Patent Publication Number: US-2009240165-A1

Title: Apparatus for containing sampled liquid

Description:
BACKGROUND OF THE INVENTION 
     (1) Field of the Invention 
     The present invention relates to an apparatus for containing sampled liquid punctured into an organism to collect a compositional bodily fluid, and that stores the collected compositional bodily fluid to enable a measurement, analysis, or other processing of the compositional bodily fluid. 
     (2) Description of the Related Art 
     Devices that collect a compositional bodily fluid to perform various tests are known in which a portion to collect a compositional bodily fluid from an organism is integrated into a portion where the measurement, analysis, or other processing of the collected compositional bodily fluid are performed. 
     Patent Document 1 proposes a blood collecting device in which a blood collection needle punctured into an organism to collect blood projects out of the main body integral with the needle. In this blood collecting device, the blood collection needle projects out of the periphery of the main body formed from, for example, an SOI plate. The blood collection needle includes a blood-collecting hollow portion in communication with a meandering channel provided in the main body. The device also includes a pump unit at an end of the channel. The blood collection needle is punctured into an organism, and the pump unit is used to draw blood into the channel, where the blood glucose level or other characteristics of the blood is measured. Because this type of blood collecting device requires a driving section, such as the pump unit, to draw the blood into the meandering channel, the configuration of the device tends to become complex. 
     Patent Document 2 proposes a device for analyte measurement configured so that a lance including a lancing element, a separation element, and a connector connecting these elements projects out of a substrate integral with the lance. In this device, a fill channel is provided that extends in a straight line from the gap between the lancing element and the separation element of the connector to the measurement site of the substrate. The tip of the lancing element is used to make an incision in the skin, and bodily fluid is collected in the gap between the lancing element and the separation element. The measurement of the bodily fluid is made by transferring the bodily fluid to the measurement site through the fill channel by capillary action. This device can transfer the bodily fluid to the measurement site without using driving means such as a pump unit. However, when the device is reduced in size, the fill channel becomes short, and it becomes difficult to store a sufficient amount of bodily fluid. 
     Patent Document 3 proposes a test strip device that includes a substrate and a microneedle. The microneedle is integral with the substrate, and two-dimensionally extends out of the substrate. An opening to pool bodily fluid is provided in the microneedle, and a channel in communication with the opening extends to the substrate. The channel has large numbers of sub-channels, above which a continuous open space is created to provide a reaction zone or the like. In this test strip device, the microneedle is punctured into an organism to pool bodily fluid in the opening of the microneedle. The bodily fluid is then stored in the channel by being drawn or by capillary action. The bodily fluid in the channel is stored in the sub-channels, and, when stored in sufficient amounts, fills the reaction zone or the like, where various measurements are performed. In this device, it is difficult to smoothly store a sufficient amount of bodily fluid in the reaction zone or the like by capillary action through the opening, channel, and the large numbers of sub-channels, and the storage of a sufficient amount of bodily fluid often takes time.
     Patent Document 1: JP-A-2000-185034   Patent Document 2: JP-A-2004-298628   Patent Document 3: JP-A-2004-113772   

     BRIEF SUMMARY OF THE INVENTION 
     In devices in which the puncture portion used to collect a compositional bodily fluid is integrated into a portion where the collected compositional bodily fluid undergoes a measurement, analysis, or some other processing, it is difficult to ensure a desired storage volume or storage speed because, when a sufficient amount of compositional bodily fluid is to be stored by capillary action without using a driving section such as a pump, a sufficient force cannot be provided for the transfer of the compositional bodily fluid, and the storage volume or storage speed tends to vary greatly depending on the channel configuration. 
     Ensuring a sufficient storage volume is particularly difficult when the size of the fine puncture portion is reduced to relieve the burden on an organism, because it accompanies a corresponding reduction in the size of the collecting portion or the channel. 
     It is accordingly an object of the present invention to provide an apparatus for containing sampled liquid that can store a sufficient amount of compositional bodily fluid in a short time period with a simple configuration. 
     The invention provides an apparatus for containing sampled liquid that includes: a substrate; and a puncture portion, integral with the substrate, and that projects out of the substrate for insertion into an organism. The puncture portion includes a collection channel, and the substrate includes a storage channel in communication with the collection channel. The collection channel collects a compositional bodily fluid, and the storage channel stores the compositional bodily fluid transferred thereto by capillary action. The storage channel includes an inflecting portion or a branched portion shaped to enable capillary action transfer of the compositional bodily fluid. At least an innermost portion of the storage channel farthest from the collection channel is open to atmosphere. 
     The provision of the inflecting portion or branched portion shaped to enable capillary action transfer of the compositional bodily fluid helps increase the total length of the storage channel, and therefore the total volume of the storage channel. Because the increased storage channel length helps increase the inner wall surface area in contact with the compositional bodily fluid in the storage channel for a given storage volume of the compositional bodily fluid, the capillary force required for the transfer of the compositional bodily fluid can be provided with ease. This facilitates the storage of a sufficient amount of compositional bodily fluid in the storage channel in a short time period. Further, because the compositional bodily fluid is stored in the storage channel by capillary action transfer, the device does not require driving means to collect the compositional bodily fluid, making it possible to simplify the configuration. 
     ADVANTAGEOUS EFFECTS 
     The invention provides an apparatus for containing sampled liquid that includes a storage channel provided with an inflecting portion or a branched portion shaped to enable capillary action transfer of a compositional bodily fluid. In the storage channel, at least an innermost portion farthest from the collection channel is open to atmosphere. With this construction, the apparatus for containing sampled liquid can easily store a sufficient amount of compositional bodily fluid in a short time period with a simple configuration. 
    
    
     
       BRIEF DESCRIPTION OF SEVERAL VIEWS OF THE DRAWING 
         FIG. 1  is a perspective view illustrating an apparatus for containing sampled liquid of an embodiment of the present invention. 
         FIG. 2A  through  FIG. 2C  illustrate a puncture portion of the apparatus for containing sampled liquid of an embodiment of the present invention, in which  FIG. 2A  is a plan view,  FIG. 2B  is a side view, and  FIG. 2C  is a front view. 
         FIG. 3A  through  FIG. 3C  are partial enlarged views of storage channels of the apparatus for containing sampled liquid of an embodiment of the present invention, in which  FIG. 3A  is a plan view,  FIG. 3B  is a cross sectional view taken at line A-A of  FIG. 3A , and  FIG. 3C  is a cross sectional view taken at line B-B of  FIG. 3A . 
         FIG. 4  is a plan view of a substrate according to a modification example of the apparatus for containing sampled liquid of an embodiment of the present invention. 
         FIG. 5A  through  FIG. 5G  are photographs showing test pieces tested in Examples 1 to 7. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION  
     An embodiment of the present invention is described below with reference to the accompanying drawings. 
       FIG. 1  through  FIG. 3  represent an embodiment of the present invention. 
       FIG. 1  illustrates an apparatus for containing sampled liquid  10 . The apparatus for containing sampled liquid  10  includes a plate-like substrate  11 , and a puncture portion  13  integral with the substrate  11 , and that projects out as a partial protrusion from the periphery of the substrate  11  in the plane of the plate-like substrate  11 . The puncture portion  13  includes collection channels  17  formed from micro channels. The substrate  11  includes storage channels  15  formed from micro channels in communication with the collection channels  17 . 
     The apparatus for containing sampled liquid  10  is a device that enables a measurement, analysis, or other processing of a compositional bodily fluid. This is attained by puncturing the puncture portion  13  into an organism, collecting the compositional bodily fluid in the collection channels  17 , and storing the compositional bodily fluid in the storage channels  15  by the capillary action transfer of the fluid to the storage channels  15 . 
     The compositional bodily fluid to be collected by the apparatus for containing sampled liquid  10  is a variety of fluids found in organisms, such as the blood and the interstitial fluid of humans and animals. The processing of the compositional bodily fluid includes various processes performed on small quantities of compositional bodily fluid, for example, such as a measurement or analysis of various components contained in the compositional bodily fluid, and a reaction of the compositional bodily fluid with other components. Examples include measurements of blood glucose level; blood tests for ketone bodies, glycohemoglobin, lipids, proteins, and antigen-antibody reaction; DNA analysis; identification of antibodies and proteins, and testing of chemical substances. 
     The puncture portion  13  of the apparatus for containing sampled liquid  10  is described below. In this embodiment, as illustrated in  FIG. 2 , the puncture portion  13  includes a base end  21  on the substrate  11  side, an end point  23  at the tip, and an jagged surface portion  25  having jags formed on the lateral periphery. The cross section of the base end  21 , the end point  23 , and the jagged surface portion  25  orthogonal to the projecting direction of the puncture portion  13  is trapezoidal in shape over the entire length. 
     The size of the puncture portion  13  can be appropriately selected according to intended use. For example, the maximum length of the cross section orthogonal to the direction of projection from the substrate  11  may fall in a range of from 100 to 2,000 μm, and the total length along the projecting direction may be from 0.15 to 2 mm. When the maximum length of the cross section orthogonal to the projecting direction is excessively small, it becomes difficult to ensure sufficient strength during use. Further, it makes the collection channels  17  too narrow to collect a sufficient amount of fluid. On the other hand, when the maximum length of the cross section is too large, the puncturing causes more damage in the surrounding cells or more pain in the organism, increasing the burden on the organism. When the total length along the projecting direction is too small, it becomes difficult to puncture the organism. When too large, it becomes difficult to provide strength for the puncture portion  13  during use, and bending or breaking becomes likely during puncturing. 
     The cross sectional shape of the puncture portion  13  orthogonal to the projecting direction can be suitably selected. For example, the cross section may be semicircular, circular, semi-elliptical, elliptical, triangular, square, rectangular, trapezoidal, rhomboidal, polygonal (including a pentagon and higher polygons), and various jagged shapes. In this embodiment, as illustrated in  FIG. 2 , the cross section is trapezoidal in shape for ease of formation and other considerations. 
     The jagged surface portion  25  is provided on preferably at least a portion of the lateral periphery of the puncture portion  13 . Particularly preferably, ridge portions  27  are repeatedly formed along the projecting direction of the puncture portion  13 . In this case, it is particularly preferable that maximum points  26   a,    26   b,  and  26   c,  at which the cross sectional area orthogonal to the projecting direction of the puncture portion  13  is maximum, be alternately disposed with minimum points  28   a,    28   b,  and  28   c,  at which the cross sectional area is minimum, and that the cross sectional area at the maximum point  26   a  closest to the tip be equal to or greater than the cross sectional area at the maximum points  26   b  and  26   c  on the side of the substrate  11 . This helps reduce damage to the surrounding cells or pain caused by puncturing, reducing the burden on the organism. The shape and the position of the jagged surface portion  25  can be suitably selected according to such factors as the intended use of the apparatus for containing sampled liquid  10 , and the site of puncturing in an organism. 
     For purposes such as the reduction of the burden on an organism, and the provision of strength for the puncture portion  13  during use, it is preferable that the maximum length of the cross section at the maximum points  26   a,    26   b,  and  26   c  be 40 to 600 μm, more preferably 80 to 300 μm, and that the maximum length of the cross section at the minimum points  28   a,    28   b,  and  28   c  be 20 to 300 μm, more preferably 40 to 150 μm, and that the distance between the maximum points  26   a,    26   b,  and  26   c  be 5 to 200 μm, more preferably 20 to 100 μm. 
     The collection channels  17  of the puncture portion  13  are configured to collect the compositional bodily fluid of an organism upon insertion, and transfer the fluid to the storage channels  15  of the substrate  11  by capillary action. The collection channels  17  may be provided as hollow pores formed inside the puncture portion  13 , opening to outside at a predetermined position on the tip side and/or the lateral periphery of the puncture portion  13 . Alternatively, the collection channels  17  may be provided as grooves or slits opening to outside on the lateral periphery of the puncture portion  13 . Preferably, the collection channels  17  are provided as grooves, because the grooves are easy to form, and help increase the contact area with the compositional bodily fluid, and provide sufficient strength for the puncture portion  13  during use. 
     When the collection channels  17  are provided as hollow pores or grooves, the cross section of the collection channels  17  orthogonal to the projecting direction of the puncture portion  13  can have any shape, for example, such as an arc, a substantially triangular shape (substantially V-shaped), and a substantially quadrangular shape (substantially U-shaped). The cross section preferably has the same shape as that of the storage channels  15  of the substrate  11 , from the standpoint of preventing formation of steps between the collection channels  17  and the storage channels  15 , as will be described later. 
     In this embodiment, the collection channels  17  are provided as two grooves along the projecting direction of the puncture portion  13 , and the cross section of each collection channel  17  orthogonal to the projecting direction of the puncture portion  13  is substantially quadrangular in shape (substantially U-shaped). The cross section is so shaped because it helps increase the cross sectional area for a given opening width. Each collection channel  17  is continuously provided on the jagged surface portion  25 , passing through the ridge portions  27  in the projecting direction of the puncture portion  13 . The inner wall surfaces of each collection channel  17  include a flat bottom surface  17   a  extending along the entire length. 
     Preferably, the cross sectional area of the collection channels  17  orthogonal to the projecting direction of the puncture portion  13  is set so that a sufficient strength is provided for the puncture portion  13  during use, and that the collected compositional bodily fluid can be transferred at a sufficient transfer speed by capillary action. 
     For example, when the storage volume of compositional bodily fluid in the storage channels  15  of the substrate  11  is 10 to 600 nl, the cross sectional area may be 200 μm 2  or more, or may be the same as the cross sectional area of the storage channels  15  of the substrate  11  (described later), for purposes such as the collection of a sufficient amount of fluid. 
     Further, when the collection channels  17  are provided as grooves, the opening width may be the same as that of the storage channels  15  of the substrate  11 . For example, when the storage volume of compositional bodily fluid in the storage channels  15  of the substrate  11  is 10 to 600 nl, the opening width may be 10 to 30 μm. 
     When the collection channels  17  are provided as grooves on the puncture portion  13  having the jagged surface portion  25  on the lateral periphery, it is preferable that the collection channels  17  continuously open to outside on the surface of the jags. In this way, the collection channels  17  can have a wide contact area with the compositional bodily fluid, facilitating the fluid collection. 
     The collection channels  17  may be provided as a single channel. However, providing a plurality of collection channels  17  as in this embodiment is more preferable because it helps increase the amount of collection, and the area of the inner wall surfaces in contact with the compositional bodily fluid. 
     The substrate  11  of the apparatus for containing sampled liquid  10  is described below. 
     As illustrated in  FIG. 1 , the substrate  11  is planar in shape, and includes the puncture portion  13  in such an arrangement that the puncture portion  13  is puncturable into an organism. The storage channels  15  in communication with the collection channels  17  are provided on one side of the substrate  11 . For handling such as operability, the portion of the substrate  11  opposite from the puncture portion  13  is provided with a receptacle where the storage channels  15  are not disposed. 
     The shape, size, or other configuration of the substrate  11  is not particularly limited, as long as the puncture portion  13  can be provided, and the storage channels  15  can be formed to ensure a desired storage volume. 
     The storage channels  15  of the substrate  11  are configured so that the compositional bodily fluid transferred from the collection channels  17  of the puncture portion  13  can be stored therein by capillary action transfer. The storage channels  15  are compartmentalized by their inner wall surfaces along the axis line. It is not preferable to slope the inner wall surfaces with an abrupt angle with respect to the axis line of the storage channels  15  over the entire length. 
     The storage channels  15  may be open to atmosphere over the entire length, or may be hollow pores except at an innermost portion  36  open to atmosphere. With the storage channels  15  open to atmosphere, the gas inside the storage channels  15  can easily be released during the transfer and storage of the compositional bodily fluid. With the storage channels  15  provided as hollow pores, the contact area with the compositional bodily fluid transferred in the storage channels  15  can be increased to help increase the capillary force for the transfer of the compositional bodily fluid. The hollow pores can be formed by covering the grooved storage channels with a member such as a plate. For example, a plate prepared to include grooves symmetrical to the storage channels  15  is mated with the storage channels  15  to form the hollow pores. 
     In this embodiment, the storage channels  15  are provided as grooves open to atmosphere over the entire length. The grooved channels are easy to form, and enable the gas inside the storage channels  15  to be easily released. The open channel configuration is preferable because it helps release the gas from the channels and enables the transfer and storage of the compositional bodily fluid introduced from different directions at the same time, particularly in partial storage channels  31   x  configured to introduce the compositional bodily fluid from different directions, as will be described later. 
     As illustrated in  FIG. 1 , the storage channels  15  are configured to include branched portions  33   x  and  33   y,  and bent or curved inflecting portions  35   x  and  35   y,  spreading out two-dimensionally in the plane of the substrate  11 . Each branched portion  33   x  is in communication with the partial storage channel  31   x  disposed between the branched portions  33   x;  partial storage channels  31   y  in communication with the collection channels  17 ; partial storage channels  31   z  linearly disposed between the branched portions  33   x  and the branched portions  33   y;  and partial storage channels  31   w  disposed with inflecting portions  35   x  and  35   y  between the branched portions  33   x  and the branched portions  33   y.  Each branched portion  33   y  is in communication with the partial storage channel  31   x  disposed between the branched portions  33   y;  the partial storage channels  31   z;  and the partial storage channels  31   w.  In the storage channels  15 , the innermost portion  36  is defined by the partial storage channels  31   w.    
     By the provision of the branched portions  33   x  and  33   y,  the compositional bodily fluid can be transferred by being branched into the partial storage channels  31   w,    31   x,  and  31   z.  This configuration is more preferable than the arrangement without the branched portions  33   x  and  33   y,  because it reduces the transfer distance of the compositional bodily fluid in the storage channels  15 , and therefore the storage time of the compositional bodily fluid. 
     The cross section of the partial storage channels  31   w,    31   x,    31   y,    31   z  of the storage channels  15  orthogonal to the axis line may have any shape, such as an arc, a substantially triangular shape (substantially V-shaped), or a substantially quadrangular shape (substantially U-shaped). It is preferable that the partial storage channels  31   w,    31   x,    31   y,    31   z  in communication with one another via the branched portions  33   x  and  33   y  have the same or similar cross sectional shape orthogonal to the axis line. With the same or similar cross sectional shape, the cross sections of these portions will resemble or match along the entire channels. This helps prevent formation of steps between the inner wall surfaces of the partial storage channel  31   w,    31   x,    31   y,    31   z  at the branched portions  33   x  and  33   y,  particularly when the channels have the same cross sectional shape. Here, the partial storage channel  31   w,    31   x,    31   y,    31   z  are all substantially quadrangular in shape (substantially U-shaped), because helps increase the cross sectional area for a given opening width. 
     The storage channels  15  must have a volume large enough to store a sufficient amount of compositional bodily fluid for intended measurements, analyses, or other processing. For example, the total storage volume of the storage channels  15  for the compositional bodily fluid may be 10 to 600 nl. 
     It is preferable that the cross sectional areas of the partial storage channels  31   w,    31   x,    31   y,    31   z  orthogonal to the axis line be set to enable a desired amount of compositional bodily fluid to be transferred by capillary action at a sufficient transfer speed. For example, when the storage volume of compositional bodily fluid in the storage channels  15  is 10 to 600 nl, the cross sectional area is preferably 200 to 1,800 μm 2 . When the cross sectional area is excessively small, the entire length of the partial storage channels  31   w,    31   x,    31   y,    31   z  tends to increase, which increases the space required to dispose the storage channels  15 . Further, an excessively small cross sectional area causes undesirable effects such as increased fluid resistance, and the speed of capillary action transfer tends to decrease. On the other hand, when the cross sectional area is too large, the surface tension for a given storage volume of the compositional bodily fluid tends to decrease, which tends to reduce the speed of capillary action transfer. The cross sectional area may be continuously increased or decreased along the axis line within the same partial storage channels  31   w,    31   x,    31   y,  and  31   z.    
     The opening width of the grooved, partial storage channels  31   w,    31   x,    31   y,    31   z  may be set so as to make molding of uniform inner wall surfaces easier, and to obtain a sufficient surface tension. For example, when the storage volume of the storage channels  15  is 10 to 600 nl, the opening width may be 10 to 30 μm. 
     It is preferable that the inner wall surfaces of the partial storage channels  31   y  in communication with the collection channels  17  of the puncture portion  13  be continuous to the inner wall surfaces of the collection channels  17  without any steps. This helps the capillary action transfer of the compositional bodily fluid from the collection channels  17  to the storage channels  15 . Here, the collection channels  17  of the puncture portion  13 , and the partial storage channels  31   y  have the same cross sectional shape orthogonal to the axis line, and are continuous without any clear boundary. 
     In the storage channels  15 , when the inner wall surfaces have an altered shape portion where the shape of the storage channels  15  changes, the contact state between the compositional bodily fluid and the inner wall surfaces, for example, such as the wettability of the inner wall surfaces, and fluid resistance, tend to change in portions separated by the altered shape portion. This makes it difficult to smoothly transfer the compositional bodily fluid, particularly when there is an abrupt change in the altered shape portion, such as in large steps, and discontinuous portions on the inner wall surfaces. 
     Because the storage channels  15  includes the inflecting portions  35   x  and  35   y,  at least a part of the inner wall surfaces at these portions undergoes a geometrical change by being curved or bent. Further, at the branched portions  33   x  and  33   y,  because at least three partial storage channels,  31   w,    31   x,    31   y,  or  31   z,  are in communication with one another, at least a part of the inner wall surfaces undergoes a geometrical change by being curved or bent, while the other inner wall surfaces are discontinuous. Thus, the inflecting portions  35   x  and  35   y  and the branched portions  33   x  and  33   y  tend to prevent a smooth capillary action transfer of the compositional bodily fluid, and storage of a sufficient amount of compositional bodily fluid in a short time period. The transfer of the compositional bodily fluid may not be possible at all when there is a step or other obstacles in these portions. 
     To avoid such problems, the inflecting portions  35   x  and  35   y  and the branched portions  33   x  and  33   y  in the storage channels  15  must be shaped to enable capillary action transfer of the compositional bodily fluid. 
     In one exemplary configuration of the inflecting portions  35   x  and  35   y  and the branched portions  33   x  and  33   y  that enables capillary action transfer of the compositional bodily fluid, it is preferable that at least a part of the inner wall surfaces of the storage channels  15  be continuous in the inflecting portions  35   x  and  35   y  and the branched portions  33   x  and  33   y  without substantially any step. As used herein, “to be continuous without substantially any step” means that the surfaces are continuous without any portions where the wettability of the compositional bodily fluid transferred in the storage channels  15  varies discontinuously, or portions where the fluid resistance for the transferred compositional bodily fluid varies discontinuously, such as in projections or other jags, and bent surfaces with an apex. 
     For example, at the inflecting portions  35   x  and  35   y,  at least a part of the inner wall surfaces, preferably all of the inner wall surfaces may be flat or curved surfaces that are smoothly continuous to the adjacent inner wall surfaces of the storage channels  15  on the both sides. Further, at the branched portions  33   x  and  33   y,  when the cross sectional shape of the partial storage channels  31   w,    31   x,    31   y,  and  31   z  is substantially quadrangular (substantially U-shaped), at least a part of the inner wall surfaces, preferably a pair of the inner wall surfaces in the plane of the substrate  11  may be flat or curved surfaces that are smoothly continuous to the inner wall surfaces of the partial storage channels  31   w,    31   x,    31   y,  and  31   z  in communication with one another via the branched portions  33   x  and  33   y.  Further, when the cross sectional shape of the partial storage channels  31   w,    31   x,    31   y,  and  31   z  is substantially triangular (substantially V-shaped) or arc-like, the inner wall surface(s) and/or the edge facing the inner wall surface in the plane of the substrate  11  may be a flat or curved surface(s), or a straight or curved line, that is smoothly continuous to the inner wall surfaces and/or the edges of the partial storage channels  31   w,    31   x;    31   y,  and  31   z  in communication with one another via the branched portions  33   x  and  33   y.    
     In this embodiment, the cross sectional shapes of the partial storage channels  31   w,    31   x,    31   y,  and  31   z  are substantially quadrangular (substantially U-shaped). At the inflecting portions  35   x  and  35   y,  the bottom surface of the groove in the partial storage channels  31   w  is a smooth, continuous flat surface, and the side surfaces of the groove are smooth, continuous curved surfaces. At the branched portions  33   x  and  33   y,  as illustrated in  FIG. 3A  through  FIG. 3C , bottom surfaces  33   a  of the groove are flat surfaces that are smoothly continuous to bottom surfaces  31   a  of the partial storage channels  31 . Further, the bottom surfaces  31   a  of the groove in the partial storage channels  31   w,    31   x,    31   y,  and  31   z,  and the bottom surfaces  33   a  in the branched portions  33   x  and  33   y  form a flat, continuous surface over the entire length of the storage channels  15  within the two-dimensional plane of the substrate  11 . The depth of the groove is uniform. This makes it easier to transfer the transferred compositional bodily fluid along the bottom surfaces  31   a  and  33   a,  facilitating a smooth transfer of the compositional bodily fluid throughout the storage channels  15 . 
     In another exemplary configuration of the inflecting portions  35   x  and  35   y  and the branched portions  33   x  and  33   y  that enables capillary action transfer of the compositional bodily fluid, the partial storage channels  31   w,    31   x,    31   y,  and  31   z  may be formed so that a maximum value-to-minimum value ratio of the channel cross sectional area orthogonal to the axis line of these channels is 2.5 or less at the ends of the partial storage channels  31   w,    31   x,    31   y,  and  31   z  adjacent to the branched portions  33   x  and  33   y.  In this range, there will not be large differences in the capillary force transferring the compositional bodily fluid, or in the fluid resistance between the partial storage channels  31   w,    31   x,    31   y,  and  31   z,  making it possible to equally transfer the compositional bodily fluid to the partial storage channels  31   w,    31   x,    31   y,  and  31   z.  Here, the maximum value-to-minimum value ratio of the cross sectional area orthogonal to the axis line of the channels is preferably 2.5 or less throughout the storage channels  15  except at the branched portions  33   x  and  33   y.  It is particularly preferable, as in this embodiment, that the cross sections of all the partial storage channels  31   w,    31   x,    31   y,  and  31   z  orthogonal to the axis line have the same shape over the entire length, because it helps prevent formation of large steps at the branched portions  33   x  and  33   y.    
     As required, electrodes or various other components, or chemicals such as enzymes and DNA fragments for the measurement, analysis, or other processing of the compositional bodily fluid may be disposed on the substrate  11 , in contact with the storage channels  15 . 
     The apparatus for containing sampled liquid  10  is made of biocompatible material. Examples of the biocompatible material include high molecular polymers, biopolymers, proteins, and biocompatible inorganic materials. 
     The high molecular polymer is preferably those usable in medical applications, for example, such as polyvinyl chloride, polyethylene glycol, parylene, polyethylene, polypropylene, silicone, polyisoprene, polymethyl methacrylate, fluorocarbon resin, polyether imide, polyethylene oxide, polyethylene terephthalate, polyethylene succinate, polybutylene terephthalate, polybutylene succinate, polybutylene succinate carbonate, polyphenylene oxide, polyphenylene sulfide, polyformaldehyde, polyanhydride, polyamide (nylon 6, nylon 66), polybutadiene, polyvinyl acetate, polyvinyl alcohol, polyvinyl pyrrolidone, polyester amide, polymethyl methacrylate, polyacrylonitrile, polysulfone, polyethersulfone, ABS resin, polycarbonate, polyurethane (polyether urethane, polyester urethane, polyether urethane urea), polyvinylidene chloride, polystyrene, polyacetal, polybutadiene, ethylene-vinyl acetate copolymer, ethylene-vinyl alcohol copolymer, ethylene-propylene copolymer, polyhydroxyethyl methacrylate, polyhydroxybutyrate, poly(ortho ester), polylactic acid, polyglycol, polycaprolactone, polylactic acid copolymer, polyglycolic acid.glycol copolymer, polycaprolactone copolymer, polydioxanone, perfluoroethylene-propylene copolymer, cyanoacrylate polymer, polybutyl cyanoacrylate, polyallyl ether ketone, epoxy resin, polyester resin, polyimide, phenol resin, and acrylic resin. 
     Examples of the biopolymer include cellulose, starch, chitin.chitosan, agar, carrageenan, alginic acid, agarose, pullulan, mannan, curdlan, xanthan gum, gellan gum, pectin, xyloglucan, guar gum, lignin, oligosaccharide, hyaluronan, schizophyllan, and lentinan. Examples of the protein include collagen, gelatin, keratin, fibroin, glue, sericin, vegetable protein, milk protein, egg protein, synthetic protein, heparin, and nucleic acid. Other examples include sugars, syrup, glucose, maltose, sucrose, and a polymer alloy thereof. 
     Examples of the biocompatible inorganic material include: ceramics such as glass; nanocomposite ceramics; Al 2 O 3 /ZrO 2  composite ceramics; Si 3 N 4  nanocomposite materials; hydroxyapatite; calcium carbonate; carbon; graphite (nanografiber); carbon nanotubes (CNT); fullerene composite materials; hydroxyapatite.polymer composite materials; cobalt-chromium alloys; stainless steel; titanium; and titanium alloys. 
     Among these biocompatible materials, it is preferable to use biodegradable polymers that contain materials, for example, such polylactic acid, polyglycolic acid, polycaprolactone, collagen, starch, hyaluronan, alginic acid, chitin, chitosan, cellulose, and gelatin. Use of biodegradable materials made of these compounds is also preferable. These materials are preferable because they decompose in a microbe environment, which makes the disposal of the apparatus for containing sampled liquid  10  easier after use. 
     Use of polylactic acid is particularly preferable. Because polylactic acid is moderately compatible to the compositional bodily fluid, it makes it easier to collect, transfer, and store the compositional bodily fluid by capillary action through the collection channels  17  and the storage channels  15 . Polylactic acid also helps prevent excessive adsorption of the components contained in the compositional bodily fluid. 
     In the apparatus for containing sampled liquid  10  made of biocompatible materials, it is preferable to perform a biocompatibility enhancing treatment on the surface of the apparatus for containing sampled liquid  10 , or at least on the inner wall surfaces of the collection channels  17  and the storage channels  15 . 
     The biocompatibility enhancing treatment is intended to adjust compatibility to the compositional bodily fluid, or help prevent adsorption of the compositional bodily fluid components, by modifying the surface in contact with the compositional bodily fluid, or applying a surface treatment agent. 
     The biocompatibility enhancing treatment that adjusts compatibility to the compositional bodily fluid can be performed, for example, by applying and immobilizing chemicals such as polyethylene glycol, sodium hydroxide, polysorbate, Poloxamer, and silicone. 
     The biocompatibility enhancing treatment that helps prevent adsorption of the compositional bodily fluid components can be performed, for example, by applying and immobilizing chemicals such as heparin, phosphoric acid, polyethylene glycol, sodium hydroxide, polysorbate, Poloxamer, and silicone. 
     The compatibility to the compositional bodily fluid can be evaluated by, for example, the size of the contact angle, although the invention is not so limited. With the compatibility appropriately selected this way, the capillary action collection and storage of the compositional bodily fluid in the collection channels  17  and the storage channels  15  becomes easier. It is preferable to prevent adsorption of the compositional bodily fluid components as much as possible, and, for this purpose, the agent may be appropriately applied to such an extent that the compatibility to the compositional bodily fluid is not inhibited. 
     The method for producing the apparatus for containing sampled liquid  10  configured as above is not particularly limited. In one exemplary method, the puncture portion  13  and the substrate  11  are molded as an integral unit using the foregoing materials, and the collection channels  17  and the storage channels  15  are formed thereon using, for example, an excimer laser. In another exemplary method, the puncture portion  13  and the substrate  11  are formed as an integral unit using a mold having patterns for the collection channels  17  and the storage channels  15 , followed by various biocompatibility enhancing treatments as required. 
     The measurement, analysis, or other processing of the compositional bodily fluid using the apparatus for containing sampled liquid  10  can be performed as follows. 
     First, the apparatus for containing sampled liquid  10  illustrated in  FIG. 1  is held on an operating holder (not shown) using the receptacle of the substrate  11  on the opposite end of the puncture portion  13 . By holding the operating holder, the puncture portion  13  is punctured into an organism from the side of the end point  23 . The insertion of the puncture portion  13  places the jagged surface portion  25  inside the organism, and the openings of the collection channels  17  continuously formed along the jags of the jagged surface portion  25  will be in contact with the compositional bodily fluid. The compositional bodily fluid in contact with the openings of the collection channels  17  is then collected into the collection channels  17  under the pressure of the organism and by capillary action. 
     The compositional bodily fluid in each collection channel  17  is transferred toward the substrate  11  by capillary action as it is collected. The capillary action transfers the compositional bodily fluid from the collection channels  17  to the partial storage channels  31   y  in communication with the collection channels  17 . Here, because the inner wall surfaces of the collection channels  17  are continuous to the inner wall surfaces of the partial storage channels  31  without steps, the compositional bodily fluid in the collection channels  17  is smoothly transferred into the partial storage channels  31   y.  The transferred compositional bodily fluid reaches the branched portions  33   x.    
     At each branched portion  33   x,  as illustrated in  FIG. 3A  through  FIG. 3C , side surfaces  31   b  of each partial storage channel  31   y  bend and join to one of the side surfaces  31   c  of the partial storage channel  31   w,  and one of the side surfaces  31   d  of the partial storage channel  31   x.  The side surfaces  31   b  are discontinuous to the other surfaces of the side surfaces  31   c  and  31   d.  The side surfaces  31   b  of each partial storage channel  31   y  are also discontinuous to side surfaces  31   e  of the partial storage channel  31   z.  However, because the bottom surface  31   a  of the partial storage channels  31   y  is a flat surface that is continuous to the bottom surfaces  31   a  of the other partial storage channels  31   w,    31   x,  and  31   z  via the bottom surface  33   a  of each branched portion  33   x,  the compositional bodily fluid that has reached the branched portions  33   x  is equally introduced, via the bottom surface  33   a  of each branched portion  33   x,  to the bottom surfaces  31   a  of the partial storage channels  31   w,    31   x,  and  31   z  connected to the branched portions  33   x.    
     The compositional bodily fluid introduced into the partial storage channels  31   w,    31   x,  and  31   z  is further transferred by capillary action in each channel. The compositional bodily fluid transferred through the partial storage channels  31   z  reaches the branched portions  33   y,  and, as in the branched portions  33   x,  is introduced into the partial storage channels  31   x  and  31   w  before it reaches the innermost portion  36  defined by the partial storage channel  31   w.  Here, the compositional bodily fluid is introduced in two different directions in the partial storage channel  31   x  connecting the branched portions  33   x,  and in each partial storage channel  31   w  connecting the branched portion  33   x  and the branched portion  33   y.  However, because the partial storage channels  31   x  and  31   w  are open to atmosphere, the gas inside the partial storage channels  31   x  and  31   w  can be released to outside, and the transfer and storage of the compositional bodily fluid is possible over the entire length of the partial storage channels  31   x  and  31   w,  even when the compositional bodily fluid is transferred from the both sides at the same time. 
     The storage of the compositional bodily fluid completes when the compositional bodily fluid is transferred throughout the storage channels  15 . 
     The measurement, analysis, or other processing of the compositional bodily fluid stored in the storage channels  15  is performed in this state. This completes the use of the apparatus for containing sampled liquid  10 . 
     In the apparatus for containing sampled liquid  10  as above, the compositional bodily fluid is transferred by capillary action and stored in the storage channels  15 . Because this does not require driving means for the collection of the compositional bodily fluid, the apparatus for containing sampled liquid  10  can be realized with a simple configuration. 
     Further, because the storage channels  15  include the branched portions  33   x  and  33   y  and the inflecting portions  35   x  and  35   y  shaped to enable capillary action transfer of the compositional bodily fluid, the total length of the storage channels  15  can be increased by simply increasing the number of the partial storage channels  31   w,    31   x,    31   y,  and  31   z.  This helps increase the total volume of the storage channels  15 . Further, the inner wall surfaces of the storage channels  15  in contact with the compositional bodily fluid can be increased for a given storage volume of the compositional bodily fluid. This helps increase the capillary force for the transfer of the compositional bodily fluid. 
     The storage channels  15  include a bent portion or a discontinuous portion in part of the inner wall surfaces at the branched portions  33   x  and  33   y.  However, because the inner wall surfaces of the storage channels  15  include a continuous bottom surface over substantially the entire length of the storage channels  15  without substantially any step, the capillary force for the transfer of the compositional bodily fluid from the partial storage channels  31   y  to the other partial storage channels  31   w,    31   x,  and  31   z  via the branched portions  33   x  and  33   y  can easily be sustained to enable a smooth capillary action transfer of the compositional bodily fluid to the partial storage channels  31   w,    31   x,  and  31   z.    
     This facilitates the storage of a sufficient amount of compositional bodily fluid in the storage channels  15  in a short time period, and the measurement, analysis, and other processing of the compositional bodily fluid can be sufficiently performed with ease even when the number or size of the collection channels in the puncture portion  13  is restricted by the size of the puncture portion  13  reduced in size to relieve the burden on the organism undergoing the collection. 
     In this embodiment, the branched portions  33   x  and  33   y  are described as portions where the inner wall surfaces of the partial storage channels  31   w,    31   x,    31   y,  and  31   z  directly join. Alternatively, as illustrated in  FIG. 5B  (described later in conjunction with Examples), the inner wall surfaces of the partial storage channels  31  may be connected to each other via the inner wall surfaces of the branched portion  33 , without an inflecting portion. 
     Further, the invention is not limited to the example in which the storage channels  15  include the branched portions  33   x  and  33   y  and the inflecting portions  35   x  and  35   y.  The configuration of the storage channels  15  can be appropriately designed. For example, as illustrated in  FIG. 5C  (described later in conjunction with Examples), channels with a plurality of inflecting portions may be provided, using only a few branched portions, if any. 
     In the exemplary configuration described above, the bottom surface  31   a  and the side surfaces of the partial storage channels  31   y  form flat, continuous surfaces with the bottom surface  17   a  and the side surfaces of the collection channels  17 . The bottom surfaces  31   a  of the partial storage channels  31   w,    31   x,  and  31   z  also form flat, continuous surfaces with the bottom surfaces  33   a  of the branched portions  33   x  and  33   y.  However, these continuous surfaces may be curved or slanted surfaces. 
     In this embodiment, the partial storage channels  31   w,    31   x,    31   y,  and  31   z  are described as having the same cross sectional shape orthogonal to the axis line. However, these cross sectional shapes may be different either entirely or partially. In this case, the partial storage channels  31   w,    31   x,    31   y,  and  31   z  may have different widths and the same depth, or may be shaped to have different depths. 
     Further, the invention is not limited to the arrangement in which the storage channels  15  in communication with the two collection channels  17  are one system of channels that are in communication with one another. The storage channels  15  in communication with the collection channels  17  may be channels of different systems that are not in communication with one another. 
     The storage channels  15  are described as being provided on one side of the substrate  11 . However, the storage channels  15  may be provided on the both sides of the substrate  11  to help increase the storage volume. 
     In the exemplary configuration above, the measurement, analysis, or other processing of the compositional bodily fluid may be performed in any portion in contact with the storage channels  15 . However, the site of measurement, analysis, or other processing may be specifically designated. For example, as illustrated in  FIG. 4 , the partial storage channels  31  may be provided as large numbers of dense channels to form a dense portion  37  at a position distant from the puncture portion  13  of the substrate  11 , and a measurement unit  39  may be provided in contact with the partial storage channels  31   y  disposed in communication with the collection channels  17  of the puncture portion  13  and the dense portion  37  in between. With this arrangement, the compositional bodily fluid collected in the collection channels  17  during the collection procedure can be transferred through the partial storage channels  31   y  by the capillary action driven by the dense portion  37 , enabling the measurement, analysis, or other processing of the compositional bodily fluid. The dense portion  37  can thus be used as the driving section for the transfer of the compositional bodily fluid. 
     In this embodiment, the puncture portion  13  is described as having the jagged surface portion  25 . However, the puncture portion  13  may have a uniform surface with no jags. 
     EXAMPLES 
     Examples of the invention are described below. 
     Examples 1 to 7  
     Seven kinds of test pieces were produced by injection molding using polylactic acid. Each test piece is a planar strip (length, 4 mm; width, 2 mm; thickness, 100 μm), and has planar storage channels  15 , illustrated in  FIG. 5A  through  FIG. 5G , and two collection channels  17  on one of the surfaces. The storage channels  15  and the collection channels  17  were formed as open grooves with substantially quadrangular (substantially U-shaped) cross sections (width, 20 μm; depth, 40 μm) orthogonal to the axis line. 
     Pseudo blood was dropped over the two collection channels  17  of each test piece, and the state of the pseudo blood was observed as it was transferred and stored in the storage channels  15 . 
     The planar shape of the storage channels  15  of each test piece is as follows. 
     Example 1 
     As illustrated in  FIG. 5A , straight partial storage channels  31  are crossed at a right angle to form two branched portions  33 . Each branched portion  33  is in communication with the straight partial storage channels  31  branching out in four directions. 
     Example 2 
     As illustrated in  FIG. 5B , straight partial storage channels  31  are disposed to successively branch out in a fan-like fashion at branched portions  33 , each of which is in communication with the partial storage channels  31  branching out in three directions. The inner wall surfaces of the partial storage channels  31  in a conduction path join together via the inner wall surfaces of the branched portion  33 . 
     Example 3 
     As illustrated in  FIG. 5C , two straight partial storage channels  31  are successively joined to a semicircular inflecting portion  35  at bending inflecting portions  35  to form a continuous, semicircular concentric spiral. 
     Example 4 
     As illustrated in  FIG. 5D , straight partial storage channels  31  and semicircular inflecting portions  35  are joined at large numbers of branched portions  33  to branch out in four directions at the branched portions  33  in a concentric circle. 
     Example 5 
     As illustrated in  FIG. 5E , arc-shaped inflecting portions  35 , and straight partial storage channels  31  radially extending out from the center of the arc are joined at branched portions  33 , so that each branched portion  33  is in communication with the arc-shaped inflecting portions  35  and the straight partial storage channels  31  branching out in three or four directions in a half circle with radiating lines. 
     Example 6 
     As illustrated in  FIG. 5F , large numbers of straight partial storage channels  31  are joined at a right angle to form a lattice so that the straight partial storage channels  31  branch out in four directions at branched portions  33  in communication therewith. 
     Example 7 
     As illustrated in  FIG. 5G , large numbers of straight partial storage channels  31  are crossed so that the straight partial storage channels  31  join or branch out at branched portions  33  and bent portions  34 . Each branched portion  33  is in communication with the straight partial storage channels  31  branching out in four directions. Each bent portion  34  is in communication with the straight partial storage channels  31  branching out in two directions. 
     The observation of the pseudo blood dropped on each test piece of Examples 1 to 7 revealed that the storage channels  15  of these examples are all capable of transferring and storing the pseudo blood. 
     Comparative Example 1 
     The state of the pseudo blood being transferred and stored was observed as in Examples 1 to 7, except that a circular recess (diameter, 500 μm; depth, 50 μm) was provided at the end of each collection channel  17  instead of the storage channel  15 . The maximum cross sectional area of the circular recess was greater than that of the collection channels  17  by a factor of about 42. 
     The transfer of the pseudo blood stopped at the end of the collection channels  17 , and the pseudo blood was not stored in the circular recess. 
     Comparative Example 2 
     The state of the pseudo blood being transferred and stored was observed as in Example 1, except that the width of the storage channels  15  orthogonal to the axis line was 20 μm over the entire length, that the depth of the partial storage channels  31  between the collection channels  17  and the branched portions  33  was 40 μm, that the depth of the partial storage channels in communication with one another via the branched portions  33  was 50 μm, and that these partial storage channels were discontinuous at the branched portions  33 . 
     The transfer of the pseudo blood stopped at the branched portions  33 , and the pseudo blood was not stored in the partial storage channel  31 . 
     NUMERALS 
     
         
           10  Apparatus for containing sampled liquid 
           11  Substrate 
           13  Puncture portion 
           15  Storage channel 
           17  Collection channel 
           25  jagged surface portion 
           31  Partial storage channel 
           31   a  Bottom surface 
           33  Branched portion 
           33   a  Bottom surface 
           34  Bent portion 
           35  Curved portion