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561 ARTICLES OF BOTANICAL ORIGIN

SAMPLING
To reduce the effect of sampling bias in qualitative and quantitative results, it is necessary to ensure that the composition of the sample used be representative of the batch of drugs being examined. The following sampling procedures are the minimum considered applicable to vegetable drugs. Some articles, or some tests, may require more rigorous procedures involving more containers being sampled or more samples per container.
Gross Sample
Where external examination of containers, markings, and labels indicates that the batch can be considered to be homogeneous, take individual samples from the number of randomly selected containers indicated below. Where the batch cannot be considered to be homogeneous, divide it into sub-batches that are as homogeneous as possible, then sample each one as a homogeneous batch. It is recommended to include samples from the first, middle, and last containers where the No. of Containers in Batch (N) is 11 or more, and each container in the batch is numbered or lettered in order.
No. of Containers in Batch
(N) No. of Containers to Be Sampled
(n)
1–10  All
11–19  11
>19  n = 10 + (N/10)

(Rounding was calculated as “n” to next highest whole number.)
Samples are taken from the upper, middle, and lower sections of each container. If the crude material consists of component parts that are 1 cm or less in any dimension, and in the case of all powdered or ground materials, withdraw the sample by means of a sampling device that removes a core from the top to the bottom of the container, NLT two cores being taken from different angles. For materials with component parts >1 cm in any dimension, withdraw samples by hand. In the case of large bales or packs, samples should be taken from a depth of 10 cm, because the moisture content of the surface layer may be different from that of the inner layers.
Prepare the gross sample by combining and mixing the individual samples taken from each opened container, taking care not to increase the degree of fragmentation or significantly affect the moisture content.
For articles in containers holding <1 kg, mix the contents, and withdraw a quantity sufficient for the tests. For articles in containers holding between 1 and 5 kg, withdraw equal portions from the upper, middle, and lower parts of the container, each of the samples being sufficient to carry out the tests. Thoroughly mix the samples, and withdraw an amount sufficient to carry out the tests. For containers holding more than 5 kg, withdraw three samples, each weighing NLT 250 g, from the upper, middle, and lower parts of the container. Thoroughly mix the samples, and withdraw a portion sufficient to carry out the tests.
Laboratory Sample
Prepare the Laboratory Sample by repeated quartering of the gross sample.
Note—Quartering consists of placing the sample, adequately mixed, as an even and square-shaped heap and dividing it diagonally into four equal parts. The two opposite parts are then taken and carefully mixed. The process is repeated as necessary until the required quantity is obtained.
The Laboratory Sample should be of a size sufficient for performing all the necessary tests.
Test Sample
Unless otherwise directed in the individual monograph or test procedure below, prepare the Test Sample as follows.
Decrease the size of the Laboratory Sample by quartering, taking care that each withdrawn portion remains representative. In the case of unground or unpowdered drugs, grind the withdrawn sample so that it will pass through a No. 20 standard-mesh sieve, and mix the resulting powder well. If the material cannot be ground, reduce it to as fine a state as possible, mix by rolling it on paper or sampling cloth, spread it out in a thin layer, and withdraw the portion for analysis.

METHODS OF ANALYSIS
Foreign Organic Matter
test sample
Unless otherwise specified in the individual monograph, weigh the following quantities of the Laboratory Sample, taking care that the withdrawn portion is representative (quartering if necessary).
  Roots, rhizomes, bark, and herbs  500 g
Leaves, flowers, seeds, and fruit  250 g
Cut vegetable drugs (average weight of the pieces is <0.5 g)  50 g

Spread the sample out in a thin layer, and separate the foreign organic matter by hand as completely as possible. Weigh it, and determine the percentage of foreign organic matter in the weight of drug taken.
Total Ash
Accurately weigh a quantity of the Test Sample, representing 2–4 g of the air-dried material, in a tared crucible and incinerate, gently at first, and gradually increase the temperature to 675 ± 25 until free from carbon, and determine the weight of the ash. If a carbon-free ash cannot be obtained in this way, extract the charred mass with hot water, collect the insoluble residue on an ashless filter paper, incinerate the residue and filter paper until the ash is white or nearly so, then add the filtrate, evaporate it to dryness, and heat the whole to a temperature of 675 ± 25. If a carbon-free ash cannot be obtained in this way, cool the crucible, add 15 mL of alcohol, break up the ash with a glass rod, burn off the alcohol, and again heat the whole to a temperature of 675 ± 25. Cool in a desiccator, weigh the ash, and calculate the percentage of total ash from the weight of the drug taken.
Acid-Insoluble Ash
Boil the ash obtained as directed in Total Ash with 25 mL of 3 N hydrochloric acid for 5 min, collect the insoluble matter on a tared filtering crucible or ashless filter, wash with hot water, ignite, and weigh. Determine the percentage of acid-insoluble ash calculated from the weight of drug taken.
Water-Soluble Ash
Boil the ash obtained as directed in Total Ash with 25 mL of water for 5 min. Collect the insoluble matter in a sintered-glass crucible or on an ashless filter paper. Wash with hot water, and ignite for 15 min at a temperature not exceeding 450. Subtract the weight of this residue, in mg, obtained in Total Ash, and calculate the percentage of water-soluble ash with reference to the weight of sample as determined in Total Ash.
Alcohol-Soluble Extractives
method 1 (hot extraction method)
Transfer about 4 g of air-dried, coarsely powdered material, accurately weighed, to a glass-stoppered conical flask. Add 100 mL of alcohol, and weigh the flask. Shake, and allow to stand for 1 h. Attach a reflux condenser to the flask, boil gently for 1 h, cool, and weigh. Readjust to the original weight with alcohol. Shake, and filter rapidly through a dry filter. Transfer 25 mL of the filtrate to a tared flat-bottomed dish, and evaporate on a water bath to dryness. Dry at 105 for 6 h, cool in a desiccator for 30 min, and weigh without delay. Calculate the content, in mg/g, of alcohol-extractable matter in the test specimen.
method 2 (cold extraction method)
Transfer about 4 g of air-dried, coarsely powdered material, accurately weighed, to a glass-stoppered conical flask. Add 100 mL of alcohol, insert a stopper into the flask, and macerate for 24 h, shaking frequently during the first 8 h, and then allowing to stand. Filter rapidly, taking precautions against loss of alcohol. Evaporate 25 mL of the filtrate to dryness in a tared, flat-bottomed, shallow dish, and dry at 105 to constant weight. Calculate the content, in mg/g, of alcohol-extractable matter in the test specimen.
Water-Soluble Extractives
method 1 (hot extraction method)
Proceed as directed in Method 1 (Hot Extraction Method) in Alcohol-Soluble Extractives, except use water in place of alcohol.
method 2 (cold extraction method)
Proceed as directed in Method 2 (Cold Extraction Method) in Alcohol-Soluble Extractives, except use water in place of alcohol.
Crude Fiber
Exhaust a weighed quantity of the Test Sample, representing about 2 g of the drug, with ether. Add 200 mL of boiling dilute sulfuric acid (1 in 78) to the ether-exhausted marc, in a 500-mL flask, and connect the flask to a reflux condenser. Reflux the mixture for 30 min, accurately timed, then pass through a linen or hardened-paper filter, and wash the residue on the filter with boiling water until the effluent washing is no longer acid. Rinse the residue back into the flask with 200 mL of boiling sodium hydroxide solution, adjusted to 1.25% by titration and free from sodium carbonate. Again reflux the mixture for 30 min, accurately timed, then rapidly pass through a tared filter, wash the residue with boiling water until the last washing is neutral, and dry it at 110 to constant weight. Incinerate the dried residue, ignite to constant weight, cool in a desiccator, and weigh the ash: the difference between the weight obtained by drying at 110 and that of the ash represents the weight of the crude fiber.
Note—The boiling with acid and alkali should continue for 30 min, accurately timed, from the time that the liquid (which is cooled below the boiling point by being added to the cold flask) again boils. After the solution has been brought to boiling, the heat should be turned low enough just to maintain boiling. During the boiling, the flask should be gently rotated from time to time to wash down any particles that may adhere to the walls of the flask. A slow current of air introduced into the flask during the boiling operation aids in preventing excessive frothing.
Starch Content
method 1
The following is a general procedure for all reducing sugars and may be used to determine the starch content in botanical articles.
Malt extract: Use clean new barley malt of known efficacy, and grind just before use. Prepare malt extract just before use. For every 80 mL of malt extract needed, digest 5 g of ground malt with 100 mL of water at room temperature for 2 h. [Note—If an electric mixer is used, stir the mixture for 20 min. ] Filter to obtain a clear extract, filtering again, if necessary, and mix the infusion well.
Test solution: Extract about 5 g of the finely ground test specimen with five 10-mL portions of ether, using a filter that will completely retain the smallest starch granule. Allow the ether to evaporate from the residue, and wash with 250 mL of aqueous alcohol solution (10 in 100). Carefully wash the residue from the paper into a 500-mL beaker with about 100 mL of water. Heat to about 60 (avoiding, if possible, gelatinizing starch), and allow to stand for about 1 h, stirring frequently to effect complete solution of sugars. Transfer to a wide-mouth bottle, rinse the beaker with a little warm water, and cool. Add an equal volume of alcohol, mix, and allow to stand for NLT 1 h.
Centrifuge until the precipitate is closely packed on the bottom of the bottle, and decant the supernatant. Wash the precipitate with successive 50-mL portions of alcohol solution (50 in 100) by centrifuging and decanting through a suitable filter until the washings are sugar free. [Note—To test for the presence of sugar, transfer a few drops of the washings to a test tube, and add 3 or 4 drops of a 20% solution of 1-naphthol in alcohol, prepared by dissolving 200 mg of 1-naphthol in 1 mL of alcohol and 2 mL of water. Shake the test tube well to allow uniform mixing, allow 2–4 mL of sulfuric acid to flow down the sides of the test tube, and hold the test tube upright. If sugar is present, the interface of the two liquids is colored faint to deep violet, and on shaking, the whole solution becomes blue-violet. ]
Transfer the residue from the bottle and hardened filter to a beaker with about 50 mL of water. Immerse the beaker in boiling water, and stir constantly for 15 min or until all of the starch is gelatinized. Cool the beaker to 55, add 20 mL of Malt extract, and hold at this temperature for 1 h. Heat again to boiling for a few min, cool to 55, add 20 mL of Malt extract, and hold at this temperature for 1 h or until the residue when treated with iodine TS shows no blue tinge upon microscopic examination. Cool, dilute with water to 250 mL, and filter.
General procedure: Transfer 200 mL of the Test solution to a flask fitted with a reflux condenser, add 20 mL of hydrochloric acid, and heat in a boiling water bath for 2.5 h. Cool, nearly neutralize with sodium hydroxide TS, complete neutralization with sodium carbonate TS, dilute with water to 500 mL, mix, and filter. The volume of aliquot taken depends on the starch content of the specimen under test (see Table 1). The aliquot should contain between 100 and 200 mg of dextrose. Transfer 50 mL of the filtrate to a 400-mL alkali-resistant glass beaker, add 50 mL of alkaline cupric tartrate TS, cover the beaker with a water glass, and heat. Adjust the flame in the burner so that the contents of the flask begin to boil in 4 min, and continue boiling for exactly 2 min. Filter the hot solution at once through a sintered-glass filter. Wash the precipitate of cuprous oxide thoroughly with water at about 60, then with 10 mL of alcohol, and finally with 10 mL of ether.
Table 1. Determination of the Optimum Aliquot
Expected Starch Content
(%) Aliquot
(mL)
60  25
50  35
40  50
30  50
20  50

For solutions of reducing sugars of comparatively high purity, proceed as directed in Method 1A to determine the amount of reduced copper obtained by weighing the dried cuprous oxide. For solutions of reducing sugars containing large amounts of organic impurities, including sucrose, proceed as directed in Method 1B to determine the amount of reduced copper obtained by titration with sodium thiosulfate.
Method 1A— Dry the precipitate obtained in General procedure for 30 min in an oven at 110 ± 2, cool to room temperature in a desiccator, and weigh. Refer to Table 2 to find the quantity of dextrose, in mg, corresponding to the weight of cuprous oxide found. Determine the percentage of dextrose and then the content of starch by the following formula:
Percentage of dextrose = (wt. of dextrose in mg × 0.1 × 500)/(wt. of sample in g × aliquot in mL)
Content of starch = % dextrose × 0.9
Table 2. Calculating Dextrose (mg) (applicable when Cu2O is weighed directly)
Cuprous
Oxide (Cu2O) Dextrose
(d-Glucose) Cuprous
Oxide (Cu2O) Dextrose
(d-Glucose) Cuprous
Oxide (Cu2O) Dextrose
(d-Glucose) Cuprous
Oxide (Cu2O) Dextrose
(d-Glucose) Cuprous
Oxide (Cu2O) Dextrose
(d-Glucose) Cuprous
Oxide (Cu2O) Dextrose
(d-Glucose)
10  4.0  90  38.9  170  75.1  250  112.8  330  152.2  410  193.7
12  4.9  92  39.8  172  76.0  252  113.7  332  153.2  412  194.7
14  5.7  94  40.6  174  76.9  254  114.7  334  154.2  414  195.8
16  6.6  96  41.5  176  77.8  256  115.7  336  155.2  416  196.8
18  7.5  98  42.4  178  78.8  258  116.6  338  156.3  418  197.9
                                    
20  8.3  100  43.3  180  79.7  260  117.6  340  157.3  420  199.0
22  9.2  102  44.2  182  80.6  262  118.6  342  158.3  422  200.1
24  10.0  104  45.1  184  81.5  264  119.5  344  159.3  424  201.1
26  10.9  106  46.0  186  82.5  266  120.5  346  160.3  426  202.2
28  11.8  108  46.9  188  83.4  268  121.5  348  161.4  428  203.3
                                    
30  12.6  110  47.8  190  84.3  270  122.5  350  162.4  430  204.4
32  13.5  112  48.7  192  85.3  272  123.4  352  163.4  432  205.5
34  14.3  114  49.6  194  86.2  274  124.4  354  164.4  434  206.5
36  15.2  116  50.5  196  87.1  276  125.4  356  165.4  436  207.6
38  16.1  118  51.4  198  88.1  278  126.4  358  166.5  438  208.7
                                    
40  16.9  120  52.3  200  89.0  280  127.3  360  167.5  440  209.8
42  17.8  122  53.2  202  89.9  282  128.3  362  168.5  442  210.9
44  18.7  124  54.1  204  90.9  284  129.3  364  169.6  444  212.0
46  19.6  126  55.0  206  91.8  286  130.3  366  170.6  446  213.1
48  20.4  128  55.9  208  92.8  288  131.3  368  171.6  448  214.1
                                    
50  21.3  130  56.8  210  93.7  290  132.3  370  172.7  450  215.2
52  22.2  132  57.7  212  94.6  292  133.2  372  173.7  452  216.3
54  23.0  134  58.6  214  95.6  294  134.2  374  174.7  454  217.4
56  23.9  136  59.5  216  96.5  296  135.2  376  175.8  456  218.5
58  24.8  138  60.4  218  97.5  298  136.2  378  176.8  458  219.6
                                    
60  25.6  140  61.3  220  98.4  300  137.2  380  177.9  460  220.7
62  26.5  142  62.2  222  99.4  302  138.2  382  178.9  462  221.8
64  27.4  144  63.1  224  100.3  304  139.2  384  180.0  464  222.9
66  28.3  146  64.0  226  101.3  306  140.2  386  181.0  466  224.0
68  29.2  148  65.0  228  102.2  308  141.2  388  182.0  468  225.1
                                    
70  30.0  150  65.9  230  103.2  310  142.2  390  183.1  470  226.2
72  30.9  152  66.8  232  104.1  312  143.2  392  184.1  472  227.4
74  31.8  154  67.7  234  105.1  314  144.2  394  185.2  474  228.3
76  32.7  156  68.6  236  106.0  316  145.2  396  186.2  476  229.6
78  33.6  158  69.5  238  107.0  318  146.2  398  187.3  478  230.7
                                    
80  34.4  160  70.4  240  108.0  320  147.2  400  188.4  480  231.8
82  35.3  162  71.4  242  108.9  322  148.2  402  189.4  482  232.9
84  36.2  164  72.3  244  109.9  324  149.2  404  190.5  484  234.1
86  37.1  166  73.2  246  110.8  326  150.2  406  191.5  486  235.2
88  38.0  168  74.1  248  111.8  328  151.2  408  192.6  488  236.3

Method 1B
sodium thiosulfate solution: Transfer 3.9 g of sodium thiosulfate, accurately weighed, to a 100-mL volumetric flask, dissolve in and dilute with water to volume, and mix.
potassium iodide solution: Dissolve 42 g of potassium iodide in 100 mL of water.
sodium acetate solution: Dissolve 5.74 g of sodium acetate in 10 mL of water.
copper solution: Transfer about 0.3 g of pure electrolytic copper, accurately weighed, to a 250-mL flask, add 5 mL of nitric acid to dissolve the copper, add about 25 mL of water, and boil to expel red fumes. Add about 5 mL of bromine TS, and boil until the bromine is completely removed. Cool, add 10 mL of Sodium acetate solution followed by 10 mL of Potassium iodide solution, and titrate with Sodium thiosulfate solution to a light yellow color. Add enough starch TS to produce a marked blue color, and continue the titration. As the endpoint nears, add 2 g of potassium thiocyanate, and stir until completely dissolved. Continue titration until the precipitate is completely white. One mL of Sodium thiosulfate solution is equivalent to about 10 mg of copper. [Note—It is essential that the concentration of Potassium iodide solution be carefully regulated. If the solution contains less than 320 mg of copper at the completion of titration, add 4.2–5 g of potassium iodide to make a total solution of 100 mL. If greater amounts of copper are present, add Potassium iodide solution slowly, with constant agitation, from the buret in amounts proportionately greater. ]
procedure: Wash the precipitated cuprous oxide obtained in General procedure with water, cover this filter with a watch glass, and dissolve the cuprous oxide with 5 mL of nitric acid directed under the watch glass with a pipette. Collect the filtrate in a 250-mL flask, wash the watch glass, and the filter with water. Collect all the washings in the flask. Boil the contents of the flask to expel red fumes. Add about 5 mL of bromine TS, and boil until the bromine is completely removed. Cool, and proceed as directed in Copper solution beginning with “add 10 mL of Sodium acetate solution”. From the volume of Sodium thiosulfate solution consumed, obtain the weight of copper, in mg, and multiply the weight of copper by 1.1259 to obtain the weight, in mg, of cuprous oxide. From Table 2, find the quantity of dextrose, in mg, corresponding to the weight of cuprous oxide. The content of starch is equivalent to the weight, in mg, of dextrose obtained times 0.9. Conduct a blank determination, using 50 mL of alkaline cupric tartrate TS and 50 mL of Malt extract. If the weight of the cuprous oxide so obtained exceeds 0.5 mg, correct the result of the determination accordingly. [Note—The alkaline cupric tartrate TS deteriorates on standing, and the quantity of cuprous oxide obtained in the blank determination increases. ]
method 2
The following method is specific for dextrose (glucose), and because of its extreme sensitivity it may account for differences noted between values obtained from the same specimen. Duplicate determinations do not vary more than 2%.
Glucoamylase solution: Prepare a solution of glucoamylase in water containing 30 International Units (IU)/mL. Use glucoamylase obtained preferably from Rhizopus delemar. The total glucoamylase activity of the test specimen being used should be NLT 150 IU.
Acetate buffer solution: Dissolve 16.4 g of sodium acetate in 100 mL of water, add 12.0 mL of glacial acetic acid, and mix. The pH of this solution is 4.8.
Phosphate buffer: Dissolve 3.63 g of tris(hydroxymethyl) aminomethane and 5.0 g of monobasic sodium phosphate in 50.0 mL of water. At 37, adjust with phosphoric acid to a pH of 7.0, dilute with water to 100.0 mL, and mix. [Note—The pH of the buffer medium is sensitive to temperature and should be adjusted to the desired pH at the temperature to be used during incubation. ]
Enzyme solution: Dissolve 30 mg of glucose oxidase (Type II from Aspergillus niger), 3 mg of peroxidase (Type I from horseradish), and 10 mg of potassium ferrocyanide in 100 mL of Phosphate buffer. [Note—This mixture can be stored in a refrigerator for up to 10 days. ]
18 N sulfuric acid: Add slowly, while stirring, 54 mL of sulfuric acid to 102 mL of water, allow to cool to 25, and mix.
Standard solutions: Dissolve an accurately weighed quantity of USP Dextrose RS in water to obtain a solution containing 1.0 mg of USP Dextrose RS per mL. Quantitatively dilute a known volume of this solution with water to obtain Standard solutions A, B, C, D, and E, having known concentrations of 10, 20, 25, 40, and 50 &micro;g/mL of USP Dextrose RS, respectively. [Note—Allow 4 h for complete mutarotation before use. ]
Test solutions: Extract about 5 g of finely ground test specimen with five 25-mL portions of 80% alcohol, and filter. Remove all the alcohol from the residue by drying in an air oven at 105 for about 8 h. [Note 1—Any traces of alcohol remaining in the residue will inhibit glucoamylase. ] Cool, and transfer the flask containing the dried test specimen to a desiccator. Transfer about 1 g, accurately weighed, of the test specimen to a previously tared flask, add 25 mL of water, and adjust with phosphoric acid to a pH of 5.0–7.0, if necessary. Boil the suspension for about 3 min, transfer the flask to an autoclave, and heat to 135 for 2 h. Remove the flask from the autoclave, maintain the temperature near 55, and add 2.5 mL of Acetate buffer solution and sufficient water to adjust the total weight of the solution to 45 ± 1 g. Immerse the flask in a water bath maintained at 55 ± 1, and add 5 mL of Glucoamylase solution. Continuously swirl the flask for 2 h to effect hydrolysis, pass through filter paper into a 250-mL volumetric flask, wash quantitatively with water, and collect all the washings in the flask. Dilute the contents of the flask with water to volume, and mix. Transfer 1 mL of an aliquot containing 20–60 &micro;g of d-glucose to each of five test tubes. [Note 2—To obtain the range of concentration of glucose in the hydrolysate, quantitatively dilute, if necessary, with water to volume. ] Add 2 mL of Enzyme solution to each of the five test tubes, and place the test tubes in the dark at 37 ± 1 for exactly 30 min to develop the color. At the end of 30 min, add 2 mL of 18 N sulfuric acid to each of the test tubes to stop the reaction, and mix.
Control solution: Transfer an accurately weighed quantity of about 0.4 g of starch to a previously tared flask, and proceed as directed in Test solutions beginning with “add 25 mL of water, and adjust the pH with phosphoric acid”.
Procedure: Concomitantly determine the absorbances of the Standard solutions and the Test solutions at the wavelength of maximum absorbance at about 540 nm, with a suitable spectrophotometer, using the Control solution as the blank to set the instrument. Plot the absorbance values of the Standard solutions versus concentration, in &micro;g/mL, of dextrose, and draw the straight line best fitting the five plotted points. From the graph so obtained, determine the concentration, C, in &micro;g/mL, of dextrose in each of the Test solutions, calculate the average concentration, in &micro;g/mL, of the solution under test. The percentage of starch content in the weight of the test specimen taken is calculated by the formula:
(0.9C/106) × V1 × (250/V0)(100/E)(100/W) = 2.25CV1/V0EW
in which E is the weight, in g, of the test specimen taken; V0 is the volume, in mL, of the aliquot taken from the 250-mL volumetric flask; W is the percentage of dry weight of the test specimen; and V1 is the volume, in mL, if extra dilution is done (see Note 2 in Test solutions). [Note—V0 is 1.0 when no extra dilution is done. ]
Volatile Oil Determination
Set up a round-bottom, shortneck, 1-L flask in a heating mantle set over a magnetic stirrer. Insert an egg-shaped stirring bar magnet in the flask, and attach a cold-finger condenser and an appropriate volatile oil trap of the type illustrated (see Figure 1).

Figure 1. Traps for volatile oil apparatus.
Coarsely comminute a sufficient quantity of the drug to yield from 1 to 3 mL of volatile oil. Small seeds, fruits, or broken leaves of herbs ordinarily do not need comminution. Very fine powders are to be avoided. If this is not possible, it may be necessary to mix them with purified sawdust or purified sand. Place a suitable quantity of the drug, accurately weighed, in the flask, and fill it one-half with water. Attach the condenser and the proper separator. Boil the contents of the flask, using a suitable amount of heat to maintain gentle boiling for 2 h, or until the volatile oil has been completely separated from the drug and no longer collects in the graduated tube of the separator.
If a proper quantity of the volatile oil has been obtained in the graduated tube of the separator, it can be read to tenths of 1 mL, and the volume of volatile oil from each 100 g of drug can be calculated from the weight of the drug taken. The graduations on the separator “for oils heavier than water” are so placed that oil remains below the aqueous condensate that automatically flows back into the flask.
Water Content
For unground or unpowdered drugs, prepare about 10 g of the Laboratory Sample by cutting, granulating, or shredding, so that the parts are about 3 mm in thickness. Seeds or fruits smaller than 3 mm should be cracked. Avoid the use of high-speed mills in preparing the sample, and exercise care that no appreciable amount of moisture is lost during the preparation and that the portion taken is representative of the Laboratory Sample. Determine the water content as directed for Procedure for Articles of Botanical Origin in Water Determination 921, Method III (Gravimetric).

TEST FOR AFLATOXINS
Caution—Aflatoxins are highly dangerous, and extreme care should be exercised in handling aflatoxin materials.
Where the individual monograph calls for compliance with the limits for aflatoxins, the limits are NMT 5 ppb for aflatoxin B1 (AFB1) and NMT 20 ppb for the sum of aflatoxins B1 (AFB1), B2 (AFB2), G1 (AFG1), and G2 (AFG2). The extent of testing may be determined using a risk-based approach that considers the likelihood of contamination. The presence of unexpected contamination with aflatoxins is to be considered in determining compliance. The following analytical procedures are provided for determining compliance. Unless otherwise specified in the individual monograph, use Method I. If system suitability fails, use either Method II or Method III.
Method I
This TLC test is provided to detect the possible presence of AFB1, AFB2, AFG1, and AFG2 in any material of plant origin.
zinc acetate–aluminum chloride reagent
Dissolve 20 g of zinc acetate and 5 g of aluminum chloride in sufficient water to make 100 mL.
sodium chloride solution
Dissolve 5 g of sodium chloride in 50 mL of water.
test solution 1
Grind about 200 g of plant material to a fine powder. Transfer about 50 g of the powdered material, accurately weighed, to a glass-stoppered flask. Add 200 mL of a mixture of methanol and water (17:3). Shake vigorously by mechanical means for NLT 30 min, and filter. [Note—If the solution has interfering plant pigments, proceed as directed for Test Solution 2. ] Discard the first 50 mL of the filtrate, and collect the next 40-mL portion. Transfer the filtrate to a separatory funnel. Add 40 mL of Sodium Chloride Solution and 25 mL of solvent hexane, and shake for 1 min. Allow the layers to separate, and transfer the lower aqueous layer to a second separatory funnel. Extract the aqueous layer in the separatory funnel twice, each time with 25 mL of methylene chloride, by shaking for 1 min. Allow the layers to separate each time, separate the lower organic layer, and collect the combined organic layers in a 125-mL conical flask. Evaporate the organic solvent on a water bath. Transfer the remaining extract to an appropriate sample tube, and evaporate to dryness on a water bath. Cool the residue. If interferences exist in the residue, proceed as directed for Cleanup procedure in Test Solution 2. Otherwise, dissolve the residue obtained above in 0.2 mL of a mixture of chloroform and acetonitrile (9.8: 0.2), and shake by mechanical means if necessary.
test solution 2
Collect 100 mL of the filtrate from the start of the flow, and transfer to a 250-mL beaker. Add 20 mL of Zinc Acetate–Aluminum Chloride Reagent and 80 mL of water. Stir, and allow to stand for 5 min. Add 5 g of a suitable filtering aid, such as diatomaceous earth, mix, and filter. Discard the first 50 mL of the filtrate, and collect the next 80-mL portion. Proceed as directed for Test Solution 1, beginning with “Transfer the filtrate to a separatory funnel”.
Cleanup procedure: Place a medium-porosity sintered-glass disk or a glass wool plug at the bottom of a 10-mm × 300-mm chromatographic tube. Prepare a slurry of 2 g of silica gel with a mixture of ethyl ether and solvent hexane (3:1), pour the slurry into the column, and wash with 5 mL of the same solvent mixture. Allow the absorbent to settle, and add to the top of the column a layer of 1.5 g of anhydrous sodium sulfate. Dissolve the residue obtained above in 3 mL of methylene chloride, and transfer it to the column. Rinse the flask twice with 1-mL portions of methylene chloride, transfer the rinses to the column, and elute at a rate NMT 1 mL/min. Add successively to the column 3 mL of solvent hexane, 3 mL of ethyl ether, and 3 mL of methylene chloride; elute at a rate NMT 3 mL/min; and discard the eluates. Add to the column 6 mL of a mixture of methylene chloride and acetone (9:1), and elute at a rate NMT 1 mL/min, preferably without the aid of vacuum. Collect this eluate in a small vial, add a boiling chip if necessary, and evaporate to dryness on a water bath. Dissolve the residue in 0.2 mL of a mixture of chloroform and acetonitrile (9.8: 0.2), and shake by mechanical means if necessary.
test solution 3
If interferences still exist in the residue, proceed as directed for Cleanup procedure with IAC in Test Solution in Method II.
aflatoxin solution
Caution—Aflatoxins are highly toxic. Handle with care.
Dilute the USP Aflatoxins RS 1:5 with acetonitrile to obtain a solution having a concentration of 0.4 &micro;g/mL each of AFB1 and AFG1, and 0.1 &micro;g/mL each of AFB2 and AFG2.
procedure
Separately apply 2.5, 5, 7.5, and 10 &micro;L of the Aflatoxin Solution and three 10-&micro;L applications of either Test Solution 1, Test Solution 2, or Test Solution 3 to a suitable thin-layer chromatographic plate (see Chromatography 621) coated with a 0.25-mm layer of chromatographic silica gel mixture. Superimpose 5 &micro;L of the Aflatoxin Solution on one of the three 10-&micro;L applications of the Test Solution. Allow the spots to dry, and develop the chromatogram in an unsaturated chamber containing a solvent system consisting of a mixture of chloroform, acetone, and isopropyl alcohol (85:10:5) until the solvent front has moved NLT 15 cm from the origin. Remove the plate from the developing chamber, mark the solvent front, and allow the plate to air-dry. Locate the spots on the plate by examination under UV light at 365 nm.
system suitability
The four applications of the Aflatoxin Solution appear as four clearly separated blue fluorescent spots. Observe any spot obtained from the Test Solution that coincides in hue and position with those of the Aflatoxin Solution. Any spot obtained from the Test Solution with the superimposed Aflatoxin Solution is not less intense than that of the corresponding Aflatoxin Solution.
acceptance criteria
No spot from any of the other applications of the Test Solution corresponds to any of the spots obtained from the applications of the Aflatoxin Solution. If any spot of aflatoxins is obtained in the Test Solution, match the position of each fluorescent spot of the Test Solution with those of the Aflatoxin Solution to identify the type of aflatoxin present. The intensity of the aflatoxin spot, if present in the Test Solution, when compared with that of the corresponding aflatoxin in the Aflatoxin Solution will give an approximate concentration of aflatoxin in the Test Solution. Where the individual monograph calls for compliance with the limits for aflatoxins, the limits are NMT 5 ppb for AFB1 and NMT 20 ppb for the sum of AFB1, AFB2, AFG1, and AFG2, except when otherwise indicated.
Method II
sodium chloride solution
See Method I.
phosphate buffered saline solution
Prepare 10 mM phosphate buffer solution containing 0.138 M sodium chloride and 0.0027 M potassium chloride in water, and adjust with 2 M sodium hydroxide to a pH of 7.4.1
immunoaffinity column (iac)
Before conditioning, adjust the IAC to room temperature. For conditioning, apply 10 mL of Phosphate Buffered Saline Solution onto the column and let it flow through the column by gravity force at a rate of 2–3 mL/min. Leave 0.5 mL of the Phosphate Buffered Saline Solution on top of the column until the Test Solution is applied.
test solution
Sample extraction: Transfer about 5 g of a representative powdered sample, accurately weighed, to a glass-stoppered flask. Add 20 mL of a mixture of methanol and water (17:3). Shake vigorously by mechanical means for NLT 30 min, and filter. Discard the first 5 mL of the filtrate, and collect the next 4-mL portion. Transfer the filtrate to a separatory funnel. Add 4 mL of Sodium Chloride Solution and 2.5 mL of hexane, and shake for 1 min. Allow the layers to separate, and transfer the lower aqueous layer to a second separatory funnel. Extract the aqueous layer in the separatory funnel twice, each time with 2.5 mL of methylene chloride, by shaking for 1 min. Allow the layers to separate each time, separate the lower organic layer, and collect the combined organic layers in a 50-mL conical flask. Evaporate the organic solvent on a water bath. Transfer the remaining extract to an appropriate sample tube, and evaporate to dryness on a water bath. Cool the residue. If interferences exist in the residue, proceed as directed for Cleanup procedure with IAC. Otherwise, dissolve the residue obtained above in 200 &micro;L of acetonitrile, and shake by mechanical means if necessary.
Cleanup procedure with IAC: The residue is dissolved in 5 mL of a mixture of methanol and water (60:40) and then diluted with 5 mL of water. This extract is applied onto a conditioned IAC. The IAC is rinsed twice with 10 mL of Phosphate Buffered Saline Solution, and the elution is performed slowly with 2 mL of methanol. Evaporate the eluate with nitrogen, and dissolve the residue in 200 &micro;L of acetonitrile.
aflatoxin solution
Caution—Aflatoxins are highly toxic. Handle with care.
Dilute quantitatively the USP Aflatoxins RS 1:50 with acetonitrile to obtain a solution containing 0.04 &micro;g/mL each of AFB1 and AFG1, and 0.01 &micro;g/mL each of AFB2 and AFG2.
analysis
Separately apply 5, 7.5, and 10 &micro;L of Aflatoxin Solution and three 10-&micro;L applications of the Test Solution to a suitable HPTLC plate (see Chromatography 621) coated with a 200-&micro;m layer of chromatographic silica gel mixture. Superimpose 5 &micro;L of Aflatoxin Solution on one of the three 10-&micro;L applications of the Test Solution. Allow the spots to dry, and develop the chromatogram in a saturated chamber containing a solvent system consisting of a mixture of chloroform, acetone, and water (140: 20: 0.3) until the solvent front has moved NLT 72 mm from the origin (80 mm from the lower edge of the plate). Remove the plate from the developing chamber, mark the solvent front, and allow the plate to air-dry for 5 min. Locate the spots on the plate by scanning fluorescence density (>400 nm) under UV light at 366 nm. Match the position of each fluorescent spot of the Test Solution with those of Aflatoxin Solution to identify the type of aflatoxin present. The concentration of aflatoxins in the Test Solution can be calculated from the calibration curve obtained from the scan data with Aflatoxin Solution.
system suitability
The four applications of Aflatoxin Solution appear as four clearly separated blue fluorescent spots. Observe any spot obtained from the Test Solution that coincides in hue and position with those of Aflatoxin Solution. Any spot obtained from the Test Solution with the superimposed Aflatoxin Solution is not less intense than that of the corresponding Aflatoxin Solution. The mean recovery of spiked AFB1 and AFG1 is NLT 70%.
acceptance criteria
Where the individual monograph calls for compliance with the limits for aflatoxins, the limits are NMT 5 ppb for AFB1 and NMT 20 ppb for the sum of AFB1, AFB2, AFG1, and AFG2, except when otherwise indicated.
Method III
This test method is provided as an example for the detection of the possible presence of AFB1 and total aflatoxins (AF: sum of AFB1, AFB2, AFG1, and AFG2). It has been shown to be suitable for powdered ginseng and ginger. Its suitability to other articles of botanical origin must be demonstrated.
0.1 m phosphate buffer solution
Dissolve 8.69 g of anhydrous disodium phosphate and 4.66 g of anhydrous monosodium phosphate or 5.36 g of monosodium phosphate monohydrate in 800 mL water, adjust with 2 M sodium hydroxide to a pH of 7.4, add 10 mL of polysorbate 20, and dilute to 1 L.
phosphate buffered saline solution
Prepare as directed in Method II.
working aflatoxin standard solutions
Prepare six solutions in separate 10-mL volumetric flasks according to Table 3. Dilute with methanol and water (1:1, v/v) to volume. Store in a refrigerator, and equilibrate to room temperature before use. Prepare the solutions daily.
Table 3. Preparation of Working Aflatoxin Standard Solutions
Working
Aflatoxin
Standard
Solutions USP Aflatoxins RS (&micro;L) Final Aflatoxin Concentration of Working Aflatoxin Standard Solution (ng/mL)
AFB1 AFB2 AFG1 AFG2 SAF
1  0  0  0  0  0  0
2  12.5  0.25  0.0625  0.25  0.0625  0.625
3  25  0.5  0.125  0.5  0.125  1.25
4  50  1  0.25  1  0.25  2.5
5  100  2  0.5  2  0.5  5
6  200  4  1  4  1  10

immunoaffinity column (iac)2
Use an immunoaffinity column that contains monoclonal antibodies cross reactive toward AFB1, AFB2, AFG1, and AFG2. The immunoaffinity columns have a minimum capacity of NLT 100 ng of total aflatoxin and give a recovery of NLT 80% for AFB1, AFB2, AFG1, and AFG2 when 5 ng of each AFB1, AFB2, AFG1, and AFG2 is applied in 10 mL of 10% methanol in Phosphate Buffered Saline Solution (v/v).
test solution
Extraction: Weigh 5 g of a representative test sample in a 50-mL centrifuge tube. Add 1 g of sodium chloride and 25 mL of a mixture of methanol and 0.5% sodium bicarbonate (700:300). Mix on a vortex mixer until sample particles and extract solvent are well mixed. Shake at 400 rpm for 10 min. Centrifuge for 10 min at 7000 rpm (g value = 5323 mm/s2) or at a speed that can result in a firm pellet of residues. Immediately pipette 7 mL into a 50-mL centrifuge tube, add 28 mL of 0.1 M Phosphate Buffer Solution, mix, and filter through glass microfiber paper. Collect 25 mL of filtrate (equivalent to 1 g of test sample) into a 25-mL graduated cylinder, and proceed immediately with IAC chromatography.
IAC cleanup: [Note—For IAC cleanup, columns must be kept at room temperature for at least 15 min before use. ] Remove the top cap from the column, and connect it with the reservoir. Remove the end cap from the column, and attach it to the column manifold (the fit must be tight). Let the liquid in the column pass through until the liquid is about 2–3 mm above the column bed. Pass 25 mL of filtrate into the reservoir. Let the filtrate flow through the column by gravity force. Let the column run dry. To start the flow again easily, remove the column from the manifold, add about 2 mL of Phosphate Buffered Saline Solution into the column, reattach the column to the reservoir, and wash the column with an additional 3 mL of Phosphate Buffered Saline Solution and then with 5 mL of water (the 5 mL of Phosphate Buffered Saline Solution can be added directly to the column reservoir if other techniques are used to dislodge the air bubble at the end of the column and to start flow again easily). Let the column run dry, then force 3 mL of air through the column with a syringe. Elute with 1 mL of methanol, and collect the analytes in a 3-mL volumetric flask, letting the eluate drip freely. Let the column run dry. Let stand for 1 min, then elute with an additional 1 mL of methanol, and collect in the same volumetric flask. Let the column run dry, and force 10 mL of air through the column. Dilute the eluate with water to volume. Use this as the Test Solution, and perform the analysis of aflatoxins immediately.
system suitability solution
Prepare a spiked sample by adding 5 mL of Working Aflatoxin Standard Solution 5 to a 5-g sample and repeating the procedure for the Test Solution, using 20 mL instead of 25 mL of the mixture of methanol and 0.5% sodium bicarbonate (700:300).
chromatographic system
Flow rate: 0.8 mL/min
Detection: Fluorescence detector set at excitation wavelength (Ex) 362 nm and emission wavelength (Em) 440 nm
Column: 4.6-mm × 15-cm containing 3-&micro;m packing L1
Mobile phase: Isocratic
For post-column derivatization with PHRED cell3— Water, methanol, and acetonitrile (600:250:150)
For post-column derivatization with Kobra cell4— A solution prepared by mixing 1 L of a mixture of water, methanol, and acetonitrile (600:250:150); 350 &micro;L of 4 M nitric acid; and 120 mg of potassium bromide
Post-column derivatization (PCD) systems
PHRED cell— Post-column photochemical derivatization cell
Kobra cell— Electrochemical cell, post-column bromination derivatization cell
analysis
Post-column derivatization for aflatoxins: Use a UV or Kobra cell. Inject 50 &micro;L of reagent blank (Working Aflatoxin Standard Solution 1), Working Aflatoxin Standard Solutions 2–6, or the Test Solution into the LC column. Identify the aflatoxin peaks in the Test Solution by comparing the retention times with those of the working standards. The aflatoxins elute in the order AFG2, AFG1, AFB2, and AFB1. After passing through the PHRED or Kobra cell, the AFG1 and AFB1 have been derivatized to form AFG2a (derivative of AFG1) and AFB2a (derivative of AFB1). [Note—The chemical structures of the derivatives resulting from electrochemical bromination and photolysis are not the same. The structures of AFB1 and AFG1 photolysis products have not been established. ] The retention times of AFG2, AFG2a, AFB2, and AFB2a are between about 14 and 27 min using the PHRED cell; retention times are shorter using the Kobra cell. The peaks should be baseline resolved. Construct standard curves for each aflatoxin. Determine the concentration of each aflatoxin in the Test Solution from the calibration curve.
Aflatoxins calibration curves: Calibration curves are prepared for each of the aflatoxins using the Working Aflatoxin Standard Solutions containing the four aflatoxins described. These solutions cover the range of 0.25–4 ng/mL for AFB1 and AFG1, and the range of 0.0625–1 ng/mL for AFB2 and AFG2. Make the calibration curves before analysis according to Table 3, and check the plot for linearity. If the test portion area response is outside (higher) the calibration range, then the Test Solution should be diluted with a mixture of methanol and water (1:1, v/v) and reinjected into the LC column.
Quantitation of aflatoxins: Quantitation of aflatoxins is performed by measuring peak areas at each aflatoxin retention time and comparing them with the corresponding calibration curve.
system suitability
The mean recovery of spiked AFB1 (2 &micro;g/kg) and the total of aflatoxins (5 &micro;g/kg) is NLT 68% and 70%, respectively. The relative standard deviation (RSD) is NMT 10% for AFB1 and for the total of aflatoxins.
calculations
Plot the peak area (response, y-axis) of each of the toxin standards against the concentration (ng/mL, x-axis) and determine the slope (S) and y-intercept (a). Calculate the level of toxin in the sample by the following formula:
Toxin (&micro;g/kg) = {[(R  a)/S] × V/W} × F
where R is the Test Solution peak area; V is the final volume of the injected Test Solution (mL); and F is the dilution factor. F = 1 when V = 3 mL. W is 1 g of test sample passed through the immunoaffinity column. The total of aflatoxins is the sum of AFG2, AFG1, AFB2, and AFB1.
acceptance criteria
Where the individual monograph calls for compliance with the limits for aflatoxins, the limits are NMT 5 ppb for AFB1 and NMT 20 ppb for the sum of AFB1, AFB2, AFG1, and AFG2, except when otherwise indicated.
Change to read:

2S (USP38) PESTICIDE  RESIDUE2S (USP38) ANALYSIS
Definition
Where used in this Pharmacopeia, the designation “pesticide” applies to any substance or mixture of substances intended to prevent, destroy, or control any pest, unwanted species of plants,  fungus,2S (USP38) or animals causing harm during or otherwise interfering with the production, processing, storage, transport, or marketing of pure articles. The designation includes substances intended for use as growth regulators, defoliants, or desiccants, and any substance applied to crops before or after harvest to protect the product from deterioration during storage and transport.
Limits
Within the United States, many botanicals are treated as dietary supplements and are subject to the statutory provisions that govern foods but not drugs in the Federal Food, Drug, and Cosmetic Act. Limits for pesticides  in2S (USP38) foods are determined by the Environmental Protection Agency (EPA) as indicated in the Code of Federal Regulations (40 CFR Part 180) or the Federal Register (FR).  In addition, the Food and Drug Administration (FDA) establishes action levels for unavoidable pesticide residues (21 CFR Part 109 and 21 CFR Part 509).2S (USP38) For pesticide chemicals without EPA-established tolerance levels  or FDA action levels,2S (USP38) the  residues2S (USP38) should be below the detection limit of the specified method. Results less than the EPA detection limits are considered zero values. The limits contained herein, therefore, are not applicable in the United States when articles of botanical  origin2S (USP38) are labeled for food purposes. The limits, however, may be applicable in other countries.  2S (USP38) Unless otherwise indicated in the monograph, the article to be examined complies with the limits  given2S (USP38) in Table 4. The limits for suspected pesticides that are not listed in Table 4 must comply with the regulations of the EPA. For instances in which a pesticide is not listed in Table 4 or in EPA regulations, calculate the limit by the formula:
Limit (mg/kg) = AM/100B2S (USP38)
where A is the acceptable daily intake (ADI), as published by FAO-WHO, in mg/kg of body weight; M is body weight, in kg (60 kg); and B is the daily dose of the article, in kg.
If the article is intended for the preparation of extracts, tinctures, or other pharmaceutical forms of which the preparation method modifies the content of pesticides in the finished product, calculate the limits by the formula:
Limit (mg/kg) = AME/100B2S (USP38)
where E is the extraction factor of  pesticide in2S (USP38) the preparation method, determined experimentally  as the ratio between the original pesticide content in the plant material and the final pesticide content in the preparation; B is the daily dose of the preparation in kg;2S (USP38) and A  and M2S (USP38) are as defined above.
A total or partial exemption from the test may be granted when the complete history (nature and quantity of the pesticides used, date of each treatment during cultivation and after harvest) of the treatment of the batch is known and can be checked precisely according to good agricultural and collection practice (GACP).
Table 4
Substance  Limit
(mg/kg)
Acephate  0.1
Alachlor  0.05
Aldrin and dieldrin (sum of)  0.05
Azinphos-ethyl  0.1
Azinphos-methyl  1
Bromide, inorganic (calculated as bromide ion)   125(RB 1-Aug-2014)  
Bromophos-ethyl  0.05
Bromophos-methyl  0.05
  Bromopropylate2S (USP38)   3
Chlordane (sum of cis-, trans-, and oxychlordane)  0.05
Chlorfenvinphos  0.5
Chlorpyriphos-ethyl  0.2
Chlorpyriphos-methyl  0.1
Chlorthal-dimethyl  0.01
Cyfluthrin (sum of)  0.1
-Cyhalothrin  1
Cypermethrin and isomers (sum of)  1
DDT (sum of o,p&cent;-DDE, p,p&cent;-DDE, o,p&cent;-DDT, p,p&cent;-DDT, o,p&cent;-TDE, and p,p&cent;-TDE)  1
Deltamethrin  0.5
Diazinon  0.5
Dichlofluanid  0.1
Dichlorvos  1
Dicofol  0.5
Dimethoate and omethoate (sum of)  0.1
Dithiocarbamates (expressed as CS2)  2
Endosulfan (sum of isomers and endosulfan sulphate)  3
Endrin  0.05
Ethion  2
Etrimphos  0.05
Fenchlorophos (sum of fenchlorophos and fenchlorophos-oxon)  0.1
Fenitrothion  0.5
Fenpropathrin  0.03
Fensulfothion (sum of fensulfothion, fensulfothion-oxon,  fensulfothion-oxon sulfone, and fensulfothion sulfone)2S (USP38)   0.05
Fenthion (sum of fenthion, fenthion-oxon,  fenthion-oxon sulfone, fenthion-oxon sulfoxide, fenthion sulfone, and
fenthion-sulfoxide)2S (USP38)   0.05
Fenvalerate  1.5
  Flucythrinate2S (USP38)   0.05
-Fluvalinate  0.05
Fonophos  0.05
Heptachlor (sum of heptachlor, cis-heptachlorepoxide, and trans-heptachlorepoxide)  0.05
Hexachlorbenzene  0.1
Hexachlorocyclohexane (sum of isomers -, -, -, and -)  0.3
Lindan (-hexachlorocyclohexane)  0.6
Malathion and malaoxon (sum of)  1
Mecarbam  0.05
Methacriphos  0.05
Methamidophos  0.05
Methidathion  0.2
Methoxychlor  0.05
Mirex  0.01
Monocrotophos  0.1
Parathion-ethyl and paraoxon-ethyl (sum of)  0.5
Parathion-methyl and paraoxon-methyl (sum of)  0.2
Pendimethalin  0.1
  Pentachloranisole2S (USP38)   0.01
Permethrin and isomers (sum of)  1
Phosalone  0.1
Phosmet  0.05
Piperonyl butoxide  3
Pirimiphos-ethyl  0.05
Pirimiphos-methyl (sum of pirimiphos-methyl and N-desethyl-pirimiphos-methyl)  4
Procymidone  0.1
Profenophos  0.1
Prothiophos  0.05
Pyrethrum (sum of cinerin I, cinerin II, jasmolin I, jasmolin II, pyrethrin I, and pyrethrin II)  3
Quinalphos  0.05
Quintozene (sum of quintozene, pentachloraniline, and methyl pentachlorphenyl sulfide)  1
S-421  0.02
Tecnazene  0.05
Tetradifon  0.3
Vinclozolin  0.4

2S (USP38)
Qualitative and quantitative analysis of pesticide residues:  Use analytical procedures validated e.g. in accordance with the latest version of the EU guideline on analytical quality control and validation procedures for pesticide residue analysis [Note—Current version Document No. SANCO/12571/2013, http://ec.europa.eu/food/plant/resources/qualcontrol_en.pdf ] or the EPA method validation principles (OPPTS 860.1340) that satisfy the following criteria. The method, especially with respect to its purification steps, is suitable for the combination of pesticide residue and substance under test, and is not susceptible to interference from co-extractives; the limit of quantification for each pesticide matrix combination to be analyzed is NMT the corresponding tolerance limit: the method is shown to recover between 70% and 120% of each pesticide with a repeatability NLT 20% RSD [Note—lower recoveries may be acceptable in certain cases as discussed in SANCO/12571/2013 ] ; and the concentrations of test and reference solutions and the setting of the apparatus are such that a linear response is obtained from the analytical detector.2S (USP38)
Delete the following:

TEST FOR PESTICIDES
Unless otherwise specified in the individual monograph, the following methods may be used for the analysis of pesticides. Depending on the substance being examined, it may be necessary to modify, sometimes extensively, the procedure described hereafter. Additionally, it may be necessary to perform another method with another column having a different polarity, another detection method (e.g., mass spectrometry), or a different method (e.g., immunochemical method) to confirm the results.
Extraction: [Note—Use the following procedure for the analysis of samples of articles having a water content of less than 15%. Samples having a higher water content may be dried, provided that the drying procedure does not significantly affect the pesticide content. ] To 10 g of the coarsely powdered substance under test add 100 mL of acetone, and allow to stand for 20 min. Add 1 mL of a solution in toluene containing 1.8 &micro;g of carbophenothion per mL. Mix in a high-speed blender for 3 min. Filter this solution, and wash the residue with two 25-mL portions of acetone. Combine the filtrate and the washings, and heat, in a rotary evaporator, maintaining the temperature of the bath below 40 until the solvent has almost completely evaporated. To the residue add a few mL of toluene, and heat again until the acetone is completely removed. Dissolve the residue in 8 mL of toluene. Pass through a membrane filter of 45-&micro;m pore size, rinse the flask and the filter with toluene, dilute with toluene to 10.0 mL (Solution A), and mix.
Purification
Organochlorine, Organophosphorus, and Pyrethroid Insecticides— The size-exclusion chromatograph is equipped with a 7.8-mm × 30-cm stainless steel column containing 5-&micro;m packing L21. Toluene is used as the mobile phase at a flow rate of about 1 mL/min.
Performance of the Column— Inject 100 &micro;L of a solution in toluene containing, in each mL, 0.5 mg of methyl red and 0.5 mg of oracet blue or equivalent. The column is not suitable unless the color of the eluate changes from orange to blue at an elution volume of about 10.3 mL. If necessary, calibrate the column, using a solution in toluene containing suitable concentrations of the pesticide of interest having the lowest molecular weight (for example, dichlorvos) and that having the highest molecular weight (for example, deltamethrin). Determine which fraction of the eluate contains both pesticides.
Purification of the Test Solution— Inject a suitable volume (100 to 500 &micro;L) of Solution A into the chromatograph. Collect the fraction (Solution B) as determined above under Performance of the Column. Organophosphorus pesticides elute between 8.8 and 10.9 mL. Organochlorine and pyrethroid pesticides elute between 8.5 and 10.3 mL.
Organochlorine and Pyrethroid Insecticides— Into a 5-mm × 10-cm chromatographic column, introduce a piece of fat-free cotton and 0.5 g of silica gel treated as follows. Heat chromatographic silica gel in an oven at 150 for at least 4 h. Allow to cool, and add dropwise a quantity of water corresponding to 1.5% of the weight of silica gel used. Shake vigorously until agglomerates have disappeared, and continue shaking by mechanical means for 2 h. Condition the column with 1.5 mL of hexane. [Note—Prepacked columns containing about 0.50 g of a suitable silica gel may also be used, provided they have been previously validated. ] Concentrate Solution B almost to dryness, with the aid of a stream of helium or oxygen-free nitrogen, and dilute with toluene to a suitable volume (200 &micro;L to 1 mL, according to the volume injected in the preparation of Solution B). Quantitatively transfer this solution to the column, and proceed with the chromatography, using 1.8 mL of toluene as the mobile phase. Collect the eluate (Solution C).
Quantitative Analysis of Organophosphorus Insecticides
Test Solution— Concentrate Solution B almost to dryness, with the aid of a stream of helium, dilute with toluene to 100 &micro;L, and mix.
Standard Solution— Prepare at least three solutions in toluene containing each of the pesticides of interest and carbophenothion at concentrations suitable for plotting a calibration curve.
Chromatographic System— The gas chromatograph is equipped with an alkali flame-ionization detector or a flame-photometric detector and a 0.32-mm × 30-m fused silica column coated with a 0.25-&micro;m layer of phase G1. Hydrogen is used as the carrier gas. Other gases, such as helium or nitrogen, may also be used. The injection port temperature is maintained at 250, and the detector is maintained at 275. The column temperature is maintained at 80 for 1 min, then increased to 150 at a rate of 30/min, maintained at 150 for 3 min, then increased to 280 at a rate of 4/min, and maintained at this temperature for 1 min. Use carbophenothion as the internal standard. [Note—If necessary, use a second internal standard to identify any possible interference with the peak corresponding to carbophenothion. ] Inject the chosen volume of each solution, record the chromatograms, and measure the peak responses. Calculate the content of each pesticide from the peak areas and the concentrations of the solution.
Quantitative Analysis of Organochlorine and Pyrethroid Insecticides
Test Solution— Concentrate Solution C almost to dryness, with the aid of a stream of helium or oxygen-free nitrogen, dilute with toluene to 500 &micro;L, and mix.
Standard Solution— Prepare at least three solutions in toluene containing each of the pesticides of interest and carbophenothion at concentrations suitable for plotting a calibration curve.
Chromatographic System— The gas chromatograph is equipped with an electron-capture detector, a device allowing direct on-column cold injection, and a 0.32-mm × 30-m fused silica column coated with a 0.25-&micro;m layer of phase G1. Hydrogen is used as the carrier gas. Other gases, such as helium or nitrogen, may also be used. The injection port temperature is maintained at 275, and the detector is maintained at 300. The column temperature is maintained at 80 for 1 min, then increased to 150 at a rate of 30/min, maintained at 150 for 3 min, then increased to 280 at a rate of 4/min, and maintained at this temperature for 1 min. Use carbophenothion as the internal standard. [Note—If necessary, use a second internal standard to identify any possible interference with the peak corresponding to carbophenothion. ] Inject the chosen volume of each solution, record the chromatograms, and measure the peak responses. Calculate the content of each pesticide from the peak areas and the concentrations of the solutions.
2S (USP38)
Add the following:

LIMITS OF ELEMENTAL IMPURITIES
The levels of elemental impurities should be restricted as shown in Table 5 unless otherwise stated in the individual monograph. Specific monographs may provide different limits for articles that are typically used in large quantities.
Table 5. Limits of Elemental Impurities
Element  Limits
(&micro;g/g)
Arsenic (inorganic)a  2
Cadmium  0.5
Lead  5
Mercury (total)  1
Methylmercury (as Hg)b  0.2
a  Arsenic may be measured using a nonspeciation procedure under the assumption that all arsenic contained in the supplement is in the inorganic form. Where the limit is exceeded using a nonspeciation procedure, compliance with the limit for inorganic arsenic shall be demonstrated on the basis of a speciation procedure.
b  Methylmercury determination is not necessary when the content for total mercury is less than the limit for methylmercury.  

Articles are tested according to the procedures set forth in Elemental Impurities—Procedures 233. Where speciation is required, the procedures given in Elemental Contaminants in Dietary Supplements 2232 are used for testing.2S (USP38)

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1  A suitable powder mixture is available from Sigma as PBS P-3813.
2  AflaOchraTest column (G1017; Vicam, Watertown, MA, USA) or equivalent. Aflatoxin/OTA immunoaffinity columns are suitable.
3  PHRED&#8482; Photochemical Reactor (AURA Industries, New York, NY, USA) or equivalent. Avoid looking at the UV lamp.
4  Kobra Cell&#8482; (R-Biopharm Inc., Marshall, MI, USA) or equivalent. Set at 100 mA. Do not turn on the current until the LC pump is operating to avoid overheating the cell membrane.
Auxiliary Information— Please check for your question in the FAQs before contacting USP.
Topic/Question Contact Expert Committee
General Chapter  Christopher O Okunji, Ph.D.
Scientific Liaison, Dietary Supplements
(301) 230-3244  (GCCA2010) General Chapters - Chemical Analysis

USP38–NF33 Page 345
USP38–NF33 Supplement : No. 2 Page 7601
Pharmacopeial Forum: Volume No. 40(5)

四叶花

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(出处: 蒲公英 - 制药技术的传播者 GMP理论的实践者)

vincentchampion

积分不足，好忧伤