Separation and indirect detection of small-chain peptides using chromophoric mobile phase additives

Ruthenium(II) 1,10-phenanthroline, Ru(phen)3(2+), and ruthenium(II) 2,2'-bipyridyl, Ru(bipy)3(2+), salts were evaluated as mobile phase additives for the liquid chromatographic separation of small-chain peptides on a polystyrene-divinylbenzene copolymeric (Hamilton PRP-1) stationary phase. In a basic mobile phase peptides are anions, and retention, resolution and detection occur because of the interactions between the stationary phase, the RuII complex and the peptide anion. Since the RuII complex concentration changes in the analyte band relative to the background eluent RuII complex concentration, the peptide can be detected by indirect photometric detection using the wavelength where the RuII complex absorbs. Peptide analyte peaks may be positive or negative depending on the counter-anion and its concentration. Small-chain peptides that do not contain chromophoric side-chains are detected without derivatization at about 0.1 nmol injected at a 3:1 signal-to-noise ratio. Factors that affect retention, resolution and indirect photometric detection are the RuII complex, its mobile phase concentration, mobile phase pH and solvent composition, and the type and concentration of the mobile phase counter-anion and/or buffer anion.     

Determination of ethanol in alcoholic beverages by liquid chromatography using the UV detector

Ethanol in certain beverages and in similar solutions may be determined by reversed-phase liquid chromatography (LC) using the UV detector. The mobile phase in this indirect photometric detection technique contains a low concentration of a UV-absorbing compound, such as acetone, that coelutes with the ethanol peak. Several variables such as the choice and concentration of the UV-detection agent are examined regarding their effects on the retention time, magnitude and linearity of peak area, and other aspects of quantitation. Except for filtering to remove particulate matter, samples can be injected without pretreatment. The concentration of ethanol in several types of beverages can be determined with 2% relative standard deviation, calibration is linear to 40% ethanol, and the minimum detectable concentration is 0.1%.     

Indirect UV detection of non-ionic substances in liquid chromatography by addition of a UV-absorbing uncharged compound to the mobile phase

Summary Chromatographic systems have been developed, which allow the detection and quantitation of non-ionic substances with low or no UV-absorptive properties. The detector response is obtained by using mobile phases containing an uncharged component with high UV-absorbance. Polar or non-polar bonded stationary phases have been selected, depending on the hydrophobic character of the analytes. The response pattern is compared to that observed in ion-pair reversed-phase systems with a UV-absorbing ion in the eluent. The influence on retention and detection sensitivity of the nature and concentration of the UV-absorbing compound and of the organic modifier added to the mobile phase has been studied. Principles for the optimisation of the response by changing the mobile phase composition are given. The wide application scope of the indirect UV-detection technique in non-ionic systems is demonstrated by examples of separations of various kinds of compounds, such as organic solvents, carbohydrates and polyols. Presented at the 15th International Symposium on Chromatography, Nürnberg, October 1984     

Indirect conductimetric detection of amino acids after liquid chromatographic separation

A liquid chromatographic method using indirect conductimetric detection is proposed for the determination of low levels of organic compounds, which does not require any special functional characteristics of the analyte. The signal detected is proportional to the molar concentration of the analyte and independent of its nature. The detector response is linearly dependent on analyte concentrations over at least three orders of magnitude. The basis of the detection is to create a conducting background, which will decrease on elution of the organic compounds. The theory of the method is discussed, with special reference to the quantitative displacement of the conducting species of the mobile phase from the column by the analyte on sample injection. The proposed method has been applied to study the chromatographic behaviour of twenty-one amino acids, where a 5 -μm Econosil CN column was used as the stationary phase with a mixture of water-acetonitrile-tetrahydrofuran (70:20:3) containing 1 mM perchloric acid or trichloroacetic acid as the mobile phase. The proposed method allows as little as 10 ng of each amino acid to be determined.     

New isoelectric buffers for capillary electrophoresis: N-carboxymethylated polyethyleneimine as a macromolecular isoelectric buffer

Isoelectric buffers are attractive for electrophoresis because of their low conductivity, and their compatibility with indirect photometric detection in capillary electrophoresis (CE) where they do not interfere with the detection by exhibiting competitive displacement of the UV-absorbing probe ion. N-carboxymethylated polyethyleneimine (CMPEI) was prepared by introducing a half molar equivalent of carboxylate groups onto a polyethyleneimine backbone. Its isoelectric point determined by conductometric titration and from the pH of its dilute aqueous solution is approx. 6.8, which allows isoelectric buffering at a lower pH compared to histidine (pI7.7). Although the isoelectric point is somewhat diffuse, as expected for a polymeric compound, it exhibits a buffering capacity at a pI point of about twice that of histidine. Studies of electroosmotic flow (EOF) profile at various pH values in fused silica capillaries showed that CMPEI adsorbs onto the fused silica wall and reverses the EOF at pH < 6.5. CMPEI was applied as a buffer in an electrolyte containing 0.5 mM of the anionic dye tartrazine used as the probe for indirect detection of anions. The separation system exhibited a stable baseline, no system peaks, separation efficiencies of up to 195,000 theoretical plates, and detection limits down to 0.2 microM or 2 amol of injected analyte.     

Separation of acetylated amino acids

Acetylated amino acids (Nac-AA) are separated as anions on a reversed stationary phase from a mobile phase containing a quaternary ammonium (R₄N⁺) salt as a mobile phase additive. If the counteranion accompanying the R₄N⁺ or ionic strength salt is detector active than the separated NAc-AA derivatives can be detected by an indirect detection strategy. Variables influencing the separations are NAc-AA side chain structure and the mobile phase parameters such as hdyrophobicity of the alkyl groups in the R₄N⁺ salt, R₄N⁺ salt concentration, counteranion eluent strength, counteranion concentration, solvent composition, and pH. Indirect detection is influenced by these same mobile phase parameters as well as the properties of the detector active counteranion. The detection limit for indirect photometric detection at 287 nm using a tetrapentylammonium salt with a disodium 1,5-naphthalenedisulfonate—sodium benzoate counteranion mixture was about 70 pmol of NAc-AA depending on the amino acid injected as a 10-μ1 sample.     

An investigation into detector limitations using evaporative light-scattering detectors for pharmaceutical applications

Evaporative light-scattering detection (ELSD) high-performance liquid chromatography (HPLC) is an alternative technology to low-wavelength UV analysis that is often employed when compounds lack sufficient absorptivity. Although ELSD provides an additional detector option for liquid chromatographers, studies in our laboratory indicate analyte properties may adversely affect the ability to detect certain molecules. In this investigation, a series of low-molecular-weight compounds of pharmaceutical interest are evaluated with two commercially available ELSDs. It is observed that melting point is a useful analyte property to consider in optimizing ELSD detectors. The melting point of the analyte should be significantly higher than what the compound will experience in the nebulizer/evaporator chambers to achieve the best analyte response. It is found that some analytes could not be distinguished from the evaporated mobile phase background when ELSD temperatures exceed the melting point of the compound. Though useful for many applications and of particular interest for compounds that are weak chromophores, ELSD falls short of being a "universal detector" technology. In addition to boiling points of mobile phase components, scientists should also consider the melting point and volatility of the analyte(s) when optimizing ELSD response.     

Determination of alkylphosphonic acids by capillary zone electrophoresis using indirect UV detection

Capillary zone electrophoresis with indirect UV detection was used for the determination of a series of alkylphosphonic acids. For this purpose, a few UV-absorbing background electrolytes were tested and phenylphosphonic acid, which has a mobility close to that of the analysed compounds, was shown to be the most suitable. The influence of several parameters such as concentration of the UV-absorbing background electrolyte and concentration of borate on both sensitivity and efficiency was investigated. An increase in the borate concentration produced an improvement of the signal-to-noise ratio. Conversely, the sensitivity decreased with increasing concentration of the phenylphosphonic acid. The reproducibility of the method was very satisfactory and limits of detection were less than 0.21 pmol injected.     

Evaluation of the signal intensity of induced peaks in indirect photometric detection of nonelectrolytes in reversed-phase high-performance liquid chromatography

Summary We have experimentally evaluated the equation representing the peak area of induced peaks in indirect photometric detection of nonelectrolytes as a function of the amount and concentration of the analyte and the visualizing agent and their capacity factor, the phase ratio of the column and the absorptivity and the pathlength of detection. Aliphatic alcohols and hydrocarbons were used as the test analytes. Most of the analytes behaved according to the relationship expressed by the equation.     

High-performance liquid chromatographic analysis for a non-chromophore-containing phosphatidyl inositol analog, 1-((1-O-octadecyl-2-O-methyl-sn-glycero)phospho)-1D-3-deoxy-myo-inositol, using indirect UV detection

Phosphatidylinositide-3-kinase (PI3 kinase) is an important constituent of growth factor regulation. It is also involved in oncogene signaling pathways. An ether-containing phosphatidyl inositol(PI) analog, OMDPI, 1-[(1-O-octadecyl-2-O-methyl-sn-glycero)-phospho]-1D-3-deoxy-myo-inositol, is a potent inhibitor of this pathway and may be clinically useful in the treatment of a variety of neoplasms. OMDPI is currently being investigated as an anti-tumor agent by the National Cancer Institute, NIH. OMDPI, a non-chromophore-containing PI analog, is not directly adaptable to the commonly used UV detection of HPLC. This paper reports the development and validation of an HPLC assay for OMDPI based on indirect UV detection, in which a UV-absorbing ion-pair reagent (the probe), protriptyline, is added to the mobile phase to induce a signal for the compound. The method is sensitive (limit of detection <5 microl of 1 microg/ml or 5 ng), precise (R.S.D.<2.5%), linear (r2=0.9995) and accurate (error<0.7%). It is superior to refractive index detection and evaporative light scattering detection in either sensitivity or linearity and does not require special equipment.     

Determination of ethambutol by ion-pair reversed phase liquid chromatography with UV detection

An ion-pair reversed phase liquid chromatography method for the antituberculosis drug ethambutol hydrochloride was developed using sodium 1-heptanesulfonate (4.0 mg/ml) as an ion-pairing (IP) reagent. To enable detection of the ethambutol with a UV detector without sample pretreatment, the pH 4.5 aqueous tetrahydrofuran (THF) (25%, v/v) mobile phase contained 1.0 mM Cu(II), which forms a UV-absorbing complex with the analyte. At a column temperature of 35 °C, ethambutol gives a symmetrical peak with a retention time of 5 min. Chromatographic conditions were optimized through study of the effects of mobile phase composition and pH, Cu(II) and IP reagent concentration, and column temperature. The method is shown to be simple, precise, efficient, robust, linear up to at least 0.25 mg/ml, and to have a limit of quantitation of 6 μg/ml.     

高效液相色谱-间接光度检测法测定己内酰胺酸团中的正己烷含量

采用在流动相中添加有紫外吸收的本底试剂的方法,利用高效液相色谱-间接光度检测法直接测定己内酰胺酸团中无紫外吸收的正己烷含量。考察了流动相组成、本底试剂的种类和浓度、波长梯度等对测定的影响。确定的高效液相色谱条件: 色谱柱为Agilent HC-C18柱(250 mm×4.6 mm, 5 μm),流动相为含1.17 mmol/L 1,5-萘二磺酸(本底试剂)的甲醇-水(85:15, v/v)溶液,柱温为35 ℃,流速为1.0 mL/min,并采用设定波长梯度的方法调整系统峰和被测峰的相对大小。该分析方法的线性范围为0.5～20 mg/kg,相关系数为0.99993,相对标准偏差为2.53%,检出限为0.03 mg/kg,加标回收率为98.45%～102.3%。方法简单,选择性好,灵敏度高,抗干扰强,可快速准确地测定实际样品中的正己烷。     

Indirect fluorescent determination of selected nitro-aromatic and pharmaceutical compounds via UV-photolysis of 2-phenylbenzimidazole-5-sulfonate

An indirect fluorescence (FL) detection method via the reactivity of UV-photolyzed 2-phenylbenzimidazole-5-sulfonate (PBSA) has been developed for non-fluorescent aromatic compounds. At high pH with UV photolysis, PBSA in the excited state is known to be quenched by reaction with oxygen species and analyte compounds that are reactive toward these oxygen species produced during photolysis can lessen the loss of PBSA FL. After off-line photolysis of PBSA in the presence of various nitro-aromatic test compounds, the increase in PBSA FL is clearly evident. A flow injection (FI) instrument using a PBSA mobile phase propelled through a Teflon coil wrapped around a Hg lamp is optimized and modified for use for liquid chromatography (LC). For the on-line FI determination of the non-fluorescent nitro-aromatic compounds such as 4-nitroaniline, 2-nitrophenol, 3-nitrophenol, 4-nitrophenol, and -nitronaphthalene, a positive linear response for PBSA FL from about 0.5 to 15 μM and detection limits generally between 0.2 and 1 μM (4–20 pmol) are found. Linear responses and detection limits of selected pharmaceutical compounds such as the antibacterial nitrofurantoin, antihistamines chlorpheniramine and brompheniramine, and other compounds were similar. In general, detection limits using UV detection at about 214 nm were not as good in the 1–2 μM range but linearity extended up to 100 μM. The amino acid phenylalanine and small peptides containing this aromatic amino acid were also determined using this method. Application of this detection method for the liquid chromatography determination of 4-nitroaniline, 2-nitrophenol, nitrofurantoin, and salicylate is shown.     

Chiral separation of amines in subcritical fluid chromatography using polysaccharide stationary phases and acidic additives

The chiral separation of basic compounds by subcritical fluid chromatography (SFC) is often unsuccessful, due possibly to multiple interactions of the analyte with the mobile and stationary phase. Incorporation of a strong acid, ethanesulfonic acid (ESA), into the sample diluent and mobile phase modifier gives a dramatic improvement in these separations. Screening with ethanol containing 0.1% ESA on CHIRALPAK AD-H gave separation of 36 of 45 basic compounds previously not separated in SFC. The mechanism appears to involve the separation of an intact salt pair formed between the basic compound and ESA. Other modifiers, other acids and one additional stationary phase were examined and found to yield additional separations.     

Analysis of basic compounds at high pH values by reversed-phase liquid chromatography

Reversed phase high performance liquid chromatography (RPLC) is currently the method of choice for the analysis of basic compounds. However, with traditional silica materials, secondary interactions between the analyte and residual silanols produce peak tailing which can negatively affect resolution, sensitivity, and reproducibility. In order to reduce these secondary interactions, which comprise ion exchange, hydrogen bonding, and London forces interactions, chromatographic analyses can be carried out at low or high pH values where silanol groups and basic compounds are mostly uncharged. The chromatographic behaviour of a particular bidentate stationary phase, Zorbax Extend C18, was studied with a set of basic and neutral compounds. Thanks to a higher chemical stability than traditional silica based supports, analyses were carried out with a high pH mobile phase, which represents a good alternative to the acidic mobile phases generally used to reduce ion exchange interactions. The performance of this bidentate stationary phase was also compared with that of other supports and it was proved that it is advantageous to work with high pH mobile phases when analyzing basic compounds.     

Simultaneous determination of sulfite, sulfate, and hydroxymethanesulfonate in atmospheric waters by ion-pair HPLC technique

A reversed-phase ion-pair HPLC with indirect photometric detection for the simultaneous determination of sulfite, sulfate, hydroxymethanesulfonate (HMS), and other inorganic anions in atmospheric water has been developed. Separations were accomplished in less than 10 min in a cetylpyridinium-coated C₁₈ column with 0.5 mM potassium hydrogen phthalate-0.015% triethanolamine-3% methanol at pH 7.9 as mobile phase. Quantitation was carried out by the peak area method, with detection limits in the pmol range. UV light absorption responses were linear over a wide concentration range from several hundred μmoles to the detection limits of each anion. The application of the method provides a rapid and efficient technique for the quantitative determination of sulfur and other inorganic species in atmospheric liquids.     

Sensitive, indirect photometric detector for high-performance liquid chromatography using a light-emitting diode

A low-noise detector for indirect photometric detection has been constructed using a highly stable source--a light-emitting diode (LED). Use of the detector is demonstrated for reversed-phase liquid chromatography by adding methylene blue to the mobile phase to make a background signal. The indirect determination of alcohols by their effect on methylene blue concentration distribution is demonstrated, and an investigation is made into the conditions for high sensitivity. Because the source exhibits low noise, the detection limits for alcohols are as low as more complex and expensive detection methods, despite the lower radiant power of the LED. Detection limits for nine alcohols are below micrograms injected amounts.     

Improvement of peak shape in aqueous normal phase analysis of anionic metabolites

The problem of poor peak shape for multiply charged negative-ion analytes under aqueous normal phase (ANP) conditions is investigated. Because less than adequate efficiency and symmetry can occur with a variety of mobile phases, gradients and additives, and to varying degrees depending on the instrument, sources other than solute/stationary phase interactions are more likely the cause. Since it is known that many of these compounds can interact strongly with metal ions, addition of a chelating agent to the mobile phase and/or the sample solvent was tested. In particular, ethylenediaminetetraacetic acid (EDTA) is a compound that forms strong complexes with most di-and tri-valent metal ions and can be used to verify whether trace amounts of these species are the source of the problem. In addition, the retention of a number of anionic compounds was measured at various concentrations of ammonium acetate and formate with EDTA in the mobile phase.     

Phase Systems and Post-Column Dithizone Reaction Detection for the Analysis of Organo-Mercurials by HPLC

Abstract

The suitability of HPLC (normal and reversed phase adsorption) with UV or post-column reaction detection for the analysis of organomercurials was investigated systematically. The separation of organomercurials is best carried out on a reversed phase system with a C-8 bonded phase material as the stationary phase and acetonitrile-aqueous sodium bromide mixtures as the mobile phase.

The precision and detection limit of the method and the efficiency of the extraction procedure were established. For the alkylmercury compounds the lowest limit of detection (80ppb) was obtained with the dithizone reaction detection and for the phenylmercury compounds with UV detection (60ppb). A chromatogram of a spiked fish (2ppmHg) and a river water sample (50ppbHg) is shown.     

The Separation of Organic Analyte Cations on a Low-Capacity Cation Exchange Column Using Indirect UV Detection

Abstract

The retention of organic analyte cations on a low-capacity cation exchange column using indirect UV detection was studied. It was found that a combination of cation exchange/reversed-phase interactions affected the retention of organic analyte cations provided the analytes have both a cationic charge site and a hydrophobic center. The factors that influenced the organic analyte cation retention were: concentration of organic modifier, concentration of UV absorbing analyte, pH, and mobile phase ionic strength. Elution orders for several of the organic analytes studied on the low-capacity cation exchange column were different than those observed on silica-based strong cation exchange columns.