Abstract:
A bacteria analyzer comprising: a sample preparing section for preparing a measurement sample from a specimen; a detector for detecting bacteria contained in the measurement sample prepared by the sample preparing section; and a controller including a memory under control of a processor, the memory storing instructions enabling the processor to carry out operations, comprising: obtaining the distribution state of bacteria detected by the detector; setting a bacteria count region according to the obtained bacteria distribution state; and counting the number of bacteria contained in the set bacteria count region is disclosed. Method for analyzing bacteria, and a computer program product for bacteria analyzer are also disclosed.

Description:
RELATED APPLICATIONS 
       [0001]    This application claims priority under 35 U.S.C. §119 to Japanese Patent Application No. 2008-279008 filed on Oct. 30, 2008 and Japanese Patent Application No. 2009-187935 filed on Aug. 14, 2009, the entire content of which is hereby incorporated by reference. 
       FIELD OF THE INVENTION 
       [0002]    The present invention relates to a bacteria analyzer, a method for analyzing bacteria, and a computer program product for analyzing bacteria contained in a sample such as blood, urine and the like. 
       BACKGROUND 
       [0003]    Conventional bacteria analyzers are known for analyzing bacteria contained in samples such as blood, urine and the like using flow cytometry (for example, refer to EP1136563, U.S. Laid-Open Patent No. 2004-219627). 
         [0004]    The bacteria detection method disclosed in EP1136563 creates a two-dimensional distribution diagram based on a combination of the forward scattered light intensity and the forward scattered light pulse width. Groups including bacteria are identified using the two-dimensional distribution diagram, and a new two-dimensional diagram is created based on the combination of the forward scattered light intensity and the fluorescent light intensity only for the identified groups. In this way bacteria can be separated from other components (crystals, broken cells and other impurities) according to the differences in fluorescent light intensity, and the number of bacteria can be more precisely counted. 
         [0005]    The bacteria measuring method disclosed in U.S. Laid-Open Patent No: 2004-219627 differentiates bacilli and cocci based on differences of slope in the bacteria distribution states. In order to distinguish between bacteria and other components (crystals, broken cells and other impurities), a scattergram is prepared beforehand by plotting the forward scattered light intensity and fluorescent light intensity on the two axes and presetting the range in which bacteria appear in the scattergram, then counting the number of particles appearing within the set range as the number of bacteria. 
         [0006]    The ranges in which bacteria appear in the scattergram differ greatly depending on the type of bacteria and state of proliferation. There are therefore normally circumstances under which a large number of bacteria may appear in a region in which impurities appear depending on the type of bacteria and state of proliferation. In the disclosures of EP1136563 and U.S Laid-Open Patent No. 2004-219627, however, a large number of bacteria may appear in region with impurities when a fixed region is set as the bacteria count region regardless of the type of bacteria and state of proliferation, such that there is need for improved precision in the bacteria count because in such instances bacteria in the impurity region may be excluded from the count object. 
       SUMMARY 
       [0007]    The scope of the invention is defined solely by the appended claims, and is not affected to any degree by the statements within this summary. 
         [0008]    A first aspect of the invention is a bacteria analyzer comprising: a sample preparing section for preparing a measurement sample from a specimen; a detector for detecting bacteria contained in the measurement sample prepared by the sample preparing section; and a controller including a memory under control of a processor, the memory storing instructions enabling the processor to carry out operations, comprising: obtaining the distribution state of bacteria detected by the detector; setting a bacteria count region according to the obtained bacteria distribution state; and counting the number of bacteria contained in the set bacteria count region. 
         [0009]    A second aspect of the invention is a bacteria analyzer comprising: a sample preparing section for preparing a measurement sample from a specimen; a detector for detecting bacteria contained in the measurement sample prepared by the sample preparing section; an obtaining means for obtaining the distribution state of bacteria detected by the detector; a setting means for setting a bacteria count region according to the obtained bacteria distribution state; and a counting means for counting the number of bacteria contained in the set bacteria count region. 
         [0010]    A third aspect of the invention is method for analyzing bacteria capable of being performed by a bacteria analyzer, the analyzer comprising a sample preparing section for preparing a measurement sample, and a detector for detecting bacteria contained in the measurement sample prepared by the sample preparing section, comprising: obtaining the distribution state of bacteria detected by the detector; setting a bacteria count region according to the obtained bacteria distribution state; and counting the number of bacteria contained in the set bacteria count region. 
         [0011]    A fourth aspect of the invention is a computer program product for a bacteria analyzer comprising a sample preparing section for preparing a measurement sample and a detector for detecting the bacteria contained in the measurement sample prepared by the sample preparing section, the computer program product comprising a computer readable medium storing instructions adapted to enable a bacteria analyzer to carry out operations, comprising: obtaining the distribution state of bacteria detected by the detector; setting a bacteria count region according to the obtained bacteria distribution state; and counting the number of bacteria contained in the set bacteria count region. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0012]      FIG. 1  is a perspective view schematically showing an embodiment of the bacteria analyzer of the present invention; 
           [0013]      FIG. 2  is a block diagram showing the structure of the measuring device of the embodiment of the bacteria analyzer of the present invention; 
           [0014]      FIG. 3  is a block diagram schematically showing the structure of the detector and sample preparation section of the embodiment of the present invention; 
           [0015]      FIG. 4  is a block diagram schematically showing the analog processing unit and detector of the embodiment of the present invention; 
           [0016]      FIG. 5  is a block diagram showing the structure of the operation and display device of the embodiment of the bacteria analyzer of the present invention; 
           [0017]      FIG. 6  shows an example of a bacteria measurement result screen displayed on the operation and display device; 
           [0018]      FIG. 7A  is a scattergram obtained from a measurement sample containing  Escherichia coli  ( E. coli ); 
           [0019]      FIG. 7B  is a scattergram obtained from a measurement sample containing  Bacillus  bacteria; 
           [0020]      FIG. 7C  is a scattergram obtained from a measurement sample containing  Pseudomonas aeruginosa;    
           [0021]      FIG. 7D  is a scattergram obtained from a measurement sample containing  Staphylococcus aureus;    
           [0022]      FIG. 8  is a comparison of a viable count by culture method and bacteria count in a first count region and a second count region; 
           [0023]      FIGS. 9A through 9D  show examples of the relationship between the count number and the forward scattered light intensity in a scattergram; 
           [0024]      FIG. 9A  is based on a scattergram obtained from a measurement sample containing  Escherichia coli  ( E. coli ); 
           [0025]      FIG. 9B  is based on a scattergram obtained from a measurement sample containing  Bacillus bacteria;    
           [0026]      FIG. 9C  is based on a scattergram obtained from a measurement sample containing  Pseudomonas aeruginosa;    
           [0027]      FIG. 9D  is based on a scattergram obtained from a measurement sample containing  Staphylococcus aureus;    
           [0028]      FIG. 10  compares the results of counting bacteria present in bacteria count regions set by three setting methods and a general viable count by culture method using Heart-Infusion agar medium and urine samples collected from three patients; and 
           [0029]      FIG. 11  is a flow chart showing the sequence of the bacteria counting process performed by the CPU of the operation and display device of the embodiment of the bacteria analyzer of the present invention. 
       
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       [0030]    Hereinafter, embodiments of a sample analyzer of the invention will be described in detail with reference to the accompanying drawings. 
         [0031]    The bacteria analyzer of the present embodiment is described below by way of example of a urine analyzer for analyzing urine with specific reference to the drawings. 
         [0032]      FIG. 1  is a perspective view schematically showing an embodiment of the bacteria analyzer of the present invention. As shown in  FIG. 1 , the bacteria analyzer of the present embodiment is configured by a measuring device  1 , and an operation and display device  2  which is connected to the measuring device  1  so as to be capable of data communication. 
         [0033]    The measuring device  1  and the operation and display device  2  are connected via a communication line, which is not shown in the drawing, so that the operation of the measuring device  1  can be controlled and measurement data output from the measuring device  1  can be processed to obtain analysis results by mutual data communication. The measuring device  1  and the operation and display device  2  may also be connected over a network, integratedly configured as a single apparatus, and transfer data in inter-process communication. 
         [0034]    The measuring device  1  detects the bacteria in a sample (urine) using flow cytometry, and transmits the detection result to the operation and display device  2  as measurement data. Flow cytometry is a method for detecting particles (bacteria) in a measurement sample by creating a sample flow containing a measurement sample, irradiating the sample flow with laser light, and detecting the light, such as forward scattered light, side scattered light, and side fluorescent light emitted from the particles (bacteria) in the measurement sample. For example, the particles (bacteria) distributed in a scattergram can be counted using a scattergram (two-dimensional distribution diagram) prepared by plotting the forward scattered light intensity and side fluorescent light intensity on the two axes. 
         [0035]    Specifically, a predetermined region in which the bacteria are concentrated in the distribution of the scattergram is set as the bacteria count region, and the particles (bacteria) appearing in the bacteria count region are counted. In the present embodiment, using a scattergram in which the forward scattered light intensity and side fluorescent light intensity are plotted on the two axes, the particles (bacteria) appearing in the set bacteria count region in the scattergram are counted. 
         [0036]    Bacteria which may be present in urine include  Escherichia coli, Bacillus  species,  Pseudomonas aeruginosa, Staphylococcus aureus  and the like, which have different sizes and attributes. The type of bacteria present in the urine differs for each patient subject. The region in which the bacteria appear in the scattergram is different depending on the type of bacteria, and each type of bacterium has a characteristic occurrence pattern. In the present embodiment, the bacteria count region in the scattergram is set according to the bacteria appearance pattern in the scattergram, and the bacteria appearing in the set bacteria count region are counted. 
         [0037]      FIG. 2  is a block diagram showing the structure of the measuring device  1  of the embodiment of the bacteria analyzer of the present invention. The measuring device  1  is provided with a device  4 , detector  5  for performing the measurement of a measurement sample, an analog processor  6  for the output of the detector  5 , operation and display section  7 , and control board  9  for controlling the operation of each hardware part. 
         [0038]    The control board  9  has a controller  91  with a control processor and a memory for operating the control processor, a 12-bit A/D converter  92  for converting the signals output from the analog processor  6  into digital signals, and an operation section  93  for storing the digital signals output from the A/D converter  92  and performing a process to select data output from the controller  91 . The controller  91  is connected to the display/operation section  7  through a bus  94  and an interface  95   b,  and connected to the operation and display device  2  through a bus  94   b  and an interface  95   c.  The operation section  93  outputs an operation result to the controller  91  through an interface  95   d  and a bus  94   a.  The controller  91  also transmits the operation result (measurement data) to the operation and display device  2 . 
         [0039]    The device  4  is provided with a sample preparing section  41  for preparing a measurement sample by fluorescent staining of a sample. The sample preparing section  41  prepares a bacteria count measurement sample.  FIG. 3  is a block diagram schematically showing the structure of the detector  5  and sample preparation section  41  of the embodiment of the present invention. 
         [0040]    In  FIG. 3 , the urine contained in the test tube T 1  is aspirated by a syringe pump (not shown) using an aspirating tube  17 , and then dispensed to the sample preparing section  41  by the sample distribution section  42 . The sample preparing section  41  includes a first sample preparing unit  41   u  and a second sample preparing unit  41   b.  The first sample preparing unit  41   u  accommodates a first sedimentation aliquot for analyzing relatively large tangible components such as red blood cells, white blood cells, epithelial cells and the like; the second sample preparing unit  41   b  accommodates a second bacterial system aliquot for analyzing relatively small tangible components such as bacteria. 
         [0041]    The urine dispensed to the first sample preparing unit  41   u  and the second sample preparing unit  41   b  is respectively diluted with diluting solution  43   u  and  43   b,  and mixed with a staining liquid (staining reagent)  44   u  and  44   b.  A suspension of the tangible components is prepared by respectively staining with the dye contained in the staining liquid  44   u  and  44   b.  The first sample preparing unit  41   u  prepares a first sample for measuring the tangible components containing at least white blood cells, and the second sample preparing unit  41   b  prepares a second sample for measuring bacteria. 
         [0042]    Among the two types of suspensions (measurement samples) prepared in this manner, the suspension (first sample) prepared by the first sample preparing unit  41   u  is first delivered to the detector  5  where a sample flow encapsulated in added sheath fluid is irradiated by laser light in a sheath flow cell  503 . Thereafter, the suspension (second sample) prepared by second sample preparing unit  41   b  is delivered to the detector  5  where a sample flow encapsulated in added sheath fluid is irradiated by laser light in the sheath flow cell  503 . These operations are performed by operating drive units and electromagnetic valves (not shown) controlled by the controller  91 . 
         [0043]      FIG. 4  is a block diagram schematically showing the structure of the detector  5  and analog processor  6  of the embodiment of the present invention. As shown in  FIG. 4 , the detector  5  is configured by a light-emitter  501  for emitting laser light, irradiating lens unit  502 , sheath flow cell  503  for irradiating with laser light, collective lens  504  disposed on a line extending in the direction of travel of the laser light emitted from the light-emitter  501 , pinhole  505  and PD (photodiode)  506  (a beam stopper (not shown) is disposed between the sheath flow cell  503  and the collecting lens  504 ), collective lens  507  disposed in a direction intersecting the direction of travel of the laser light emitted from the light-emitter  501 , dichroic mirror  508 , optical filter  509 , pinhole  510  and APD (avalanche photodiode)  511 , and PD (photodiode)  512  disposed on the side of the dichroic mirror  508 . 
         [0044]    The light-emitter  501  is provided for emitting light on a sample flow containing a measurement sample passing through the interior of the sheath flow cell  503 . The irradiating lens unit  502  is provided for rendering into parallel rays the light emitted from the light-emitter  501 . The PD  506  is provided for receiving the forward scattered light emitted from the sheath flow cell  503 . Note that information can be obtained relating to the size of the particles (blood cells) in the measurement sample from the forward scattered light emitted from the sheath flow cell  503 . 
         [0045]    The dichroic mirror  508  is provided for splitting the side scattered light and side fluorescent light emitted from the sheath flow cell  503 . Specifically, the dichroic mirror  508  is provided for directing the side scattered light emitted from the sheath flow cell  503  to the PD  512 , and directing the side fluorescent light emitted from the sheath flow cell  503  to the APD  511 . The PD  512  is also provided for receiving the side scattered light. Information can be obtained relating to the size of the nucleus of a particle (blood cell) in the measurement sample from the side scattered light emitted from the sheath flow cell  503 . 
         [0046]    The APD  511  is also provided for receiving the side fluorescent light. When light irradiates a fluorescent substance such as a stained blood cell, light is produced that has a longer wavelength than the wavelength of the irradiating light. The fluorescent light intensity becomes stronger as the degree of staining increases. Therefore, the type and attributes of the bacteria can be specified by the side fluorescent light emitted from the sheath flow cell  503 . The PD  506 , PD  512 , and APD  511  convert the respectively received light signal to an electrical signal, which is then respectively amplified by the amplifiers  61 ,  62 ,  63 , and subsequently transmitted to the control board  9 . 
         [0047]      FIG. 5  is a block diagram showing the structure of the operation and display device  2  of the embodiment of the bacteria analyzer of the present invention. As shown in  FIG. 5 , the operation and display device  2  is configured by a CPU (central processing unit)  21 , RAM  22 , memory device  23 , input device  24 , display device  25 , output device  26 , communication interface  27 , portable disk drive  28 , and internal bus  29  connecting all the hardware. The CPU  21  is connected to each hardware part mentioned above of the operation and display device  2  via the internal bus  29 ; the CPU  21  controls the operation of these hardware parts, and executes the functions of various software in conjunction with a computer program  231  stored in the memory device  23 . The RAM  22  is a volatile member configured by SRAM, SDRAM or the like, and is used for developing loaded modules during the execution of the computer program  231 , and for storing temporary data during the execution of the computer program  231 . 
         [0048]    The memory device  23  is configured by an internal ROM, fixed-type storage device (hard disk) or the like. The computer program  231  stored on the memory device  23  may be downloaded from a portable storage medium  90  such as a DVD, CD-ROM or the like for recording information such as programs and data, then expanded from the memory device  23  to the RAM 22  during execution. Of course, the computer program may also be downloaded from an external computer connected to a network through the communication interface  27 . The memory device  23  is also provided with a count range specification information memory  232  for storing count range specification information, which is information necessary for specifying a count range. Information for decision parameters such as the range of mean values of the forward scattered light intensity, distribution width threshold values, and threshold values of the side fluorescent light intensity for exclusion from the count range may be stored as count range specification information. 
         [0049]    The communication interface  27  is connected to the internal bus  29 , and is capable of sending and receiving data via the connection with the measuring device  1  over the communication line. That is, instruction information specifying to start a measurement and the like is transmitted to the measuring device  1 , and measurement data are received. 
         [0050]    The input device  24  is a data input medium such as a keyboard and mouse. The display device  25  is a CRT monitor, LCD or the like, and displays analysis results graphically. The output device  26  is a printing device such as a laser printer, inkjet printer or the like. 
         [0051]    The operation of the bacteria analyzer with the above-mentioned structure is described below. When the bacteria analyzer of the present embodiment counts the bacteria contained in urine, the operation and display device  2  prepares a scattergram based on the measurement data from the measuring device  1 , counts the detected number of bacteria (number of particles) based on the prepared scattergram, and displays the result on the display device.  FIG. 6  shows an example of a bacteria measurement result screen displayed on the operation and display device  2 . 
         [0052]    In the scattergram shown in  FIG. 6 , the forward scattered light intensity (FSC) is plotted on the vertical axis and the side fluorescent light intensity (FL) is plotted on the horizontal axis. The bacteria count is the total counted number of bacteria appearing in the set bacteria count region when the bacteria count region has been set in the scattergram according to the appearance pattern of the bacteria in the scattergram. 
         [0053]    The bacteria count region set according to the appearance pattern of the bacteria in the scattergram is described in detail below. As described above, the characteristic appearance pattern of the bacteria is shown in the scattergram according to the type of bacteria present in the urine of the subject because the type of bacteria present in the urine is different for each subject.  FIG. 7  shows examples of scattergrams generated based on the measurement results of measurement samples respectively prepared from axenically cultured samples (culture solution) for four types of bacteria.  FIG. 7(   a ) shows an example of a scattergram produced based on the measurement results of a measurement sample prepared from a sample of  E. coli,    FIG. 7(   b ) shows an example of a scattergram produced based on the measurement results of a measurement sample prepared from a sample of  Bacillus  sp.,  FIG. 7(   c ) shows an example of a scattergram produced based on the measurement results of a measurement sample prepared from a sample of  Pseudomonas aeruginosa,  and  FIG. 7(   d ) shows an example of a scattergram produced based on the measurement results of a measurement sample prepared from a sample of  Staphylococcus aureus.    
         [0054]    In the scattergram shown in  FIG. 7 , the forward scattered light intensity (FSC) is plotted on the vertical axis and the side fluorescent light intensity (FL) is plotted on the horizontal axis. Note that the appearance patterns of the bacteria in the scattergrams are compared using the late stage of the logarithmic growth phase of the bacteria in the relationship between culturing time and the bacteria count. The late stage of the logarithmic growth phase is the phase of logarithmic division and propagation of bacteria, and is the stage prior to the end stage of the logarithmic growth phase before the stationary phase during which bacteria division and extinction attain equilibrium. 
         [0055]    As shown in  FIGS. 7(   a ) and  7 ( b ), bacteria appear concentrated in a region of relatively high forward scattered light intensity and side fluorescent light intensity in the scattergrams generated based on the measurement results of the measurement samples respectively prepared from the  E. coli  and  Bacillus  sp. samples. This phenomenon is caused by the large sizes of the  E. coli  and  Bacillus  sp. bacteria, and indicates the same appearance pattern for similarly large bacteria. 
         [0056]    As shown in  FIGS. 7(   c ) and  7 ( d ), bacteria appear concentrated in a region of low forward scattered light intensity and side fluorescent light intensity due to the small size of the  Pseudomonas aeruginosa  in the scattergrams generated based on the measurement results of the measurement samples respectively prepared from the  Pseudomonas aeruginosa  and  Staphylococcus aureus  samples. This phenomenon indicates the same appearance pattern for similarly small bacteria. The  Staphylococcus aureus  bacteria have variable size due to having botryoidal characteristics, and appear in a broad range from a region of low forward light intensity and side fluorescent light intensity to a region of high forward scattered light intensity and side fluorescent light intensity. 
         [0057]    As shown in  FIGS. 7(   a ) through  7 ( d ), a first count region h and a second count region g are set in the scattergram as the bacteria count regions. The first count region h corresponds to a region composed of the combined second count region g and third count region f. 
         [0058]    In the case of large size bacteria such as the  E. coli  and  Bacillus  sp. bacteria shown in  FIGS. 7(   a ) and  7 ( b ), the bacteria count value is the value of the total bacteria appearing in the third count region f from which the first count region h and the second count region g are excluded. In the case of small bacteria or variable size bacteria such as the  Pseudomonas aeruginosa  and  Staphylococcus aureus  bacteria shown in  FIGS. 7(   c ) and  7 ( d ), the bacteria count value is the total bacteria appearing in the first count region h. 
         [0059]      FIG. 8  is a comparison of a viable count by culture method and bacteria count in the first count region h and the second count region g.  FIG. 8  shows the examination results obtained using  Bacillus  sp. and  Pseudomonas aeruginosa  bacteria in the measurement samples among the scattergrams of  FIG. 7  ( FIGS. 7(   b ) and ( c )). The viable count by culture method was counted using the samples (media) used in the measurement sample from which the scattergrams of  FIG. 7  were obtained. The output values in  FIG. 8  respectively represent the bacteria count of the first count region h in the case of  Pseudomonas aeruginosa  bacteria, and the value after subtracting the bacteria count of the second count region g from the bacteria count of the first count region h in the case of  Bacillus  sp. bacteria. Note that when counting bacteria, a correction is added to the appropriate count region by excluding the region of high probability that no bacteria will appear in the first count region h and second count region g of  FIG. 7 . 
         [0060]    As shown in  FIG. 8 , in the case of large size bacteria such as Bacillus sp., the output value (2.4E+07) is understood to approach the viable count (2.3E+07) by subtracting the bacteria count (0.1E+07) of the second count region g from the bacteria count (2.5E+07) of the first count region h. Therefore, large size bacteria can be counted with high precision by counting the bacteria appearing in the third count region f obtained by excluding the second count region g from which the first count region h. 
         [0061]    In the case of small size bacteria such as Pseudomonas aeruginosa, the output value (1.4E+08) is understood to approach the viable count (1.9E+08) by not subtracting the bacteria count (1.3E+08) of the second count region g from the bacteria count (1.4E+08) of the first count region h. Therefore, small size bacteria can be counted with high precision by counting the bacteria appearing in the first count region without excluding the second count region g from the first count region h. 
         [0062]    The standard for setting the bacteria count region (first count region h or second count region g) for counting bacteria from the appearance pattern in the scattergram is described below. 
         [0063]      FIG. 9  is a histogram showing the relationship between the count value and the forward scattered light intensity in each scattergram of  FIG. 7 .  FIG. 9(   a ) shows the relationship between the count value and the forward scattered light intensity in the basic measurement result produced from the  E. coli  scattergram of  FIG. 7(   a ),  FIG. 9(   b ) shows the relationship between the count value and the forward scattered light intensity in the basic measurement result produced from the  Bacillus  sp. scattergram of  FIG. 7(   b ),  FIG. 9(   c ) shows the relationship between the count value and the forward scattered light intensity in the basic measurement result produced from the  Pseudomonas aeruginosa  scattergram of  FIG. 7(   c ), and  FIG. 9(   d ) shows the relationship between the count value and the forward scattered light intensity in the basic measurement result produced from the  Staphylococcus aureus  scattergram of  FIG. 7(   d ),In  FIG. 9 , the count value is plotted on the vertical axis and the forward scattered light intensity (FSC) is plotted on the horizontal axis. 
         [0064]    As shown in  FIG. 9 , large size bacteria such as  E. coli  and  Bacillus  sp. shown in  FIGS. 9(   a ) and  9 ( b ) have larger mean values Mean for the forward scattered light intensity (FSC) than the small size bacteria such as  Pseudomonas aeruginosa  shown in  FIG. 9(   c ). Variable size bacteria such as  Staphylococcus aureus  shown in  FIG. 9(   d ) have larger mean values for the forward scattered light intensity (FSC) than the small size bacteria similar to the large size bacteria. However, variable size bacteria such as shown in  FIG. 9(   d ) can be distinguished from the large size bacteria because the forward scattered light intensity distribution width DW, which reflects the size of variation, is larger than that of the large size bacteria shown in  FIGS. 9(   a ) and  9 ( b ). Therefore, a bacteria count region corresponding to the bacteria appearance pattern can be set based on the forward scattered light intensity distribution width DW and the mean value M of the forward scattered light intensity (FSC). 
         [0065]    Specifically, the bacteria are large size bacteria such as  E. coli  and  Bacillus  sp. when the mean value M of the forward scattered light intensity is large and the forward scattered light intensity distribution width DW is small. In this case, the a large number of bacteria appear in the region of relatively high fluorescent light intensity in the scattergram and few bacteria appear in the second count region g of relatively low fluorescent light intensity, as shown in  FIGS. 7(   a ) and  7 ( b ). Therefore, the bacteria count is accomplished by counting the bacteria appearing in the third count region f obtained by excluding the second count region g from the first count region h. 
         [0066]    Small size bacteria such as  Pseudomonas aeruginosa  are present when the mean value M of the forward scattered light intensity is small and the forward scattered light intensity distribution width DW is small. In this case, a large amount of bacteria appear in the region of low forward scattered light intensity and a large amount of bacteria appear in the second count region g, as shown in  FIG. 7(   c ). Therefore, the bacteria count is accomplished by counting the bacteria appearing in the first count region h including the second count region g. 
         [0067]    Bacteria are variable size bacteria such as  Staphylococcus aureus  when the mean value M of the forward scattered light intensity if large and the forward scattered light intensity distribution width DW is also large. In this case, bacteria appear over a large region from the region of relatively low side fluorescent light intensity in the scattergram, and a large amount of bacteria appear in the second count region g, as shown in  FIG. 7(   d ). Therefore, the bacteria count is accomplished by counting the bacteria appearing in the first count region h including the second count region g. 
         [0068]    The measurement samples prepared from the urine of a plurality of subjects are then measured using the bacteria analyzer of the present embodiment, and the bacteria count is compared to a viable count by the culture method. Three setting methods are used as the method for setting the bacteria count region for counting the number of bacteria. The culture method uses two types of culture, that is, CLED agar medium and Heart-Infusion agar medium. 
         [0069]    The first setting method sets the first count region h for all measurement samples. The second setting method sets the threshold of the mean value M of the forward scattered light intensity as W(ch), and sets the threshold of the distribution width DW of the forward scattered light intensity as X(ch). Measurement samples with a mean value M equal to or greater than the threshold value W and a distribution width DW less than X are set to the third count region f, and measurement samples with a mean value M less than W and measurement samples with a mean value M equal to or greater than W and a distribution width DW equal to or greater than X are set to the first count region h. The third setting method sets the distribution width DW at 60% of the lateral of the maximum count position of the histogram, sets the threshold value of the mean value M as Y, and sets the threshold value of the distribution width DW as Z. Measurement samples with a mean value M equal to or greater than Y and a distribution width DW less than Z are set to the third count region f, and measurement samples with a mean value M less than Y and measurement samples with a mean value M equal to or greater than Y and a distribution width DW equal to or greater than Z are set to the first count region h. 
         [0070]    Note that the threshold value W of the mean value M, and the threshold values X and Z of the distribution width DW are respectively set, for example, at values 20 ch, 30 ch, 45 ch, 60 ch and the like when values 0 to 255 are channel (ch) values as in the present embodiment. The threshold values W, Y, X, and Z are pre-stored, as information required for setting the count range, in the count range characteristic information memory  232  of the memory device  23  of the operation and display device  2 . 
         [0071]      FIG. 10  compares the results of counting bacteria present in bacteria count regions set by three setting methods and a general viable count by culture method using Heart-Infusion agar medium and urine samples collected from three patients. As shown in  FIG. 10 , regarding sample  1 , the count result was 13% according to the first setting method when the count result of the viable count by culture method was 100%, whereas the count result was 98% using the second setting method and 98% using the third setting method, by which methods the count result approaches the viable count. 
         [0072]    Regarding the second sample, the count result was 3% according to the first setting method when the count result of the viable count by culture method was 100%, whereas the count result was 51% using the second setting method and 51% using the third setting method, by which methods the count result approaches the viable count. 
         [0073]    Regarding the third sample, the count result was 16% according to the first setting method when the count result of the viable count by culture method was 100%, whereas the count result was 83% using the second setting method and 83% using the third setting method, by which methods the count result approaches the viable count. 
         [0074]    These results prove it is possible to obtain values near the viable count by the culture method by setting the bacteria count region based on the second and third setting methods and counting the bacteria present within the set bacteria count region. 
         [0075]      FIG. 11  is a flow chart showing the sequence of the bacteria counting process performed by the CPU  21  of the operation and display device  2  of the embodiment of the bacteria analyzer of the present invention.  FIG. 11  illustrates the processing when the bacteria count region is set according to the third setting method. 
         [0076]    The CPU  21  of the operation and display device  2  obtains the measurement data from the measuring device  1  (step S 1101 ), and creates a scattergram (step S 1102 ). In the present embodiment, the scattergram is generated by plotting the forward scattered light on the vertical axis and plotting the side fluorescent light on the horizontal axis. 
         [0077]    The CPU  21  calculates the mean value M and the distribution width DW of the forward scattered light intensity (step S 1103 ). The method of calculating the distribution width DW is not specifically limited. In the present embodiment, the distribution width DW is calculated as the width of the forward scattered light intensity at a height (count number) equivalent to “20” when the maximum height (maximum count number) in the histogram of the forward scattered light intensity is designated “100.” 
         [0078]    The CPU  21  determines whether the mean value M of the forward scattered light intensity is equal to or greater than the threshold W (0&lt;W&lt;255) (step S 1104 ). When the CPU  21  has determined that the mean value M of the forward scattered light intensity is equal to or greater than the threshold value W (step S 1104 : YES), the CPU  21  then determines whether the distribution width DW of the forward scattered light intensity is less than the threshold X (0&lt;X&lt;255) (step S 1105 ). 
         [0079]    When the CPU  21  has determined that the distribution width DW of the forward scattered light intensity is less than the threshold value X (step S 1105 : YES), the CPU  21  then sets the third count region f, that is the region obtained by excluding the second count region g from the first count region h, as the bacteria count region (step S 1106 ). 
         [0080]    When the CPU has determined that the mean value M of the forward scattered light intensity is less than the threshold value W (step  51104 : NO), or when the distribution width DW of the forward scattered light intensity is equal to or greater than the threshold value X and the mean value M of the forward scattered light intensity is equal to or greater than W (step S 1105 : NO), the CPU  21  sets the first count region h as the bacteria count region (step S 1107 ). 
         [0081]    The CPU  21  counts the bacteria included in the set bacteria count region (step S 1108 ), and displays the scattergram and the calculated bacteria count on the display device  25  (step S 1109 ). 
         [0082]    According to the embodiment described above, the bacteria count region can be set as the count target according to the bacteria distribution state on the scattergram, particles other than bacteria can be prevented from inflating the count value by effectively excluding a region containing particles such as impurities that are not bacteria, and undercounting the bacteria count by excluding from the count target a region in which bacteria are actually present can be prevented before such exclusion occurs. Therefore, highly accurate count values can be obtained, and a bacteria analyzer capable of performing high precision analysis can be provided. 
         [0083]    Note that although the above embodiment is described by way of example of a bacteria analyzer capable of detecting and counting both bacteria and tangible components in urine, the present invention is not specifically limited to this example inasmuch as the present invention is also applicable to an apparatus capable of detecting and counting only bacteria, and a bacteria analyzer for analyzing bacteria contained in other samples such as blood without limitation to urine. Although the setting of the bacteria count region changes based on the distribution width and mean value of the forward scattered light intensity which functions as information relating to bacteria size, the present invention is not limited to this arrangement. For example, rather than the mean value of the forward scattered light intensity, the value of the forward scattered light intensity at the peak of the distribution of the forward scattered light intensity may also be used. As a further example, the standard deviation of the forward scattered light intensity distribution may also be used in place of the distribution width DW which reflects the variation in the size of the bacteria. As a still further example, the setting of the bacteria count region may also be set based on the distribution width and mean value of the side fluorescent light intensity which functions as information relating to the attributes of the bacteria. 
         [0084]    Although the above embodiment is described by way of example in which the bacteria count region is selected from a first count region h and a third count region f, the present invention is not limited to this arrangement. For example, a suitable bacteria count region may be set according to the bacteria distribution state, and the bacteria present in the set bacteria counting region may be counted. 
         [0085]    Although the above embodiment is described by way of example in which the forward scattered light intensity and the side fluorescent light intensity are used when generating a scattergram for representing the bacteria distribution state, the present invention is not limited to this arrangement. For example, the forward scattered light intensity and the side fluorescent light intensity may be used, and the width of the light signals may be used rather than the light intensity. 
         [0086]    Moreover, the present invention is not limited to the above embodiment, and may be variously modified and transposed insofar as such modifications and transpositions do not depart from the scope of the present invention.