Patent Publication Number: US-4093381-A

Title: Method for assaying endotoxins

Description:
BACKGROUND OF THE INVENTION 
     Endotoxins, which are commonly known as pyrogens, are substances produced by microorganisms growing in water or in aqueous solutions. They cause inflammation and general fever when injected intravenously. They are colloidal in nature and they persist even after the organisms which produce them are destroyed by sterilization. 
     Neither the mode(s) of their activity nor their structures are known. However, in general, it is known that in gram-negative bacteria, the glycopeptide basal layer is covered with a lipopolysaccharide which constitutes 20-30% of the cell wall. Lipopolysaccharides, components of the whole somatic antigen, with molecular weights of the order of 10 6  to 10 7 , exhibit endotoxin activity. It is difficult to construct a molecular model for a lipopolysaccharide which would adequately explain the shapes revealed by electron microscopy. 
     Endotoxins of high antigentic activity have been extracted from bacteria by using one of the recognized published procedures. The best known are the Boivin trichloroacetic acid procedure (Boivin, A., and Mesrobeanie, L., Compt. Rend. Soc. Biol. 113,490, (1933); 128,5 (1938): as modified by Webster, Sagin, Landy and Johnson (Webster, M. E., Sagin, J. F., Landy, M. and Johnson, A., J. Immunology, 74,455 (1955), and the trypsin digestion method of Hartwell and Shear (Hartwell, J. L., and Shear, M. J. J Nat. Cancer Inst., 4, 107-22, (1943). These methods produce bacterial endotoxins possessing properties adequate for most immunological and pathological studies. The purified endotoxins are comparatively stable in the solid form, but they may become inactivated in solution by hydrolysis. 
     Shigella dysenteriae has been proposed as an international reference bacterium for preparing endotoxins for pyrogenic activity. The endotoxin derived from this source contains 4.504.6% nitrogen and 0.80-085% phosphorus. It has a molecular weight of about 10 7  and a strong pyrogenic activity at a level of 0.01 ppm in water (Humphrey, J. H., and Bangham, D. R., Bull Org. Mond. Sante, 20, 1231-44 (1959). 
     The first significant pyrogenic work was done between 1911-1916 by Jona (Jona, J. L., Med. J. of Australia iii, 71-73 (1916) and Hort and Penfield (Hort, E. C., and Penfield, W. J., Britt. Med. J., 2, 1589 (1911). They discovered that intravenous infusions cause elevation of body temperature. In their work freshly prepared distilled water was injected into both a man and animals as a control. A portion of the same distilled water was innoculated into an unsterile container for a period of time and this preparation was then injected into the same man and animals. The febrile reaction occurred only when the innoculated distilled water was injected into the unsterile container. They concluded that the fever-causing product, called pyrogen, was associated with bacteria but was not a part of the bacteria themselves since autoclaving, boiling and filtering did not reverse the febrile reaction. They also were able to classify microorganisms into pyrogenic-type gram negative and nonpyrogenic-type gram positive. Because of the lack of advanced equipment and knowledge their experiments were limited, but they formed the basis for the development of the modern standardized pyrogen test. Siebert (Siebert, F. B., Amer, J. Physiol. 67, 90-04 (1923), (Siebert, F. B., Amer. J. Physiol., 71, 621-51 (1925), in 1923, confirmed these observations by injecting distilled water into rabbits. In her experiments she demonstrated that bacterial products are present in all pyrogenic fluids that are unaffected by autoclaving, boiling and filtering techniques. She concluded that pyrogenic reactions occur even in sterile fluids and that pyrogenic reactions reactions can be prevented in pharmaceutical preparations only by the removal of pyrogens. 
     In the conventional method parenteral solutions are examined for pyrogens by using rabbits as test animals according to the procedure outlined in the United States Pharmacopeia (USP) This procedure was adopted in the early 1940&#39;s when the need for an official pyrogen test was first recognized. A collaborative study was undertaken by the Food and Drug Administration, the National Institutes of Health, and 14 pharmaceutical manufacturing companies. As a result of these studies, the first official pyrogen test was adopted and appeared in the XIIth Revision of the United States Pharmacopeia. Pharmaceutical companies and research laboratories have made extensive use of the USP rabbit pyrogen test during the past 35 years because of its low cost and the ease with which the rabbits are handled during the test. However, other animals such as dogs, cats, monkeys, and horses are equally reliable for the test. The rabbit is reported to be the most sensitive animal for indicating the absence of pyrogens, whereas the dog is the most sensitive animal for establishing the presence of pyrogens. Some investigators have used both animals in order to obtain a better indication, particularly in doubtful cases. 
     The test is performed in a room in which the temperature and humidity are maintained at the same levels as the room in which the animals are housed. 
     The USP test requires the use of healthy mature rabbits of either sex weighing not less than 1500 grams. However, to avoid the emotional stimuli which occur when males and females are mixed, most laboratories use rabbits of a single sex. Animals eliciting a negative pyrogen reaction may be used again after 48 hours and those eliciting a positive pyrogen reaction may be used after a two-week rest period. 
     The test animals are fed until an hour before the first temperature reading is made and they are not fed, with the exception of water, until the one-day test period is over. On the day of the test, the initial temperatures of the animals are recorded. Rabbits with initial control temperatures above 39.8° C are rejected for the test. 
     All syringes, needles and glassware used for the injections are prepared in advance by heating at 250° C in a muffle furnace for at least 30 minutes. This process renders the implements pyrogen-free and they can then be sterilized. 
     Since rectal temperature probes, clinical thermometers and electric or digital recording devices must remain in place throughout the pyrogen test, the animals must be restrained. This is usually accomplished with restraining boxes. 
     Prior to injection, samples are made isotonic with pyrogen-free sodium chloride and warmed to 37° C. Then 10 ml of the sample per kilogram of body weight of the animal are injected into each of 3 selected rabbits through the ear vein. Then, the maximum temperature-rise over a period of several hours is noted for each rabbit. A negative test is indicated when no rabbit shows an individual rise in temperature of 0.6° C or more above its respective control temperature, of if the sum of the 3-rabbit temperature rises does not exceed 1.4° C. The test is repeated with 5 rabbits. If 3 or less of the total of 8 rabbits show individual temperature rises of 0.6° C or more, and if the sum of the temperature rises for all rabbits does not exceed 3.7° C, the sample is nonpyrogenic. 
     A test with a slight variations from the USP test is formulated in the United States Public Health Service (PHS) Regulations for the official pyrogen test for biologic products. At the final point, these regulations state that a negative pyrogen test of a product is indicated when less than one-half of the 3 or more test rabbits show individual temperature rises of 0.6° C or less, or if the average temperature rise of all test rabbits is less than 0.5° C. 
     In 1971, Reinhold and Fine (Reinhold, R. B. Fine, J., Proc. Soc. Exp. Biol. Med. 137, 334-40 (1971), developed a specific in vitro assay method, the `Limulus Amebocyte Lysate Test`, which has a sensitivity level of 0.001-0.005 mg of pyrogen per ml of human plasma. The test is performed by mixing the sample with a cell lysate which is extracted from the circulating amebocytes of Limulus polyphemus (horseshoe crab). If sufficient pyrogen is present in the sample, the lysate will gel; otherwise, the bulk of the solution will remain fluid indicating a negative test. 
     Although the test will normally detect a low level of endotoxins, it has not been used widely with sufficient confidence to replace the present rabbit test, primarily because there is a borderline region in the gelatin process wherein the analyst must rely heavily on his visual judgment. Also, the gel-forming reaction is quite delicate and it is irreversibly terminated with improper care. 
     BRIEF DESCRIPTION OF THE INVENTION 
     An analytical method has been developed which is capable of detecting pyrogens at the 10 parts per billion (ppb) level. The method depends on the measurement of the ultra-violet spectrum of solutions containing the pyrogens over the 200 to 800 nm range using the equipment described below. The absorption at 259 nm measures the concentration of endotoxins. 
     DETAILED DESCRIPTION OF THE INVENTION 
     An absorption spectrum is obtained by placing a substance in a suitable cell and exposing it to the energy source of interest in the frequency range being studied. The spectrophotometer is designed so that it measures the transmitted energy relative to the incident energy at a given frequency. The energy required to excite an electron in a compound from its ground state molecular orbital to an excited state is directly proportional to the frequency of the radiation that causes the transition: 
     
             E.sub.2 - E.sub.1 = hν                                             
 
    
     where E 2  and E 1  are the energies of the initial and final states, respectively, h is Planck&#39;s constant, 6.624 × 10 -27  erg-sec and ν is the frequency of the incident radiation. 
     When a molecule absorbs electromagnetic radiation in the ultra-violet or visible region, the electronic transitions are accompanied by the lower-energy vibronic and rotational transitions of the molecule as a whole as well as those of the individual chemical bonds within the molecule. These cause absorption bands to appear in the spectrum. 
     Such absorption is described by the Beer-Lambert law. Beer&#39;s law states that in a non-absorbing solvent, each solute molecule absorbs the same fraction of incident light regardless of the concentration. This law is valid only in dilute solutions. Lambert&#39;s law states that the intensity of light passing through a homogeneous medium decreases logarithmically as the thickness of the layer increases. The combined laws may be written: 
     
             A = log (io/l) = εlc                                          
 
    
     where: 
     A is the absorbance. 
     lo is the intensity of incident light. 
     l is the intensity of transmitted light. 
     l is the cell thickness in cm. 
     c is the concentration in mole/liter. 
     ε is the molar absorptivity or extinction coefficient in liters/mole-cm. 
     Modern ultra-violet/visible spectrophotometers can commonly measure spectra from 180 nm to 800 nm. 
    
    
     My invention is illustrated by the following specific but non-limiting example. 
     EXAMPLE 
     An ACTA MVI Spectrophotometer was used for measuring the absrobance of endotoxin solutions over a concentration range of 10 to 10,000 ppb. 
     Endotoxins 
     Lipopolysaccharide E. coli 0127:B8 
     Lipopolysaccharide E. coli 055:B5 
     Lipopolysaccharide S. abortus equi 
     Lipopolysaccharide S. enteritidis 
     Lipopolysaccharide S. flexneri 
     All endotoxins were prepared commercially by the Westphal extraction method and were shipped in powder form in vials that must be kept refrigerated. 
     Since the endotoxins have low solubilities in water, all stock solutions were prepared at 50 ppm concentrations. The solutions were prepared by dissolving 50 mg of each endotoxin in 1-liter of endotoxin-free distilled water. 
     Before measuring the endotoxin concentrations it was necessary to establish the wavelength of maximum absorption. It was also necessary to establish that the endotoxin absorption followed Beer&#39;s law. 
     The stock solutions were diluted to 7.5 ppm with endotoxin-free distilled water and the absorption curve of each was run in a 10-cm cell in order to establish its wavelength of maximum absorption. The data for E. coli 1027:B8, E. coli 055:B5, S. abortus equi, S. enteritidis and S. flexneri are presented in Tables 1 through 5. A solution containing a mixture of five endotoxins was prepared. It consisted of 50 ppm of each of the endotoxins cited above. This stock solution was diluted, as above, to 7.5 ppm and its absorption curve was run. The data are presented in Table 6. 
     
                       TABLE 1                                                     
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UV ABSORPTION DATA FOR                                                    
BACTO-LIPOPOLYSACCHARIDE E. COLI 0127:B8                                  
Wavelength                                                                
          Slit Width Absor-   Transmittance                               
nm        mm         bance    Per Cent                                    
______________________________________                                    
200       2.00       1.150     7.5                                        
220       0.28       0.473    33.8                                        
225       0.24       0.342    45.5                                        
230       0.22       0.297    50.5                                        
233       0.20       0.300    50.0                                        
234       0.20       0.304    49.6                                        
235       0.20       0.314    48.8                                        
240       0.19       0.372    42.3                                        
245       0.18       0.458    35.0                                        
250       0.17       0.544    28.6                                        
255       0.16       0.598    25.2                                        
259       0.16       0.606    24.8                                        
260       0.16       0.605    24.9                                        
263       0.16       0.582    26.2                                        
265       0.16       0.560    27.7                                        
270       0.16       0.487    32.8                                        
275       0.16       0.402    39.8                                        
280       0.15       0.316    48.2                                        
285       0.15       0.233    58.5                                        
290       0.15       0.162    69.0                                        
295       0.14       0.102    79.2                                        
4.5 ml of 50 ppm E. Coli 0127:B8 were diluted to                          
30 ml. The final concentration is 7.5 ppm.                                
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                       TABLE 2                                                     
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UV ABSORPTION DATA FOR                                                    
BACTO-LIPOPOLYSACCHARIDE E. COLI 055:B5 -                                 
  Wavelength  Silt Width Absor- Transmittance                             
nm                                                                        
  mm          bance      Per Cent                                         
______________________________________                                    
220       0.28       0.300    50.0                                        
225       0.24       0.217    60.6                                        
230       0.22       0.177    66.8                                        
233       0.20       0.172    67.2                                        
234       0.20       0.174    67.0                                        
235       0.20       0.175    67.0                                        
240       0.19       0.191    64.4                                        
245       0.18       0.225    60.2                                        
250       0.17       0.255    55.5                                        
255       0.16       0.275    53.0                                        
259       0.16       0.280    52.5                                        
260       0.16       0.280    52.5                                        
263       0.16       0.275    53.0                                        
265       0.16       0.270    54.3                                        
270       0.16       0.240    57.5                                        
275       0.16       0.202    63.0                                        
280       0.15       0.162    68.9                                        
285       0.15       0.125    75.0                                        
290       0.15       0.095    80.2                                        
295       0.14       0.069    85.1                                        
4.5 ml of 50 ppm E. coli 055:B5 were diluted to                           
30 ml. The final solution concentration is 7.5 ppm.                       
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                       TABLE 3                                                     
______________________________________                                    
UV ABSORPTION DATA FOR                                                    
BACTO-LIPOPOLYSACCHARIDE S. ABORTUS EQUI                                  
Wavelength                                                                
          Silt Width Absor-   Transmittance                               
nm        mm         bance    Per Cent                                    
______________________________________                                    
220       0.28       0.343    45.3                                        
225       0.24       0.250    56.2                                        
230       0.22       0.210    61.5                                        
233       0.20       0.209    61.8                                        
234       0.20       0.212    61.1                                        
235       0.20       0.217    60.8                                        
240       0.19       0.260    55.0                                        
245       0.18       0.325    47.2                                        
250       0.17       0.390    40.8                                        
255       0.16       0.425    37.5                                        
259       0.16       0.435    36.8                                        
260       0.16       0.434    36.7                                        
263       0.16       0.421    38.0                                        
265       0.16       0.410    39.0                                        
270       0.16       0.365    43.0                                        
275       0.16       0.310    49.0                                        
280       0.15       0.255    55.6                                        
285       0.15       0.195    63.8                                        
290       0.15       0.145    72.0                                        
295       0.14       0.095    80.2                                        
4.5 ml of 50 ppm S. abortus equi were diluted to                          
30 ml. The final concentration is 7.5 ppm.                                
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                       TABLE 4                                                     
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UV ABSORPTION DATA FOR                                                    
BACTO-LIPOPOLYSACCHARIDE S. ENTERITIDIS                                   
Wavelength                                                                
          Slit Width Absor-   Transmittance                               
nm        mm         bance    Per Cent                                    
______________________________________                                    
220       0.28       0.355    44.0                                        
225       0.24       0.264    54.6                                        
230       0.22       0.225    59.7                                        
233       0.20       0.224    59.8                                        
234       0.20       0.228    59.1                                        
235       0.20       0.232    58.8                                        
240       0.19       0.273    53.2                                        
245       0.18       0.332    46.5                                        
250       0.17       0.395    40.1                                        
255       0.16       0.430    37.0                                        
259       0.16       0.437    36.7                                        
260       0.16       0.434    36.8                                        
263       0.16       0.420    38.0                                        
265       0.16       0.405    39.5                                        
270       0.16       0.360    43.5                                        
275       0.16       0.305    49.8                                        
280       0.15       0.245    57.0                                        
285       0.15       0.185    65.5                                        
290       0.15       0.135    73.4                                        
295       0.14       0.092    81.0                                        
4.5 ml of 50 ppm S. enteritidis were diluted to                           
30 ml. The final concentration is 7.5 ppm.                                
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                       TABLE 5                                                     
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UV ABSORPTION DATA FOR                                                    
BACTO-LIPOPOLYSACCHARIDE S. FLEXNERI                                      
Wavelength                                                                
          Slit Width Absor-   Transmittance                               
nm        mm         bance    Per Cent                                    
______________________________________                                    
220       0.28       0.410    39.0                                        
225       0.24       0.310    49.0                                        
230       0.22       0.260    55.0                                        
233       0.20       0.255    55.6                                        
234       0.20       0.257    55.2                                        
235       0.20       0.260    55.0                                        
240       0.19       0.290    51.2                                        
245       0.18       0.345    45.0                                        
250       0.17       0.400    40.0                                        
255       0.16       0.438    36.6                                        
259       0.16       0.443    36.0                                        
260       0.16       0.441    36.1                                        
263       0.16       0.429    37.2                                        
265       0.16       0.418    38.4                                        
270       0.16       0.375    42.0                                        
275       0.16       0.325    47.4                                        
280       0.15       0.270    53.8                                        
285       0.15       0.215    61.0                                        
290       0.15       0.165    68.5                                        
295       0.14       0.118    76.0                                        
4.5 ml of 50 ppm S. flexneri were diluted to                              
30 ml. The final concentration is 7.5 ppm.                                
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                       TABLE 6                                                     
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UV ABSORPTION DATA FOR                                                    
THE MIXTURE OF                                                            
i E. COLI 0127:B8, 50 ppm                                                 
E. COLI 055:B5, 50 ppmBACTO-                                              
S. ABSORTUS EQUI, 50 ppmLIPOPOLYSACCHARIDE                                
S. ENTERITIDIS, 50 ppm                                                    
S. FLEXNERI, 50 ppm                                                       
Wavelength                                                                
          Slit Width Absorb-  Transmittance                               
nm        mm         ance     Per Cent                                    
______________________________________                                    
220       0.28       0.390    40.8                                        
225       0.24       0.287    51.7                                        
230       0.22       0.245    57.0                                        
233       0.20       0.250    56.2                                        
234       0.20       0.251    56.0                                        
235       0.20       0.260    55.0                                        
240       0.19       0.297    50.4                                        
245       0.18       0.350    44.6                                        
250       0.17       0.400    40.0                                        
255       0.16       0.416    37.7                                        
257       0.16       0.419    38.2                                        
258       0.16       0.420    38.0                                        
259       0.16       0.419    38.2                                        
260       0.16       0.418    38.4                                        
263       0.16       0.410    39.0                                        
265       0.16       0.400    40.0                                        
270       0.16       0.355    44.0                                        
275       0.16       0.300    50.0                                        
280       0.15       0.240    57.7                                        
285       0.15       0.185    65.2                                        
290       0.15       0.136    73.8                                        
295       0.15       0.088    81.8                                        
20 ml of each solution were mixed to a final volume                       
of 1000 ml. 4.5 ml of the 50 ppm solution of the                          
above mixture were diluted to 30 ml. The final                            
concentration is 7.5 ppm.                                                 
______________________________________                                    
 
    
     The absorption maxima for all individual endotoxins are essentially the same, i.e., 259 mm. For the five endotoxin mixtures, the absorption maxima shifted slightly toward a lower wavelength, 258 mm, and the peak broadened to some extent. From this point on, all of the absorption measurements were made at 258 mm. 
     In order to examine the linearity of the absorption-vs-concentration curve, a 1-liter solution of the five endotoxins cited above, containing a total of 50 ppm, was prepared by mixing 200 ml of each 50  ppm endotoxin solution in a 1-liter volumetric flask. This stock solution was kept refrigerated at 10° C. The stock solution was diluted to prepare a series of standards to be used in making the standard curve. These colutions had concentrations ranging from 10 ppb to 10 ppm. As shown in Table 7, the solutions were divided into three groups; the first having concentrations of 10-50 ppb; the second and the third having concentrations of 50-1000 and 500-10,000 ppb respectively. The absorption data for the standard solutions are shown in Table 8. 
     With the exception of Group 1, all other measurements were made at 258 nm and with a salt width of 0.16mm with the Beckman DU Spectrophotometer. Group 1 measurements required a more sensitive and elaborate measuring instrument. The ACTA MVI was used for the measurements. 
     The settings of the ACTA MVI Spectrophotometer were kept constant throughout the experiment as indicated below: 
     
         ______________________________________                                    
Scanning Wavelength Range                                                 
                     : 300-225 nm                                         
Scanning Speed       : 1/2 nm/sec                                         
Chart Display        : 10 nm/inch                                         
Chart Speed          : 1 inch/min                                         
Period Set           : 0.5                                                
Span                 : 0.1                                                
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                       TABLE 7                                                     
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STANDARD SOLUTIONS OF ENDOTOXIN MIXTURE                                   
USED FOR PREPARING THE STANDARD CURVES                                    
GROUP 1                                                                   
                    Concentration                                         
                    ppb     ppm                                           
Blank-double distilled water                                              
                      0         0.000                                     
 0.2 ml of stock solution diluted to 1-liter                              
                      10        0.010                                     
 0.5 ml of stock solution diluted to 1-liter                              
                      25        0.025                                     
 1.0 ml of stock solution diluted to 1-liter                              
                      50        0.050                                     
GROUP 2                                                                   
 1.0 ml of stock solution diluted to 1-liter                              
                      50        0.050                                     
 2.0 ml of stock solution diluted to 1-liter                              
                      100       0.100                                     
 3.0 ml of stock solution diluted to 1-liter                              
                      150       0.150                                     
 4.0 ml of stock solution diluted to 1-liter                              
                      200       0.200                                     
 5.0 ml of stock solution diluted to 1-liter                              
                      250       0.250                                     
 7.0 ml of stock solution diluted to 1-liter                              
                      350       0.350                                     
 8.0 ml of stock solution diluted to 1-liter                              
                      400       0.400                                     
 10.0 ml of stock solution diluted to 1-liter                             
                      500       0.500                                     
 15.0 ml of stock solution diluted to 1-liter                             
                      750       0.750                                     
 20.0 ml of stock solution diluted to 1-liter                             
                      1000      1.000                                     
GROUP 3                                                                   
 10.0 ml of stock solution diluted to 1-liter                             
                       500      0.500                                     
 20.0 ml of stock solution diluted to 1-liter                             
                      1000      1.000                                     
 30.0 ml of stock solution diluted to 1-liter                             
                      1500      1.500                                     
 50.0 ml of stock solution diluted to 1-liter                             
                      2500      2.500                                     
100.0 ml of stock solution diluted to 1-liter                             
                      5000      5.000                                     
150.0 ml of stock solution diluted to 1-liter                             
                      7500      7.500                                     
200.0 ml of stock solution diluted to 1-liter                             
                      10000     10.000                                    
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                       TABLE 8                                                     
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UV ABSORBANCE AND TRANSMITTANCE DATA FOR                                  
SOLUTIONS OF THE ENDOTOXIN MIXTURE                                        
USED FOR PREPARING STANDARD CURVES                                        
GROUP 1                                                                   
Concentration                                                             
           Absorb-    Transmittance                                       
ppb        ance       Per Cent                                            
______________________________________                                    
Double                                                                    
Distilled  0.0019     99.8                                                
Water                                                                     
10         0.0042     99.0                                                
25         0.0061     98.5                                                
50         0.0090     98.0                                                
GROUP 2                                                                   
50         0.009      98.0                                                
100        0.012      97.2                                                
150        0.014      96.8                                                
200        0.018      96.0                                                
250        0.020      95.5                                                
350        0.026      94.2                                                
400        0.028      93.6                                                
500        0.033      92.8                                                
600        0.038      91.7                                                
750        0.048      89.5                                                
1000       0.062      86.8                                                
GROUP 3                                                                   
500        0.033      92.8                                                
1000       0.062      86.8                                                
1500       0.091      81.1                                                
2500       0.146      71.5                                                
5000       0.288      51.5                                                
7500       0.419      38.1                                                
10000      0.575      26.7                                                
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     The absorbance for each group is linear with concentration indicating that Beer&#39;s law is obeyed. 
     It is apparent from the data that a convenient and accurate method has been developed for monitoring the concentration of endotoxins whose identities are known. It is capable of detecting endotoxins at levels of a few ppb.