欧盟官网上的最新HPLC确认方案

piao0923

附件为我从欧盟官网上下载下来的最新的HPLC确认方案，相信很多人在写HPLC确认方案时不知道各项目的合格标准定为多少合适？比如流速的误差范围，保留时间的误差范围，峰面积的误差范围，柱温箱的温度误差范围，等等，在该方案中都可以找到标准答案。由于时间有限，很抱歉我来不及翻译，如果有疑问或不明白的地方可以回帖提出来，我乐意为你解答。

毒手药王邓智先

PA/PH/OMCL (11) 04
QUALIFICATION OF EQUIPMENT ANNEX 1: QUALIFICATION OF HPLC EQUIPMENT
Full document title and reference        Qualification of Equipment
Annex 1: Qualification of HPLC equipment
PA/PH/OMCL (11) 04
Document type        Guideline
Legislative basis        The present document was also accepted by EA as recommendation document to be used in the context of Quality Management System audits of OMCLs
Date of first adoption        May 2005
Date of original entry into force        June 2005
Date of entry into force of revised document        1st July 2011
Previous titles/other references        This document replaces document PA/PH/OMCL (07) 17 DEF
Custodian
Organisation        The present document was elaborated by the OMCL Network/ EDQM of the Council of Europe
Concerned Network        GEON




ANNEX 1 OF THE OMCL NETWORK GUIDELINE “QUALIFICATION OF EQUIPMENT”
QUALIFICATION OF HPLC EQUIPMENT
Introduction
The present document is the first Annex of the core document “Qualification of Equipment”, and it should be used in combination with it when planning, performing and documenting the HPLC equipment qualification process.
The core document contains the general introduction and the Level I and II of qualification, common to all type of instruments, and the present annex contains HPLC instrument-related recommendations on parameters to be checked and the corresponding typical acceptance limits, as well as practical examples on the methodology that can be used to carry out these checks.
When qualifying HPLC equipment, it should be noted that it is acceptable to check at Level III and IV several of the mentioned parameters at the same time in a combined test procedure (e.g. “overall” system performance test giving information on peak area precision, retention time precision, gradient reproducibility, etc).
TABLE III
Level III. Periodic and motivated instrument checks Examples of requirements for HPLC instruments and detectors
Instrument module        Parameter to be checked        Typical tolerance
                limits
Solvent delivery system        •        Flow rate
•        Proportioning accuracy and precision (gradient test)
•        Proportioning ripple        •        土 5 %
•        土 2
&#8226;        < 0,2 %
Injector        &#8226;        Volume precision
&#8226;        Carry-over        &#8226;        RSD < 1.0 %
&#8226;        see Annex I
Autosampler        &#8226; Thermostatting accuracy and precision        &#8226; 土 3 °C
Oven or cooling device        &#8226; Thermostatting accuracy        &#8226; 土 2 °C
UV/DAD detector        &#8226;        Linearity
&#8226;        Wavelength accuracy        &#8226;        r2 > 0.999
&#8226;        土 2 nm
Fluorescence detector        &#8226;        Wavelength accuracy excitation
&#8226;        Wavelength accuracy emission
&#8226;        Sensitivity        &#8226;        土 3 nm
&#8226;        土 3 nm
&#8226;        see Annex I
Electrochemical detector        &#8226;        Accuracy of the signal
&#8226;        Stability of the signal        &#8226;        see Annex I
&#8226;        see Annex I
RID detector        &#8226;        Signal/Noise ratio
&#8226;        Drift over time        &#8226;        see Annex I
&#8226;        土 0.1 mV/min
CD detector        &#8226;        Signal/Noise ratio
&#8226;        Sensitivity
&#8226;        Drift over time
&#8226;        Linearity        &#8226;        see Annex I
&#8226;        see Annex I
&#8226;        see Annex I
&#8226;        r > 0.999


TABLE IV
Level IV. In-use instrument checks
Examples of requirements for HPLC instruments with UV or DAD detectors
Parameter to be checked        Typical tolerance limits
&#8226; System suitability check for the method        According to Ph. Eur. or MAH dossier or validated in-house method
&#8226; Peak area precision (applicable to the main peaks in the test solution)        RSD < 1.5 %
(unless otherwise prescribed in the system suitability of the method, e.g. specific requirements from Ph. Eur. 2.2.46, API monographs or MA dossiers)
&#8226; Retention time precision        RSD ± 5 %
&#8226; Carry-over (by comparing consecutive standard (of the substance being quantified) and blank injections)        < 0.2 %
&#8226; Signal/Noise ratio (to be applied for related substances test)        According to Ph. Eur.


ANNEX I
Level III. Periodic and motivated instrument checks
This Annex contains practical examples of tests and their associated tolerance limits for several parameters related to the performance of the different modules of a HPLC.
These examples can be considered by the OMCLs as possible approaches to perform the Level III of the equipment qualification process: “Periodic and motivated instrument checks”.
HPLC SOLVENT DELIVERY SYSTEM
The following tests are proposed for the periodic and motivated check of the HPLC solvent delivery system: flow rate and gradient test.
FLOW RATE
Materials:
Volumetric flask of 5 or 10 ml Calibrated chronometer
Settings:
Mobile phase: degassed water No column (open end)*
Flow rate: adjusted between 0.5 and 3.0 ml/min
If high-pressure mixing systems are installed, this test has to be done on each solvent channel.
* For certain equipment, e.g. in the case of low flow rates, the check would be performed by using a column or a backpressure regulator.
Method:
Set the flow rate at an appropriate level and measure the time needed to fill the volumetric flask up to the mark. Record the time needed.
V *60
f = V /1        f =
J 1
f.        measured flow rate [ml/min]
t         elapsed time to fill up to mark [s]
V        volume of the volumetric flask [ml]
D = 100-f—F
F
D        deviation [%]
F        adjusted flow rate [ml/min]
f.        measured flow rate [ml/min]
Limits: 土 5%
GRADIENT COMPOSITION AND RIPPLE
Settings:
Stainless steel capillary e.g. 2000 x 0.12 mm installed instead of a column Detection: UV-Detector adjusted to 265 nm Mobile phase A: degassed water
Mobile phase B: degassed water containing 0.5% acetone Flow rate: 1.0 ml/min
Method:
The test is carried out in the following way by using a gradient program depending on the number of solvent channels and the configuration of the system:
A-B
A-B and A-C A-C, A-B and B-D
time [min]        % mobile phase A (water)        % mobile phase B (water-acetone mixture)
0.0        100        0
0.1        90        10
10        90        10
10.1        50        50
20        50        50
20.1        10        90
30        10        90
30.1        0        100
40        0        100
40.1        100        0

Start the test by pumping water for at least 10 min to equilibrate the system.
The zero % value at the start of the test is the baseline. All steps are measured at the beginning of the horizontal part of the line either by software or manually on the paper print using a liner. The height of the 100% water/acetone mixture is used as the 100% value in the following calculation.
h
%H = 100*h H
%H        calculated composition
h         height of the measured line
H         height of the 100% water/acetone mixture line (mobile phase B)
d=%H - G
d         deviation
G        gradient composition adjusted [% acetone/water solution mixture = mobile phase B]
Limits:
Absolute deviation: 土 2 of the adjusted value
The ripple of the gradient composition is the percentage of noise of the 50% line from the gradient program.
N
%R = 100*1
h50
%R        ripple
h5Q        height of the 50% line
N        height of the noise line, measured during 1 minute in the linear region
Limits: < 0.2 %
HPLC INJECTOR
Volume precision and carry-over are the tests proposed for the periodic and motivated check of the HPLC injector.
VOLUME PRECISION AND CARRY-OVER
Solutions:
Solvent A: methanol : water R, 60 : 40.
Reference solution (a): dissolve 15.0 mg methyl-, ethyl-, and propylparabene in 100.0 ml of solvent A.
Reference solution (b): Dilute 1.0 ml of reference solution (a) to 10.0 ml of solvent A. Reference solution (c): Dilute 1.0 ml of reference solution (b) to 100.0 ml of solvent A.
Settings:
Column: Lichrospher 100 RP8, 5 jam, 125 x 4 mm, without precolumn
Mobile phase: methanol : water = 60 : 40
Flow rate: 1.0 ml/min
Detection: 254 nm
Injection volume: 20 |al
Method:
Injection scheme:
-6x reference solution (b)
-1x reference solution (a)
-1x solvent A (blank injection 1)
-1x reference solution (b)
-1x solvent A (blank injection 2)
-1x reference solution (c)
Limits:
Repeatability of peak areas: The relative standard deviation of the peak areas of all peaks in the chromatogram obtained with the reference solution (b) should be < 1.0 %.

Carry-over: The percentage of the peak area corresponding to propylparabene in the blank injection 1 does not exceed 0.5% of 10 times the peak area of the propylparabene peak in the chromatogram obtained with the reference solution (b) injected after the blank injection.
The percentage of the peak area corresponding to propylparabene in the reference solution (c) is 0.9 - 1.1% of the peak area of the propylparabene peak in the chromatogram obtained with the reference solution (b) injected after the blank injection.
HPLC AUTOSAMPLER
Thermostatting accuracy and precision can be tested in the frame of the periodic and motivated check of the HPLC Autosampler.
THERMOSTATTING ACCURACY
Materials:
Calibrated temperature probe.
Method:
Select a temperature along the operational or required temperature range of the equipment. Wait until the system is equilibrated.
By means of the calibrated probe, measure the actual temperature in the autosampler and compare it to the selected temperature.
Repeat the same procedure at different pre-selected points covering the temperature range. Limits:
The actual temperature may not differ more than ± 3°C with respect to the selected temperature.
THERMOSTATTING PRECISION
Materials:
Calibrated temperature probe.
Method:
Select a temperature along the operational or required temperature range of the equipment. Wait until the system is equilibrated.
By means of the calibrated probe, make “n” measurements over a pre-established period of time. Compare the mean of the “n” measurements to the selected temperature.
Limits:
The actual temperature may not temperature.

HPLC OVEN/COOLING DEVICE
Thermostatting accuracy is the parameter tested in this example of periodic and motivated check of the HPLC oven/cooling device.
THERMOSTATTING ACCURACY
Materials:
Calibrated thermometer.
Method:
Set the column oven temperature to 40 °C, wait about 30 minutes to equilibrate the system, put a calibrated thermometer into the oven and read the temperature after 10 minutes.
Limits: 38 - 42°C.
HPLC UV/DAD DETECTOR
The periodic and motivated check of the HPLC UV/DAD detector can be performed by testing the linearity and the wavelength accuracy.
LINEARITY
Solutions:
Std. 1: 0.5 |ag caffeine/1 ml methanol HPLC Grade Std. 2: 1.0 |ag caffeine/1 ml methanol HPLC Grade Std. 3: 5.0 |ag caffeine/1 ml methanol HPLC Grade Std. 4: 25.0 |ag caffeine/1 ml methanol HPLC Grade Std. 5: 50.0 |ag caffeine/1 ml methanol HPLC Grade Std. 6: methanol HPLC Grade (blank)
Std. 5: weigh 9.0 to 11.0 mg caffeine and fill up to 200.0 ml with methanol HPLC
Std. 4: dilute 50.0 ml of Std. 5 to 100.0 ml with methanol
Std. 3: dilute 10.0 ml of Std. 5 to 100.0 ml with methanol
Std. 2: dilute 20.0 ml of Std. 3 to 100.0 ml with methanol
Std. 1: dilute 10.0 ml of Std. 3 to 100.0 ml with methanol
Settings:
Column: RP-18 5 jam 30-50 x 2,1-4.6 mm or capillary 2000 mm x 0.12 mm ID Mobile phase: methanol HPLC Grade Oven temperature: 40 °C
Flow rate: 1.0 ml/min (adjusted by using 100% methanol)
Detection: 273 nm Injection volume: 20 |al
Method:
Injection scheme:
2 x        blank
1 x        Std.        1
1 x        Std.        2
1 x        Std.        3
1 x        Std.        4
1 x        Std.        5

Limits: r2 > 0.999
Remark: As this test employs different test solutions to be injected, it covers also the check of correct positioning vials in the autosampler.
WAVELENGTH ACCURACY
If there are built-in test procedures for the determination and adjustment of wavelength accuracy, follow the instructions of the instrument manual.
In all other cases use the procedure described below.
Solutions:
DAD: caffeine Std. 5 from the linearity testing UV/VIS: 1.0 |ag/ml anthracene solution in water
Settings:
Mobile phase: 15% acetonitrile in water
Column: RP18, 5 jam 30-50 x 2,1-4.6 mm or capillary 2.0 m x 0.12 mm ID Oven temperature: 40 °C
Flow rate: 1.0 ml/min (adjusted by using 15% acetonitrile in water)
Detection: scan from 230 nm to 290 nm (DAD)
Injection volume: 20 |al
Method:
DAD: Inject 20 |al of the caffeine solution and record the spectrum. The maximum is at 272 nm and the minimum at 244 nm.
UV/VIS: fill the cell with the anthracene solution and change the wavelength from 248 to 254 nm in 1 nm steps; record the maximum of absorption. The theoretical value is 251 nm.
Limits: 土 2 nm
HPLC FLUORESCENCE DETECTOR
The following three parameters are proposed for the performance of the periodic and motivated check of the HPLC fluorescent detector:
WAVELENGTH ACCURACY EXCITATION
Method:
Rinse and fill the measuring cell with de-ionized water Adjust the excitation wavelength to 350 nm.
Measure the emission and subtract 397 nm (theoretical value).
Limits: 土 3 nm
WAVELENGTH ACCURACY EMISSION
Method:
Rinse and fill the measuring cell with de-ionized water Adjust the emission wavelength to 397 nm.
Measure the excitation and subtract 350 nm (theoretical value).
Limits: 土 3 nm
SENSITIVITY
Solutions:
Quinine HCL2H2O solution conc. 0.015 ag/ml (=15 ppb)
The quinine solution is prepared with the following mobile phase: dissolve 6.8 g of potassium dihydrogen phosphate R and 3.0 g of hexylamine R in 700 ml of water R, adjust to pH 2.8 with dilute phosphoric acid R, add 90 ml of acetonitrile R and dilute to 1000.0 ml with water R.
Settings:
The chromatographic conditions are set according to Ph. Eur. “Quinine HCl” (01/2005:0018), test “Other cinchona alkaloids”，with modified flow rate and acetonitrile concentration.
Mobile phase: as above Column: RP18, 5 |am, 250 x 4.6 mm Flow rate: 1,2 ml/min Excitation wavelength: 350 nm Emission wavelength: 397 nm
Flow-cell volume: 8 |al (for this example, a Waters 2475 MultiFluorescentiedetector was used. Flow-cell volume may vary depending on the instrument manufacturer)
Method:
Inject 10 |al of the quinine solution and measure the peak height.
Inject 10 |al of the blank and measure the peak height of the noise.
Divide the peak height of the quinine solution by 3 times the peak height of the noise.
Divide the concentration of the quinine solution by the previously obtained factor.
Limits: < 0.5 ppb
HPLC ELECTROCHEMICAL DETECTOR
Accuracy and stability of the signal are the proposed parameters to be tested during the periodic and motivated check of the HPLC electrochemical detector.
ACCURACY AND STABILITY OF THE SIGNAL
Settings:
Cell potential of a dummy cell: 800 mV Rise time filter: 0.1 s Range: 0.1 nA Temperature: 30 °C
Method:
Accuracy: Measure the electric current and subtract 2.67 nA (theoretical value)
Stability: Measure the noise over a period of 5 minutes
Limits:
Accuracy (cell current): 土 0.05 nA
Stability of the signal (Noise): max. 2 pA or 20 mV
HPLC RID DETECTOR
Signal to Noise ratio and drift over time are the parameters proposed for the periodic and motivated check of the HPLC RID (refractive index) detector.
SIGNAL TO NOISE RATIO
Solutions:
Standard solution: D-fructose concentrate solution at 4.0 mg/ml (dilute 200.0 mg fructose + 20 ml water + 25.0 ml acetonitrile up to 50.0 ml with water for HPLC)
Settings:
Column: spherisorb NH2 (or equivalent) 250 x 4.6 mm or other Oven temperature: 38°C Flow rate: 1.0 ml/min Injection volume: 20 |al
Mobile phase: 0.253g sodium hydrogen phosphate R in 220 ml + 780 ml acetonitrile
Method:
After equilibration, inject three times a blank solution of mobile phase over a run time where the system is stable. Measure the baseline noise over an appropriate period.
The baseline noise is accepted if the mean height of the three replicates is < 1000 |aV.
To calculate the signal to noise ratio, inject three times a solution of fructose at 0.4 mg/ml and calculate the mean of the three replicates.
Limits: S/N > 10
DRIFT OVER A DEFINED PERIOD OF TIME
Method:
Calculate the slope of the amplitude of random variations in the detector’s signal over 1 minute.
Limits: 土 0.1 mV/min
Alternatively, the requirement may be expressed in ARI/min or in % of full scale of the selected range.
HPLC CD DETECTOR
The following tests are proposed to perform the periodic and motivated check of the HPLC CD (circular dichroism) detector.
LINEARITY AND SIGNAL TO NOISE RATIO
dissolve 25.0 mg D(-) pantolactone in 50.0 ml water dilute 2.0 ml of reference solution (a) to 10.0 ml with water dilute 4.0 ml of reference solution (a) to 10.0 ml with water dilute 6.0 ml of reference solution (a) to 10.0 ml with water dilute 8.0 ml of reference solution (a) to 10.0 ml with water dilute 0.5 ml of reference solution (b) to 25.0 ml with water
Settings:
Column: C18, 150 x 4 mm, 5 |am
Mobile phase: acetonitrile : water = 10 : 90
Flow: 1.0 ml/min
Detection: 225 nm
Injection volume: 20 |al
Method:
Check the linearity of de CD- and UV-signal of D(-)pantolactone reference solution a,b,c,d,e. Measure the noise of the CD-signal of reference solution (f) between 0 - 10 min.
-        Calculate the absolute concentration (ag) in the cell
-        Calculate the signal-to-noise ratio (S/N) for 0.01 ag in the cell
-        Calculate the sensitivity with the calculated S/N and the specified S/N= 2 (0.01 x 2/ S/N calculated)
Limits:
Linearity: The linearity of the calibration line obtained with reference solution (a,b,c,d,e) should be r
> 0.999.
Sensitivity: The sensitivity at S/N= 2 should be better than 0.01 ag.
S/N ratio: The limit for S/N is > 1.0 and the sensitivity should be 0.020 ag at maximum.

DRIFT OVER A DEFINED PERIOD OF TIME
Settings:
Column: C18, 150 x 4 mm, 5am
Mobile phase: acetonitrile : water = 10 : 90
Flow: 1.0 ml/min
Detection: 290 nm
Injection volume: 20 |al
Method:
Inject water and stop the flow after 5 minutes. Measure the CD-signal for 1 hour. Measure with the cursor the drift of the baseline between 5 and 65 min.
Limits:
Not more than 0.1 mdeg/h SPECTRA COMPARISON
Solutions:
Reference solution (a): dissolve 5.0 mg dexamethasone in 10.0 ml 40% acetonitrile
Settings:
Column: C18, 150 x 4 mm, 5am
Mobile phase: acetonitrile : water = 40 : 60
Flow: 1.0 ml/min
Detection: 230 nm
Injection volume: 20 |al
Method:
Compare the maxima/minima obtained at the Installation of the detector (see table).
CD max        CD min        UV max
222 nm        224 nm        236 nm
230 nm        252 nm       
284 nm               

Limits:
The maxima and minima may not differ more than 土 4 nm.

sakura416

usp621中有同样的内容
不过一般按厂家给的技术标准而定

毒手药王邓智先

尼龙/电话/ omcl（11）04@piao0923    谁 有时间校对一下

附件1：资质资格的高效液相色谱设备

完整的文档和参考设备的资格

附件1：资格的高效液相色谱设备

尼龙/电话/ omcl（11）04

文档类型指南

立法依据本文件也被接受的建议文件的使用范围内的质量管理体系的审核omcls

首次执行日2005

原生效日期六月2005

生效的修订文件第一七月2011

以前的标题/其他参考本文件替换文件尼龙/电话/ omcl（07）17号

托管人

组织本文件阐述的omcl网络/ ED QM的欧洲理事会

有关网络建

附件1的omcl网络指南”资格的设备”

资格的高效液相色谱设备

景区简介

本文件是第一个附件的核心文件”设备的资格”，而应该结合使用它在规划，执行和记录设备的高效液相色谱法鉴定过程。

核心文件包含的一般介绍和一级和二级资质，共同所有类型的仪器，和本附件包括高效液相色谱仪器相关建议的参数进行检查和相应的典型的接受范围，以及实际的例子的方法，可以用来进行这些检查。

高效液相色谱设备时，应指出的是，可接受的检查在第三和第四级的几个参数，同时在联合测试程序（例如“整体”系统的性能测试提供信息的峰面积的精度，保留时间精度，梯度重现，等）。



表三

三级。周期性和动机的仪器检查的例子，要求的高效液相色谱仪器和检测器

仪器模块的参数进行检查的典型性

限制

溶剂输送系统&#8226;流量

&#8226;配料准确度和精密度（梯度）

&#8226;配料纹波&#8226;土5%

&#8226;土2

&#8226;< 0.2 %

喷油器&#8226;量精度

&#8226;遗留&#8226;相对标准偏差< 1%

&#8226;见附件

自动&#8226;色谱峰的准确度和精密度&#8226;土3°丙

烤箱或冷却装置&#8226;恒温精度&#8226;土2°丙

紫外检测器&#8226;线性

&#8226;波长精度&#8226;r 2 > 0.999

&#8226;土2海里

荧光检测器激发波长精度&#8226;

&#8226;发射波长精度

&#8226;敏感性&#8226;土3海里

&#8226;土3海里

&#8226;见附件

电化学检测器&#8226;信号精度

&#8226;稳定的信号&#8226;见附件

&#8226;见附件

&#8226;摆脱探测器的信号/噪声比

&#8226;漂移随着时间的&#8226;见附件

&#8226;土0.1毫伏/分钟

&#8226;镉探测器的信号/噪声比

&#8226;灵敏度

&#8226;漂移随着时间的

&#8226;线性&#8226;见附件

&#8226;见附件

&#8226;见附件

&#8226;大于0.999

表四

四级。使用仪器

例子要求高效液相色谱仪器紫外或爸爸探测器

参数是典型的容忍限度检查

&#8226;系统适用性检查的方法根据pH值。欧元。或马来酸酐档案或验证内部方法

&#8226;峰面积的精度（主要适用于在测试解决方案）相对标准偏差< 1.5%

（除非另有规定的系统适用性的方法，例如具体要求欧元从pH值。2.2.46，原料药的专著或马档案）

&#8226;保留时间精度为5%±

&#8226;结转（通过比较标准（连续的物质被量化）和空白注射）< 0.2%

&#8226;信噪比（用于有关物质检测）根据pH值。欧元。



我的附件

三级。周期性和动机的仪器

该附件包含实际的例子，测试和相关的容忍限度的几个相关参数性能的不同模块的高效液相色谱。

这些例子可以被认为是由omcls作为可能的办法来执行第三级别的设备鉴定过程：“周期和动机的仪器检查”。

高效液相色谱溶剂输送系统

以下试验提出了周期性和积极的检查的高效液相色谱溶剂输送系统：流量和梯度试验。

流动率

材料：

5或10毫升容量瓶中校准计时器

设置：

流动相脱气水无柱（开口）*

流量：调整0.5至3毫升/分钟

如果高压混合系统的安装，测试了各溶剂通道。

*某些设备，例如在低流量，检查将进行通过使用一列或背压调节器。

方法：

设定流量在一个适当的水平和测量的时间来填补瓶到标记。记录所需的时间。

五* 60

第五/ 1 = =

1

F .流量测量[毫升/分钟]

不经过时间填充到标记[的]

五卷的容量瓶[ m ]

100-f-f =

女

四偏差[ % ]

为调整流量[毫升/分钟]

F .流量测量[毫升/分钟]

土限制：5%

梯度组成和纹波

设置：

不锈钢毛细管，例如2000×0.12毫米安装而不是一列：紫外检测器检测调整到265纳米相：脱气水

乙：流动相脱气水含0.5%丙酮流量：1毫升/分钟

方法：

测试是进行以下方式使用梯度程序取决于一些溶剂渠道和系统配置：

B

公司和交流交流，B和D

时间[至少] %相（水）%移动相（水丙酮混合物）

0 100 0

0.1 90 10

10 90 10

10.1 50 50

20 50 50

20.1 10 90

30 10 90

30.1 0 100

40 0 100

40.1 100 0

开始测试水抽至少10分钟，以平衡系统。

零%开始测试基准。所有步骤测量开始时的水平线的部分，可以通过软件或手动上纸印刷用内衬。高度的100% /丙酮混合物作为100%个值的计算。

小时

% = 100 *小时小时

%小时计算的组成

有高度的测量线

有高度的100% /丙酮混合物线（流动相）

四= %小时-克

四偏差

克梯度组成的调整[ %丙酮/水溶液混合流动相A ]

限制：

绝对偏差：土2调整值

纹波的梯度噪声成分的百分比的50%线从梯度程序。

氮

% = 100 * 1

h50

%的涟漪

h5q高度的50%行

2高度噪音线，测量在1分钟在线性区

限制：0.2%

高效液相色谱注射器

体积精密和结转的测试提出了周期性和积极的检查的高效液相色谱注射器。

体积精密和结转

解决方案：

溶剂：甲醇：水，60 : 40。

参考解决方案（一）：溶解15毫克甲基，乙基，和propylparabene在100毫升的溶剂A

参考溶液（乙）：稀1毫升的参考解决方案（一）至10毫升的溶剂的溶液（三）：稀1毫升的参考解决方案，（二）100毫升的溶剂A

设置：

专栏：lichrospher 100 rp8果酱，5，125×4毫米，无前

流动相：甲醇：水= 60 : 40

流量：1毫升/分钟

检测：254纳米

注射量：20 |铝

方法：

注射计划：

- 6参考解决方案（二）

- 1参考解决方案（一）

- 1溶剂（空白注1）

- 1参考解决方案（二）

- 1溶剂（空白注2）

- 1参考解决方案（丙）



可重复性的峰面积的相对标准偏差：峰面积的所有峰的色谱与对照溶液（乙）应< 1%。

结转：百分比的峰面积相对应的空白1 propylparabene注射不超过0.5%的10倍，峰面积的propylparabene峰在色谱与对照溶液（乙）注射后，注射的空白。

百分比的峰面积相对应propylparabene的参考解决方案（丙）是0.9 - 1.1%的峰面积的propylparabene峰在色谱与对照溶液（乙）注射后，注射的空白。

高效液相色谱自动进样器

色谱峰的准确度和精密度可以测试的框架内的周期性和积极的检查的高效液相色谱自动进样器。

恒温精度

材料：

校准温度探头。

方法：

选择一个温度沿运行或需要的温度范围内的设备。等到系统平衡。

利用校准探头，测量温度的实际的自动和比较它的温度选择。

重复同样的程序在不同的预先选定的点覆盖的温度范围。限制：

实际温度不得超过3摄氏°不同±就选定的温度。

恒温精度

材料：

校准温度探头。

方法：

选择一个温度沿运行或需要的温度范围内的设备。等到系统平衡。

利用校准探头，使”测量一个预先确定的时间内。比较平均的”到选定的温度测量。

限制：

实际温度可能不是温度。

高效液相色谱/冷却装置

恒温精度参数测试在这个例子中的周期和动机的检查的高效液相色谱/冷却装置。

恒温精度

材料：

校准温度计。

方法：

设置列烤箱温度至40摄氏°，等30分钟左右平衡的系统，把校准温度计放入烤箱的温度读10分钟后。

范围：38 - 42°C

高效液相色谱紫外检测器

定期主动检查的高效液相色谱紫外检测器可以进行测试的线性和波长精度。

线性的

解决方案：

标准1：0.5 |银咖啡因/ 1毫升甲醇分级标准2：1 |银咖啡因/ 1毫升甲醇分级标准3：5 |银咖啡因/ 1毫升甲醇分级标准4：25 |银咖啡因/ 1毫升甲醇分级标准5：50 |银咖啡因/ 1毫升甲醇等级6：甲醇级（空白）

标准5：重9至11毫克的咖啡因和填补高达200毫升的甲醇含量

标准4：稀50毫升5至100毫升的甲醇

标准3：稀10毫升5至100毫升的甲醇

标准2：稀20毫升3至100毫升的甲醇

标准1：稀10毫升3至100毫升的甲醇



设置：

流动相：15%乙腈水

专栏：rp18果酱，5 -×2,1-4.6毫米或2米×0.12毫米编号烤箱温度：40摄氏°

流量：1毫升/分钟（调整使用15%乙腈水）

检测：扫描从230纳米到290纳米（爸爸）

注射量：20 |铝

方法：

爸爸：注射20 |铝的咖啡因溶液和记录的频谱。最大是在272纳米和244纳米的最小。

紫外/可见：填补细胞与蒽溶液和改变波长从248到254纳米，1纳米的步骤；记录最大吸收。理论值是251纳米。

限制：土2海里

高效液相色谱荧光检测仪

以下三个参数提出了性能的周期性和积极的检查的高效液相色谱荧光检测器：

激发波长精度

方法：

冲洗和填充测量细胞与去离子水调整激发波长350纳米。

衡量的排放和减去397纳米（理论值）。

限制：土3海里

发射波长精度

方法：

冲洗和填充测量细胞与去离子水调整发射波长397纳米。

测量励磁和减去350纳米（理论值）。

限制：土3海里

灵敏度

解决方案：

奎宁hcl2h2o溶液浓度。0.015银/毫升（= 15十亿分之）

奎宁溶液的制备与以下流动相溶解6.8克磷酸二氢钾和3克的己胺在700毫升水，调整PH值为2.8的稀磷酸，加入90毫升乙腈溶解并稀释至1000毫升水河

设置：

色谱条件是根据pH值。欧元。“盐酸奎宁”（01 / 2005:0018），测试”其他金鸡纳生物碱”，改性流量和乙腈浓度。

流动相：如上柱：rp18，|是5，250×4.6毫米，流量：1 , 2毫升/分钟激发波长：350纳米波长：397纳米

流动细胞体积：8 |铝（在这个例子中，一个2475 multifluorescentiedetector使用。流动细胞体积可能取决于仪器制造商）

方法：

注10 |铝的奎宁溶液和峰值测量的高度。

注10 |基地的空白和峰值测量的高度噪音。

分峰高的奎宁溶液3倍的峰值高度噪音。

分浓度的奎宁溶液由先前获得的因素。

限制：< 0.5浓度

高效液相色谱电化学检测器

准确性和稳定性提出的信号参数进行测试期间的定期检查和动机的高效液相色谱电化学检测器。

精度和稳定性的信号

设置：

细胞的潜力，一个虚拟细胞：800压上升时间：0.1：0.1：30°摄氏温度

方法：

精度：测量电流和减去2.67（理论值）

稳定性：测量噪声在5分钟的时间

限制：

精度（电流）：土0.05钠

稳定的信号（噪音）：最大2或20

高效液相色谱法消除探测器

信号噪声比和漂移随着时间的参数提出的定期检查和动机的高效液相色谱摆脱（折射率）检测器。

信号噪声比

解决方案：

标准溶液：果糖浓缩溶液在4毫克/毫升（稀200毫克果糖+ 20毫升水+ 25毫升乙腈高达50毫升水的高效液相色谱法）



设置：

专栏：spherisorb氨基（或同等学历）250×4.6毫米或其他烤箱温度：38摄氏°流量：1毫升/分钟注射量：20 |铝

流动相：0.253g磷酸氢钠在220毫升+ 780毫升乙腈

方法：

平衡后，注射三次空白溶液流动相在运行时，系统是稳定的。测量基线噪声在适当的时期。

基线噪音被接受如果平均身高的三复制是< 1000 |影音。

计算信号的信噪比，注入三倍溶液果糖在0.4毫克/毫升和计算平均值的三复制。

限制：信噪比> 10

漂移超过规定的时间内

方法：

计算边坡的振幅随机变化的检测器的信号超过1分钟。

限制：土0.1毫伏/分钟

另外，可以要求表达在急性呼吸道感染/分钟或%全尺寸的选择范围。

高效液相色谱镉探测器

以下测试的建议进行定期检查和动机的高效液相色谱光盘（圆二色）检测器。

线性和信号噪声比

溶解25毫克数（-）泛内酯在50毫升水稀释2毫升的参考解决方案（一）至10毫升水稀释4毫升的参考解决方案（一）至10毫升水稀释6毫升的参考解决方案（一）至10毫升水稀释8毫升的参考解决方案（一）至10毫升水稀释0.5毫升的参考解决方案（二）至25毫升的水

设置：

：18柱，150×4毫米，5 |是

流动相：乙腈：水= 10 : 90

流量：1毫升/分钟

检测：225纳米

注射量：20 |铝

方法：

检查线性的德光盘和uv-signal的（-）泛内酯参考溶液，乙，丙，丁，即测量噪声的cd-signal参考溶液（女）在0 - 10分钟。

计算绝对浓度（银）的细胞

计算的信号噪声比（信噪比）为0.01银的细胞

计算灵敏度的计算信噪比和指定的信噪比= 2（0.01×2 /信噪计算）

限制：

线性度：线性的校准曲线得到参考的解决方案（甲，乙，丙，丁，戊）应该是

0.999。

灵敏度：灵敏度的2例应大于0.01银。

信噪比：极限信噪比> 1，灵敏度为0.020银最大。

漂移超过规定的时间内

设置：

：18柱，150×4毫米，5

流动相：乙腈：水= 10 : 90

流量：1毫升/分钟

检测：290纳米

注射量：20 |铝

方法：

注入水和停止流通后5分钟。测量cd-signal 1小时。测量与光标的漂移的基准之间的5和65分钟。

限制：

不超过0.1 mdeg /小时谱比较

解决方案：

参考解决方案（一）：溶解5毫克地塞米松10毫升40%乙腈

设置：

：18柱，150×4毫米，5

流动相：乙腈：水= 40 : 60

流量：1毫升/分钟

检测：230纳米

注射量：20 |铝

方法：

比较极大/极小获得安装探测器（见下表）。

光盘光盘分钟最大紫外最大

222纳米的224纳米，236纳米

230纳米，252纳米

284纳米

限制：

最大值和最小值不超过4纳米。

syhorchid

谢谢楼主分享

豚鼠

楼上什么软件翻译的？  比原文还难懂

制药设备

药王是典型的中国式的英语吗？不过我不懂

jszy

谢谢两位，辛苦了

海子

流汗

孙艳红

谢谢分享

毒手药王邓智先

海子 发表于 2012-12-10 23:51
流汗

海子翻译下

bigdogpolice

估计是GOOGLE翻译的

llb1978

EDQM是COE（欧洲理事会）下设的机构，并非欧盟的，概念要搞搞清楚呀

zhiqiang2003

{:soso_e114:}

华丽

期待好一点的翻译版

情非得已

ZHICHILOUZHU 支持楼主

野性之吻

英文 看不懂啊   

chenqiushiba

谢谢，收藏了。

qdyush

这个就怕做起来难度很大

海笑/mg/mg

感谢分享，多谢了，楼主