A method for detecting the monosaccharide and oligosaccharide content and fingerprint spectrum of a compound Sophora flavescens injection, comprising: carrying out detection by using a high-performance liquid chromatography-evaporation light scattering detection method, wherein the monosaccharides and oligosaccharides are D-anhydrous glucose, D-fructose, sucrose and pinitol. The present method is an improved method for detecting monosaccharides and oligosaccharides of a compound Sophora flavescens injection, and can measure four saccharide components in the compound Sophora flavescens injection at the same time, and constructs an HPLC-ELSD fingerprint spectrum to provide a technical method for the quality control of the saccharide components in the compound Sophora flavescens injection.

A mass spectrum generation section (22) generates an original mass spectrum at a peak of a target compound based on data acquired through analysis on a sample. A background spectrum generation section (23) generates a background spectrum in accordance with each of a plurality of predetermined background acquisition conditions. A difference mass spectrum calculation section (25) obtains a difference mass spectrum by subtracting the each background spectrum from the original mass spectrum, and a spectrum similarity calculation section (27) calculates a similarity between each difference mass spectrum and a standard mass spectrum of a candidate compound selected from a spectrum library (28). A compound identification section (29) identifies the candidate compound as the target compound if the highest similarity exceeds a predetermined threshold.

Methods and systems to monitor and analysis unconventional reservoirs with wellbores with a substantially horizontal section. Monitoring and analysis is conducted in three dimensions using high-resolution geochemical fingerprinting analyses of rock samples and produced oil samples. The invention uses methods to preserve, prepare, extract, and/or analyze hydrocarbons in the pore spaces of or adsorbed in organic-rich rock samples, such as, but not limited to, drill cuttings and drill cores, using one or more combinations of physical energy sources, including, but not limited to, thermal, vapor pressure, and mechanical stress. The collected samples are transported and prepared in low temperature conditions, with parts of subsequent processing at very low temperatures, thereby allowing a fuller measurement of geochemical fingerprints for the extracted hydrocarbons using various analysis tools. More particularly, the treatment and process allows geochemical fingerprinting to very low carbon number ranges. The techniques of the present invention may be used to optimize well stacking and spacing, completion design, and cluster efficiency evaluation to improve unconventional reservoir economics.

Provided are a method of and an apparatus for formulating a multicomponent drug capable of surely making a multicomponent drug meeting criteria for productization with high accuracy into a product. The method and apparatus obtain a chromatogram from an extract or a base of a multicomponent drug, evaluate whether the base meets the criteria for productization based on the obtained chromatogram with high accuracy, and subject the base determined in the high-accuracy evaluating as an accepted one meeting the criteria to dosage form processing, to produce a formulated drug having a given dosage-form. The high-accuracy evaluating is realized by selecting with high accuracy one of reference fingerprints to which peaks of a target fingerprint prepared from the chromatogram are assigned.

The present technology relates to a method and instrument for classifying a sample. The method collects raw data from an analytical instrument (e.g., LC-MS), quantifies consistency parameters from the raw chromatographic data (e.g., peak detection) by assigning criteria and determining probability ratios, and constructs a learning model quantitation step by weighing the presence, absence, or modulation of one or more factors of the one or more samples against a decision criterion for positivity. The method can then apply the learning model to an unknown sample to detect the presence, absence, or modulation of one or more factors in the unknown sample such as the presence, absence, or modulation of a disease state or multiple disease states.

A method for detecting the content of active ingredients of a compound Sophorae flavescentis radix injection and the fingerprint spectrum thereof. The method comprises using high performance liquid chromatography to perform detection, wherein the high performance liquid chromatography is operated under the condition of a C18 chromatographic column, and active ingredients comprise matrine, oxymatrine, macrozamin, sophocarpine, oxysophocarpine, sophoridine, or/and piscidic acid. The present method is an improved method for performing detection on a compound Sophorae flavescentis radix injection, by means of same, seven ingredients in the compound Sophorae flavescentis radix injection can be simultaneously determined, and a chromatographic fingerprint spectrum can be constructed, thereby providing a technical method for quality control of a compound Sophorae flavescentis radix injection.

The present invention relates to a method for controlling a bioprocess purification system comprising a continuous chromatography configured to operate with at least three columns and configured for cyclic operation, wherein the continuous purification is performed on a sample comprising a target product having desired characteristics. The method comprises detecting (82) at least one parameter indicative of characteristics of the target product, performing (83) real time trend analysis of each detected at least one parameter to identify a deviation from the desired characteristics of the target product, and controlling (84) the bioprocess purification system to meet the desired characteristics based on the identified deviation, whereby the target characteristics is within a pre-determined range.

A fingerprint spectrum construction method for Xihuang capsules and a fingerprint spectrum includes: S1: taking contents of a Xihuang capsule, adding a methanol-chloroform-phosphoric acid solution, and carrying out ultrasonic extraction to obtain a Xihuang capsule test solution; S2: dissolving cholic acid, hyodeoxycholic acid, deoxycholic acid, bilirubin, muscone, and myrrhone in ethanol to obtain a mixed standard solution 1; dissolving quassin, 11-carbonyl-?-boswellic acid, 11-carbonyl-?-acetyl-boswellic acid, acetyl-11?-methoxy-?-boswellic acid, and sandaracopimaric acid in methanol to obtain a mixed standard solution 2; S3: respectively carrying out chromatography on the Xihuang capsule test solution and the mixed standard solutions 1 and 2, and recording corresponding chromatograms; and S4: constructing a fingerprint spectrum of the Xihuang capsule according to the chromatogram of the Xihuang capsule test solution and the chromatograms of the mixed standard solutions 1 and 2. The method can accurately, clearly and objectively evaluate the quality of Xihuang capsules.

A fingerprint spectrum construction method for a new compound aloe capsule and a fingerprint spectrum includes: (1) taking powder of a new compound aloe capsule, carrying out reflux extraction, adding methanol, carrying out ultrasonic treatment, filtering, and taking a subsequent filtrate as a test solution; dissolving barbaloin, aloe-emodin, indirubin, tryptanthrin, aloesin, and ?-sitosterol in methanol to obtain reference solutions; (2) injecting the test solution and the reference solutions into a high performance liquid chromatograph for gradient elution to obtain a chromatogram of the new compound aloe capsule and chromatograms of the reference solutions, respectively; and (3) labeling chemical components of peaks on the chromatogram of the new compound aloe capsule according to the chromatogram of the new compound aloe capsule and the chromatograms of the reference solutions to obtain a fingerprint spectrum of the new compound aloe capsule.

Each of one or more unknown compounds are separated from a sample over a separation time period. Separated compounds are ionized, producing one or more compound precursor ions for each of the unknown compounds and a plurality of background precursor ions. A precursor ion mass spectrum is measured for the combined compound and background precursor ions at each time step of a plurality of time steps spread across the separation time period, producing a plurality of precursor ion mass spectra. One or more background precursor ions are selected from the plurality of precursor ion mass spectra that have a resolving power in a range below a threshold expected resolving power. A separation time is detected for an unknown compound when a decrease in an intensity measurement of the selected background precursor ions over a time period exceeds a threshold decrease in intensity with respect to time.