Solutions for Pharmaceutical Analysis - Application Notebook
Applications, Guides | 2018 | ShimadzuInstrumentation
In modern drug research, development and quality control, analytical methods must deliver high sensitivity, selectivity and throughput. From screening trace residual solvents and elemental impurities to profiling complex lipids, chiral compounds and polymorphic forms, pharmaceutical analysis underpins safety assessment, regulatory compliance and process optimization.
This compendium reviews a range of advanced analytical applications and system innovations for pharmaceutical laboratories: triple‐quadrupole LC–MS/MS for phospholipid profiling; software‐guided lipid identification (SimLipid); mass imaging of drug distribution in tissues (iMScope TRIO); high‐throughput UHPLC and SFC methods for USP/EP monographs; automated chiral separation by SFC (Nexera UC); online supercritical extraction–SFC for cleaning validation; preparative UFPLC for rapid compound isolation; DSC for polymorphism assessment; GC/HS and GC–MS workflows for residual solvent testing; ICP–AES for ICH Q3D elemental impurity assays; RID for excipient analysis, and software solutions (iFlagger, LabSolutions Report Plus) to ensure data integrity and streamline reporting.
Lipid MRM libraries enabled profiling of over 400 phospholipids and identification of fatty acid compositions in mouse tissue. SimLipid-guided analysis revealed significant phospholipid changes following treatment. MS imaging mapped amiodarone and its deethylated metabolite in rat lungs with 5 μm resolution. Simultaneous LC–MS/MS of kinase inhibitors in plasma achieved low-ng/mL quantitation. Modified USP and JP monographs were run 5 to 10× faster on UHPLC and SFC systems, meeting all system suitability criteria. Automated chiral screening on Nexera UC identified optimal CSP/modifier combinations for omeprazole. Chiral SFC–MS/MS quantified drug enantiomers in plasma at μg/L levels. UFPLC shortened preparative workflows from hours to 90 minutes, yielding high-purity targets. DSC distinguished polymorphic forms by unique melting and recrystallization events. Headspace GC and GC–MS splitting systems quickly tested for USP residual solvents, verifying S/N, resolution and repeatability. GC–MS workflows matched FID patterns via constant linear velocity control for reliable unknown identification. ICP–AES quantified 24 elemental impurities across dosage forms, satisfying PDE limits with spike-recovery and low detection limits. RID-20A provided robust analysis of mannitol and related sugar alcohols under USP conditions. iFlagger and Report Plus software automated data review and reporting, supporting traceability and regulatory compliance.
Emerging trends include expansion of UHPLC/SFC hybrid platforms, integration of ambient imaging techniques for in situ distribution studies, AI-driven data analytics for automated method development, and microflow/high-resolution MS for single-cell and spatial omics. Sustainable chromatography using supercritical fluids and low-argon ICP optics will further reduce environmental impact and operating costs.
The suite of advanced analytical technologies and software described here provides pharmaceutical scientists with powerful tools for rapid, sensitive, and compliant analysis across a broad range of applications, from early-stage drug discovery to final product quality control.
GC, GC/MSD, GC/MS/MS, HeadSpace, GC/SQ, GC/QQQ, Software, MS Imaging, HPLC, LC/MS, LC/MS/MS, LC/QQQ, GD/MP/ICP-AES
IndustriesPharma & Biopharma
ManufacturerShimadzu
Summary
Significance of Pharmaceutical Analysis Methods
In modern drug research, development and quality control, analytical methods must deliver high sensitivity, selectivity and throughput. From screening trace residual solvents and elemental impurities to profiling complex lipids, chiral compounds and polymorphic forms, pharmaceutical analysis underpins safety assessment, regulatory compliance and process optimization.
Objectives and Study Overview
This compendium reviews a range of advanced analytical applications and system innovations for pharmaceutical laboratories: triple‐quadrupole LC–MS/MS for phospholipid profiling; software‐guided lipid identification (SimLipid); mass imaging of drug distribution in tissues (iMScope TRIO); high‐throughput UHPLC and SFC methods for USP/EP monographs; automated chiral separation by SFC (Nexera UC); online supercritical extraction–SFC for cleaning validation; preparative UFPLC for rapid compound isolation; DSC for polymorphism assessment; GC/HS and GC–MS workflows for residual solvent testing; ICP–AES for ICH Q3D elemental impurity assays; RID for excipient analysis, and software solutions (iFlagger, LabSolutions Report Plus) to ensure data integrity and streamline reporting.
Methodology and Instrumentation
- Triple-quadrupole LC–MS/MS (Shimadzu LCMS-8050, LCMS-8060) with MRM libraries for lipid profiling
- LC–MS SimLipid database search for tissue phospholipid changes
- Mass spectrometry imaging (iMScope TRIO) to localize drug and metabolites in animal models
- UHPLC/SFC switching (Nexera UC, Prominence i, Nexera-i MT) for rapid pharmacopeial compliance
- Supercritical fluid chromatography (Nexera UC) and SFC–MS/MS for chiral and small-molecule analysis
- Online supercritical fluid extraction–SFC (Nexera-UC) for cleaning validation
- Preparative UFPLC (Prominence UFPLC) for fraction collection and purification
- Differential scanning calorimetry (DSC) for polymorph characterization
- Headspace GC (HS-20 + GC-2030) and GC–MS (QP2010 Ultra, QP2020) for residual solvent analysis; FID/MS splitting
- ICP–AES (ICPE-9820) for multi-element assay per ICH Q3D
- Refractive index detection (RID-20A) for excipient testing
- Workflow software (iFlagger, LabSolutions Report Plus) for automated data review, report generation and 21 CFR Part 11 compliance
Main Results and Discussion
Lipid MRM libraries enabled profiling of over 400 phospholipids and identification of fatty acid compositions in mouse tissue. SimLipid-guided analysis revealed significant phospholipid changes following treatment. MS imaging mapped amiodarone and its deethylated metabolite in rat lungs with 5 μm resolution. Simultaneous LC–MS/MS of kinase inhibitors in plasma achieved low-ng/mL quantitation. Modified USP and JP monographs were run 5 to 10× faster on UHPLC and SFC systems, meeting all system suitability criteria. Automated chiral screening on Nexera UC identified optimal CSP/modifier combinations for omeprazole. Chiral SFC–MS/MS quantified drug enantiomers in plasma at μg/L levels. UFPLC shortened preparative workflows from hours to 90 minutes, yielding high-purity targets. DSC distinguished polymorphic forms by unique melting and recrystallization events. Headspace GC and GC–MS splitting systems quickly tested for USP residual solvents, verifying S/N, resolution and repeatability. GC–MS workflows matched FID patterns via constant linear velocity control for reliable unknown identification. ICP–AES quantified 24 elemental impurities across dosage forms, satisfying PDE limits with spike-recovery and low detection limits. RID-20A provided robust analysis of mannitol and related sugar alcohols under USP conditions. iFlagger and Report Plus software automated data review and reporting, supporting traceability and regulatory compliance.
Benefits and Practical Applications
- High throughput and reduced solvent use for pharmacopeial methods
- Automated workflows and data integrity for QC and regulatory labs
- Enhanced sensitivity and selectivity for trace impurities and biomarkers
- Rapid method scouting for chiral and lipidomic analyses
- Integrated pretreatment and analysis for cleaning validation and sample isolation
- Comprehensive polymorph and elemental impurity testing under ICH guidelines
Future Trends and Opportunities
Emerging trends include expansion of UHPLC/SFC hybrid platforms, integration of ambient imaging techniques for in situ distribution studies, AI-driven data analytics for automated method development, and microflow/high-resolution MS for single-cell and spatial omics. Sustainable chromatography using supercritical fluids and low-argon ICP optics will further reduce environmental impact and operating costs.
Conclusion
The suite of advanced analytical technologies and software described here provides pharmaceutical scientists with powerful tools for rapid, sensitive, and compliant analysis across a broad range of applications, from early-stage drug discovery to final product quality control.
References
- ICH Q3D Guideline for Elemental Impurities
- USP <467>, JP Residual Solvents
- USP <621>, EP 2.2.46, JP <621> Chromatography
- US FDA 21 CFR Part 11 Guidance; ICH Q2(R1) Validation
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
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