Method development for improving lipid nanoparticle quantification on charge aerosol detector
Posters | 2026 | Waters | HPLC SymposiumInstrumentation
HPLC
IndustriesLipidomics
ManufacturerWaters
Summary
Importance of the topic
Lipid nanoparticles (LNPs) are a cornerstone delivery platform for mRNA therapeutics and vaccines. Accurate, robust quantification of individual lipid components in LNP formulations is critical for potency, stability, process control, and regulatory compliance. Universal, non-UV detectors such as the charged aerosol detector (CAD) have become attractive alternatives to UV-based detectors because several LNP components lack chromophores. This study addresses method development and data-processing strategies to improve CAD-based quantification of LNP lipids, with emphasis on linearization, weighting, chromatographic selectivity, and automation for regulated environments.Objectives and study overview
- Evaluate CAD suitability for quantitative analysis of a panel of LNP lipids (including ionizable lipid SM-102, cholesterol, DSPC, DMG-PEG 2000).
- Characterize detector response behavior (heteroscedasticity, non-linearity) and identify transformations/weighting to achieve reliable calibration across several orders of magnitude.
- Optimize chromatographic selectivity and peak shape to improve detection limits, especially for challenging components such as DMG-PEG.
- Implement a compliant-ready workflow using Empower CDS to automate calibration, processing, and reporting suitable for manufacturing QA/QC.
Methodology
- Standards: Lipids sourced from commercial suppliers; stock solutions prepared at 5 mg/mL in methanol and diluted in 90:10 water:methanol (v/v) for calibration series spanning ~4 orders of magnitude.
- Chromatography: Short reversed-phase phenyl-hexyl columns evaluated (ACQUITY Premier CSH Phenyl-Hexyl 1.7 µm, 130 Å; GTxResolve Lipid Phenyl-Hexyl+ RP 1.6 µm, 230 Å, 2.1 × 50 mm). Typical conditions: 3 µL injection, 0.400 mL/min flow, column temperature 50 °C, mobile phases with 0.1% formic acid (A: water, B: organic—ACN or MeOH/ACN blends) using tailored gradients for lipid separations.
- Detector and data acquisition: CAD detection with settings including 35 °C evaporation temperature, ion trap 20 V, sampling rate 10 Hz, and standard time constant. Response acquisition exploits CAD’s built-in power-law transformation (the p-term) to linearize response during acquisition where possible.
- Data treatment: Examined ELSD-like log–log post-acquisition linearization vs CAD power-function linearization. Addressed heteroscedastic residuals by applying appropriate weighting (notably 1/x2) during calibration fitting in Empower CDS to minimize residual sum of squares (RSS) and improve fit quality over a wide dynamic range.
Used instrumentation
- ACQUITY Premier U(H)PLC system with BSM (Waters) and Empower CDS 3.9.0 for acquisition and automated CAD workflows.
- Columns evaluated: ACQUITY Premier CSH Phenyl-Hexyl (1.7 µm, 130 Å) and GTxResolve Lipid Phenyl-Hexyl+ RP (1.6 µm, 230 Å, 2.1 × 50 mm).
- Charged aerosol detector (CAD) with specified settings: evaporation temperature 35 °C, ion trap 20 V, sampling 10 Hz, normal time constant. Nitrogen nebulization/gas flows as per CAD configuration.
Results and discussion
- Detector response characteristics: Both ELSD and CAD show intrinsically non-linear responses to analyte concentration. ELSD data are typically linearized by log–log (post-acquisition) transformation; CAD applies a power-function transform during acquisition (p-term) to linearize response but residual heteroscedasticity remains for some analytes.
- Heteroscedastic behavior and weighting: Raw CAD responses exhibited increasing variability with concentration (heteroscedastic residuals). Application of weighting during regression (e.g., 1/x2) substantially reduced RSS and produced residual distributions more consistent with homoscedastic assumptions, improving calibration performance and fit reliability (R2 values for lipids typically ≥0.998).
- Chromatographic improvements for DMG-PEG: Use of the GTxResolve Lipid Phenyl-Hexyl+ RP column markedly improved DMG-PEG peak performance—an 86% reduction in peak width and a fivefold increase in peak height relative to the initial CSH Phenyl-Hexyl column. This enhancement materially improved sensitivity and limit of detection for DMG-PEG, historically a challenging analyte for CAD quantification.
- Dynamic range and linearity: Calibrations covering approximately four orders of magnitude were achievable with the combined approach of optimized chromatography, CAD acquisition linearization (PFV/p-term), and appropriate regression weighting. Representative figures of merit showed R2 values ≈ 0.999 for SM-102, cholesterol and DSPC, and 0.998 for DMG-PEG after optimization.
- Automation and compliance: Implementing CAD workflows within Empower CDS allowed streamlined processing (application of power-function value, automated weighting, custom fields for component concentration and molar ratio), reporting, and reduced manual intervention—supporting deployment in regulated manufacturing laboratories.
Benefits and practical applications
- Robust quantification of LNP lipid components across a wide dynamic range supports potency and formulation control in mRNA therapeutic manufacturing.
- Improved chromatographic selectivity and peak shape for low-signal components (e.g., DMG-PEG) lower LOD and enable reliable monitoring of minor components and excipients.
- Use of CAD with appropriate acquisition linearization plus weighted calibration yields reproducible, high-quality quantitative data even in the absence of chromophores.
- Integration with compliance-ready CDS software enables high-throughput, auditable workflows suitable for regulated QC environments.
Future trends and potential applications
- Further refinement of CAD acquisition parameters and optimized particle-selection approaches could enhance sensitivity for very low-abundance lipid species and PEGylated excipients.
- Expansion of tailored stationary phases (e.g., specialized phenyl-hexyl chemistries and superficially porous particle designs) will continue to improve peak capacity and resolution for complex LNP mixtures.
- Standardized approaches for heteroscedastic data handling (automated weighting selection, robust regression) will facilitate method transfer and regulatory acceptance across laboratories and vendors.
- Coupling CAD quantification with orthogonal techniques (mass spectrometry for identity/confirmation, evaporative light scattering for cross-checking) could form a robust multipronged control strategy for advanced lipid therapeutics.
Conclusion
By combining chromatographic selectivity improvements, CAD acquisition linearization (power-function application), and statistically appropriate weighting during calibration, the study demonstrates reliable, wide-dynamic-range quantification of key LNP lipids. Notably, chromatographic optimization with a GTxResolve Lipid Phenyl-Hexyl+ column substantially improved DMG-PEG peak metrics and LOD. Implementing these strategies within Empower CDS produces a compliance-ready, automated workflow suitable for high-throughput regulated environments, advancing analytical control for LNP-based therapeutics.Reference
- Fekete S, Doneanu C, Addepalli B, et al. Challenges and emerging trends in liquid chromatography-based analyses of mRNA pharmaceuticals. Journal of Pharmaceutical and Biomedical Analysis. 2023;224:115174.
- Han D, Birdsall R, Simeone J, Fogwill M, Yu Y. Comparing ELSD and CAD Performance on Polysorbate Quantification in Infliximab Drug Products. Waters Application Note. 2022.
- Birdsall R, Du X, Bigos P, Han D, Bhiwankar N. Automating Charged Aerosol Detection (CAD) Analysis with Empower CDS Using a Single-Vendor Integrated LC Platform. Waters Application Note. 2026.
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