wherein the contact member is made of an elastic body . The puncture apparatus according to claim 7, wherein the contact member includes a flange portion in which the through hole is formed and a cylindrical portion extending upward from the flange portion . The puncture apparatus according to claim 8, wherein the tubular portion is formed in a tapered shape having an outer diameter that increases toward the top . The puncture device according to any one of claims 1 to 9 , wherein the restraining means is supported to be swingable with respect to the lid . The puncture apparatus according to claim 10 , wherein the restraining means includes a leaf spring . The puncture device according to any one of claims 1 to 11, wherein when the lid has the restraining means, the lid has additional restraining means provided on the main body . Send the puncture target than to the region of the finger root side from toward the puncture target site blood further comprises a Shiboeki means to squeeze blood from the puncture target site, any of claims 1 to 12 the lancing device according to any. 14. The puncture device according to claim 13 , wherein the squeezing means has an action member for applying a force in a direction toward the fingertip with respect to a portion of the finger closer to the base than the puncture target site . The working member, Ru rotator der lancing device of claim 14. The working member, Ru mobile der movable from the portion of the base side in a direction toward the puncture target site, the lancing device according to claim 14. The working member via the sheet material that is configured to contact a finger puncture device according to any one of claims 14 to 16. The squeezing means acts on the fingertip inserted in the accommodation space in a direction to remove the fingertip from the accommodation space, thereby applying a force directed to the puncture target site on the fingertip. the that have, lancing device according to any one of claims 13 to 17. The puncture device according to claim 18 , wherein the action portion is configured as a leaf spring protruding in the accommodation space . A puncture mechanism for puncturing a puncture target site on a fingertip by moving the puncture element, and a control unit for controlling timing of moving the puncture element in the puncture device,
The control unit, when the opening portion is confirmed that it was covered by the lid, by the lancing mechanism is configured to move the lancing element, according to any one of claims 1 to 19 Puncture device. The puncture device according to any one of claims 1 to 20 , wherein the puncture device is configured to analyze a specific component in the blood based on blood discharged from the puncture target site .

Images