develop-hplc-method

pjt222

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Dieses Claude Skill führt Entwickler durch die systematische HPLC-Methodenentwicklung für anspruchsvolle Analyten wie nichtflüchtige oder polare Verbindungen. Es bietet einen strukturierten Arbeitsablauf zur Auswahl der Säulenchemie, der mobilen Phase, der Gradientenbedingungen und der Detektoren. Nutzen Sie es, wenn Sie eine Flüssigkeitschromatographie-Trennungsmethode erstellen oder optimieren müssen.

Schnellinstallation

Claude Code

Dokumentation

Develop an HPLC Method

Systematic HPLC dev: mode pick + col chem + mobile phase + gradient + flow/temp + detector + iterative refine for non-volatile, thermally labile, polar analytes.

Use When

Non-volatile / thermally labile / too polar for GC
New HPLC-UV, FLD, LC-MS from scratch
Adapt literature/compendial method → diff col/instrument
Improve existing: poor Rs, long runs, sensitivity
Pick chromatographic mode (RP, HILIC, IEX, SEC, chiral)

In

Required

Target analytes: Name + struct + MW + pKa + logP/logD
Sample matrix: Formulation, bio fluid, env extract, neat
Perf targets: Rs + LOD/LOQ + quant range

Optional

Reference method: Compendial/literature → start
Available columns: On-hand inventory
Instrument: UHPLC vs conventional, detectors, col oven
Throughput: Max run + re-equilibration
Regulatory: ICH, USP, EPA, etc

Do

Step 1: Separation Goals

Compile analyte props: MW, pKa, logP (logD at pH), chromophores, fluorophores, ionizable.
ID matrix + interferents (excipients, endogenous, degradants).
Perf criteria:
- Rs critical pairs (≥ 2.0 regulated)
- LOD/LOQ
- Run time incl re-equilibration
Assay / impurity profile / dissolution / content unif / clean verify → drives valid. category.
Isocratic vs gradient: isocratic if all analytes 2 < k' < 10; else gradient.

→ Spec doc: analytes + props + matrix + perf + isocratic/gradient decision.

If err: pKa/logP unknown → estimate from struct (ChemAxon, ACD/Labs) or scout gradient on C18 at pH 3 + pH 7 → empirical retention.

Step 2: Col Chemistry

Mode + col by analyte props.

Mode	Column Chemistry	Mobile Phase	Best For
Reversed-phase (RP)	C18 (ODS)	Water/ACN or water/MeOH + acid/buffer	Non-polar to moderately polar, most small molecules
RP (extended)	C8, phenyl-hexyl, biphenyl	Water/organic + modifier	Shape selectivity, aromatic compounds, positional isomers
RP (polar-embedded)	Amide-C18, polar-endcapped C18	Water/organic, compatible with high aqueous	Polar analytes that elute too early on standard C18
HILIC	Bare silica, amide, zwitterionic	High organic (80-95% ACN) + aqueous buffer	Very polar, hydrophilic compounds (sugars, amino acids, nucleotides)
Ion-exchange (IEX)	SAX or SCX	Buffer with ionic strength gradient	Permanently charged species, proteins, oligonucleotides
Size-exclusion (SEC)	Diol-bonded silica, polymer	Isocratic aqueous or organic buffer	Protein aggregates, polymers, molecular weight distribution
Chiral	Polysaccharide (amylose/cellulose)	Normal-phase or polar organic mode	Enantiomeric separations, chiral purity

Default RP C18 for small mols logP > 0.
logP < 0 → HILIC or IEX.
Particle size: sub-2 um for UHPLC (higher eff + backpressure), 3-5 um conventional.
Col dim: 50-150 mm L, 2.1-4.6 mm ID. Narrow → save solvent + better MS.
Chiral → screen 3-4 CSPs w/ diff selectors.

→ Col chem + dims + particle size picked w/ justification.

If err: poor retention on C18 → more retentive (phenyl-hexyl for aromatics) or diff mode (HILIC for polar).

Step 3: Mobile Phase + Gradient

Organic modifier:
- ACN: lower visc, sharper peaks, better UV <210 nm
- MeOH: diff selectivity, sometimes better polar, higher visc
Aqueous + pH:
- Neutral: water + 0.1% formic acid (MS-compat) or phosphate buffer (UV only)
- Ionizable: buffer 2 pH units from pKa → single ionic form
- pH 2-3 (formic/phosphoric): suppresses acid ionization, good start
- pH 6-8 (ammonium formate/acetate): basic analytes or low pH selectivity insufficient
- pH 9-11 (ammonium bicarbonate, BEH cols): very basic on high-pH-stable cols
Gradient:
- Start 5-10% organic → 90-95% over 10-20 min scouting
- Evaluate scouting → useful organic range
- Narrow gradient to elution window
- Steeper = faster lower Rs; shallower = better Rs longer
Col wash (95% organic, 2-3 min) + re-equilibrate (5-10 col vol initial).
Isocratic → k' = 3-8 for analytes.

→ Mobile phase (org + aq + buffer + pH) + gradient defined, scouting confirms elution in window.

If err: poor selectivity (co-elution despite optimization) → swap modifier (ACN↔MeOH), shift pH 2 units, or ion-pair reagent for charged.

Step 4: Flow + Temp

Initial flow per col ID:
- 4.6 mm ID: 1.0 mL/min
- 3.0 mm ID: 0.4-0.6 mL/min
- 2.1 mm ID: 0.2-0.4 mL/min
Backpressure within limits (< 400 bar conventional, < 1200 bar UHPLC).
Col temp:
- Start 30 C → reproducibility (no ambient fluctuation)
- 40-60 C → lower visc, lower backpressure, sharper peaks
- Chiral → strong effect on enantioselectivity, screen 15-45 C
Flow effect on Rs: small increases may improve throughput w/o Rs loss near van Deemter min.
Doc flow + temp + backpressure.

→ Flow + temp optimized, backpressure in limits, Rs maintained/improved.

If err: backpressure too high → reduce flow, raise temp, or wider-bore/larger-particle col. Rs degrades at high temp → back to 30 C + accept longer run.

Step 5: Pick Detector

Detector	Principle	Sensitivity	Selectivity	Key Considerations
UV (single wavelength)	Absorbance at fixed lambda	ng range	Compounds with chromophores	Simple, robust, most common
DAD (diode array)	Full UV-Vis spectrum	ng range	Chromophores + spectral ID	Peak purity assessment, library matching
Fluorescence (FLD)	Excitation/emission	pg range (10-100x more sensitive than UV)	Native fluorophores or derivatized	Excellent selectivity, requires fluorescent analytes
Refractive index (RI)	Bulk property	ug range	Universal (no chromophore needed)	Temperature-sensitive, gradient-incompatible
Evaporative light scattering (ELSD)	Nebulization + light scattering	ng range	Universal, non-volatile analytes	Semi-quantitative, non-linear response
Charged aerosol (CAD)	Nebulization + corona discharge	ng range	Universal, non-volatile analytes	More uniform response than ELSD
Mass spectrometry (MS)	m/z detection	pg-fg range	Structural, highest selectivity	Requires MS-compatible mobile phases

UV chromophores (aromatic, conjugated) → start DAD (quant + peak purity).
Trace in complex matrices → MS (ESI or APCI) SIM or MRM.
No chromophore (sugars, lipids, polymers) → CAD, ELSD, or RI.
Wavelength at analyte lambda-max for sensitivity, or 210-220 nm general.
FLD → optimize ex/em via spectral scan.
Mobile phase additive compat: no phosphate w/ MS, no UV-absorbing at low lambda.

→ Detector + config (lambda, gain, rate) for analyte chem + sensitivity.

If err: UV sensitivity insufficient at LOQ → FLD derivatization (OPA for amines, FMOC for AAs) or LC-MS/MS for max sensitivity + selectivity.

Step 6: Evaluate + Refine

Inject suitability std 6× + evaluate:
- RT RSD < 1.0%
- Peak area RSD < 2.0%
- Rs critical pair ≥ 2.0
- Tailing 0.8-1.5 all
- Plates per col spec
Inject placebo/matrix blank → interference at RTs.
Inject stressed/spiked → method separates degradants from main analyte(s).
If fail → adjust one var at a time:
- Poor Rs: pH, slope, or col chem
- Tailing: amine modifier (TEA for basic), change buffer, diff bonded phase
- Sensitivity: larger inj, concentrate, swap detector
Lock final params + document.

→ All suitability met, method resolves targets from matrix + degradants, params documented for transfer.

If err: iterative tune doesn't fix → fundamentally diff (change mode, 2D-LC, derivatization) → back to Step 2.

Check

All targets Rs ≥ 2.0 critical pairs
RT RSD < 1.0% 6 reps
Peak area RSD < 2.0% 6 reps
Tailing 0.8-1.5 all
No matrix interference at RTs
Degradants resolved from main
Run time (incl re-eq) meets throughput
Mobile phase compat w/ detector
All params documented (col, MP, gradient, flow, temp, detector)

Traps

Ignore MP pH for ionizable: pH near pKa → split peaks / poor repro (two ionic forms). Buffer ≥ 2 pH units from pKa.
Phosphate w/ MS: Non-volatile, contaminates source. Formate or acetate for LC-MS.
Insufficient re-eq: Flush 5-10 col vols initial MP before next inj. Inadequate → RT drift.
Too short col for complex mixes: 50 mm → speed but not enough plates for multi-component. Start 100-150 mm for dev.
Ignore dwell vol: Mixer→head delay. Differs per instrument → method transfer fails. Measure + document.
HILIC like RP: HILIC needs high organic (80-95% ACN) + small aq. More aq → more elution strength (opposite of RP). Longer eq.

→

develop-gc-method — GC method dev for volatile/semi-volatile
interpret-chromatogram — reading HPLC + GC chromatograms
troubleshoot-separation — diagnose peak shape/RT/Rs
validate-analytical-method — formal ICH Q2 valid. of HPLC method

GitHub Repository

pjt222/agent-almanac

Pfad: i18n/caveman-ultra/skills/develop-hplc-method

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