Purity test of Epirubicin Hydrochloride
Applications | | GL SciencesInstrumentation
Residual solvent analysis in pharmaceutical compounds ensures drug safety by detecting organic impurities that may harm patients.
The goal was to evaluate residual solvents in epirubicin hydrochloride using Japanese Pharmacopoeia guidelines.
The analytes were separated by gas chromatography with flame ionization detection on an InertCap Pure-WAX capillary column (0.53 mm I.D. × 30 m, 1 μm). Temperature program: 40 °C (11 min), ramp 10 °C/min to 90 °C, ramp 50 °C/min to 130 °C (30 min). Carrier gas: helium at 20 kPa. Injection: split 1:15 at 120 °C.
Used Instrumentation:
All solvents were baseline resolved with good peak shape and inertness. The resolution between the first analyte and internal standard exceeded the JP15 requirement (R > 30). Calibration levels ranged from 0.0068 to 1.25 μL/mL and produced linear responses.
Advances may include coupling to mass spectrometry for lower detection limits and broader solvent panels, automated sample preparation and green solvent methods to minimize environmental impact.
The study demonstrates a robust GC-FID method using an inert capillary column to quantify residual solvents in epirubicin hydrochloride meeting Japanese Pharmacopoeia requirements, offering a reliable tool for pharmaceutical quality control.
No external references were provided in the source document.
GC, GC columns, Consumables
IndustriesPharma & Biopharma
ManufacturerGL Sciences
Summary
Significance of the topic
Residual solvent analysis in pharmaceutical compounds ensures drug safety by detecting organic impurities that may harm patients.
Objectives and overview of the study
The goal was to evaluate residual solvents in epirubicin hydrochloride using Japanese Pharmacopoeia guidelines.
- Quantification of acetone, methanol, ethanol, 1-propanol and 1,4-dioxane.
- Validation of chromatographic performance on a highly inert GC column.
Methodology and instrumentation
The analytes were separated by gas chromatography with flame ionization detection on an InertCap Pure-WAX capillary column (0.53 mm I.D. × 30 m, 1 μm). Temperature program: 40 °C (11 min), ramp 10 °C/min to 90 °C, ramp 50 °C/min to 130 °C (30 min). Carrier gas: helium at 20 kPa. Injection: split 1:15 at 120 °C.
Used Instrumentation:
- GC system with FID.
- InertCap Pure-WAX column, GL Sciences.
- Internal standard: 1,4-dioxane.
Main results and discussion
All solvents were baseline resolved with good peak shape and inertness. The resolution between the first analyte and internal standard exceeded the JP15 requirement (R > 30). Calibration levels ranged from 0.0068 to 1.25 μL/mL and produced linear responses.
Benefits and practical applications of the method
- Reliable detection of trace residual solvents according to pharmacopeial standards.
- High column inertness reducing active site interactions, improving sensitivity.
- Applicable to quality control in manufacturing of epirubicin hydrochloride and similar cytotoxic compounds.
Future trends and possibilities for use
Advances may include coupling to mass spectrometry for lower detection limits and broader solvent panels, automated sample preparation and green solvent methods to minimize environmental impact.
Conclusion
The study demonstrates a robust GC-FID method using an inert capillary column to quantify residual solvents in epirubicin hydrochloride meeting Japanese Pharmacopoeia requirements, offering a reliable tool for pharmaceutical quality control.
Reference
No external references were provided in the source document.
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
Similar PDF
Organic solvents
|GL Sciences|Applications
InertSearch for GC TM InertCap® Applications Organic solvents Data No. GA023-0850 14000 1 12000 10000 9 13 12 14 15 17 8000 6000 3 6 4 4000 11 2 78 10 166 5 19 18 2000 0 10 Acetic acid…
Key words
キシレン, キシレンacetate, acetatebutyl, butylalcohol, alcoholアニソール, アニソールテトラヒドロフラン, テトラヒドロフランヘプタン, ヘプタンethyl, ethylエチルベンゼン, エチルベンゼンアセトン, アセトンエタノール, エタノールanisole, anisoleacetic, aceticxylene, xyleneheptane
Residual solvents in pharmaceuticals
|GL Sciences|Applications
InertSearch for GC TM InertCap® Applications R id l solvents Residual l t in i pharmaceuticals h ti l Data No. GA123-0850 180000 160000 140000 66 64 56 120000 63 58+59 100000 Acetone 80000 60000 40000 20000 0 0 アセトン…
Key words
alcohol, alcoholbutyl, butylmethyl, methylether, etherketone, ketoneethyl, ethylacetate, acetatepropyl, propylisopropyl, isopropylcellosolve, cellosolveacetic, aceticキシレン, キシレンester, esterisobutyl, isobutylacid
Organic solvents
|GL Sciences|Applications
InertSearch for GC TM InertCap® Applications Organic Solvents Data No. GA202-0410 40000 22 12+13 GC GA202 TC-BOND Q Methanol メタノール Methanol Methyl alcohol メタノール メチルアルコール 67-56-1 GC GA202 TC-BOND Q Ethanol エタノール Ethanol Ethyl alcohol エタノール エチルアルコール 64-17-5 GC GA202…
Key words
ヘキサン, ヘキサンuvolt, uvoltinertsearch, inertsearchinertcap, inertcapsolvebts, solvebtsブタノール, ブタノールenviroment, enviromentエチルエーテル, エチルエーテルジエチルエーテル, ジエチルエーテルメチルプロピルアルコール, メチルプロピルアルコールglycol, glycoltert, tertイソプロピルアセテート, イソプロピルアセテートテトラヒドロフラン, テトラヒドロフランポーラスポリマー
Purity test of Colchicine
|GL Sciences|Applications
InertSearch for GC TM InertCap® Applications Purity test of Colchicine Data No. GA145-0644 I.S. 2 6.0 7.0 Time (min) 8.0 9.0 200000 1 I.S. 100000 2 0 0 2 4 6 8 10 Time ((min)) 12 14 16 Conditions :…
Key words
pharmacopoeia, pharmacopoeiapharmacopeia, pharmacopeiajapanese, japaneseコルヒチン, コルヒチンプロピルアルコール, プロピルアルコールトリクロロメタン, トリクロロメタンエチルアセテート, エチルアセテートクロロホルム, クロロホルムエチル, エチルjapan, japancolchicine, colchicineethyl, ethylガスクロマトグラフィー, ガスクロマトグラフィーイナートサーチ, イナートサーチイナートキャップ
