@phdthesis{Leistner2023,
  author    = {Leistner, Adrian Dieter},
  title     = {Improving the quality analysis of monographed drugs - dapsone, baclofen, acarbose and other selected APIs},
  doi       = {10.25972/OPUS-30331},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-303318},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2023},
  abstract  = {All presented studies aimed on the improvement of the quality analysis of already monographed drugs. Thereby different LC methods were applied and coupled to i.e., the UV/VIS detector, the CAD or a hyphenation of these detectors, respectively. The choice of the chromatographic system including the detector was largely dependent on the physicochemical properties of the respective analytes. With the risk-assessment report on the API cetirizine we presented an exemplary tool, that can help to minimize the risk of the occurrence of unexpected impurities. An in- deep analysis of each step within synthesis pathway by means of reaction matrices of all compounds was performed. It is essential to understand the complete impurity profile of all reactants, solvents, and catalysts and to include them in the matrix. Finally, the API of this synthesis was checked if all impurities are identified by this tool. Of note, a shortcoming of such a targeted approach is that impurities can still occur, but they are not captured. This disadvantage can be partially compensated by non-targeted approaches if they are performed in parallel with the other studies that represent most of the impurities. However, this work also shows that even in a supposedly simple synthesis, potentially hundreds of by-products can be formed. For each of them, it must be decided individually whether their formation is probable or how their quantity can be minimized in order to obtain APIs, that are as pure as possible. In the dapsone project it was aimed to replace the existing old Ph. Eur. TLC method with a modern RP-HPLC method. This was successful and since Ph. Eur. 10.6, the method developed in this work, became a valid monograph. Within the revision process of the monograph, the individual limits for impurities were tightened. However, this new method needs HPLC instrumentation, suitable to perform gradients. As this is not always available in all control laboratories, we also developed an alternative, more simple method using two different isocratic runs for the impurity analysis. The obtained batch results of both, the new pharmacopoeial method and the more simple one, were in a comparable order of magnitude. Furthermore, within the method development stage of the Ph. Eur. method, we could identify one unknown impurity of the impurity reference by high-resolution MS/MS analysis. Also, in the baclofen project it was aimed to replace the existing Ph. Eur. method with the introduction of an additional impurity to be quantified. A corresponding method was developed and validated. However, due to the harmonization process of the pharmacopoeias, it is currently not used. In addition, we tried to find further, non- 116 SUMMARY chromophoric impurities by means of the CAD. However, except for one counterion of an impurity, no further impurities were found. Also, the aforementioned new impurity could not be detected above the reporting threshold in the batches analyzed. As the only individually specified impurity A is also present at a low level, it can be concluded that the examined batches of baclofen are very pure. The use of universal detectors, such as the CAD can be particularly interesting for compounds with no chromophore or those with only a weak chromophore. Therefore, we decided to take a closer look at the impurity profile of acarbose. Currently, acarbose and its impurities are being studied by low wavelength UV detection at 210 nm. Therefore, the question arose whether there are no other impurities in the API that do not show absorption at this wavelength. CAD, which offers consistent detection properties for all non-volatile compounds, is ideally suited for this purpose. However, it was not so easy to use the CAD together with the UV detector, for example, as a hyphenated detection technique, because the Ph. Eur. method uses phosphate buffers. However, this is non-volatile and therefore inappropriate for the CAD. Therefore, an attempt was made to replace the buffer with a volatile one. However, since this did not lead to satisfactory results and rather the self-degradation process of the stationary phase used could be observed by means of the CAD, it was decided to switch to alternative stationary phases. A column screening also revealed further difficulties with acarbose and its impurities: they show an epimerization reaction at the end of the sugar chain. However, since one wanted to have uniform peaks in the corresponding chromatograms, one had to accelerate this reaction significantly to obtain only one peak for each component. This was best achieved by using two stationary phases: PGC and Amide-HILIC. Impurity-profiling methods could be developed on each of the two phases. In addition, as expected, new impurities could be detected, albeit at a low level. Two of them could even be identified by spiking experiments as the sugar fragments maltose and maltotriose. Taken together, it can be concluded, that this work has contributed significantly to the improvement of the quality analysis of monographed drugs. In addition to the presented general tool for the identification of potential impurities, one of the methods developed, had already been implemented to the Ph. Eur. In an effort to improve the CAD's universal detection capabilities, additional methods have also been developed. Further, new improved methods for the impurity profiling are ready to use.},
  subject      = {Instrumentelle Analytik},
  language  = {en}
}
@phdthesis{Wohlfart2022,
  author    = {Wohlfart, Jonas},
  title     = {Analysis of Drug Impurities by Means of Chromatographic Methods: Targeted and Untargeted Approaches},
  doi       = {10.25972/OPUS-27387},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-273878},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2022},
  abstract  = {The presented works aimed on the analysis of new impurities in APIs and medicinal products. Different subtypes of LC were coupled to suitable detection methods, i.e. UV and various MS techniques, depending on the chemical natures of the analytes and the analytical task. Unexpected impurities in medicinal products and APIs caused several scandals in the past, concomitant with fatalities or severe side effects in human and veterinary patients. The detection of nitrosamines in sartans led to the discovery of nitrosamines in various other drugs, of which the antibiotic rifampicin was analyzed in this work. An examination of the synthesis of rifampicin revealed a high potential for the formation of 4-methyl-1-nitrosopiperazine (MeNP). An LC-MS/HRMS method suitable for the quantification of MeNP was applied in the analysis of drugs collected from Brazil, Comoros, India, Nepal, and Tanzania, where a single dose of rifampicin is used in the post-exposure prophylaxis of leprosy. All batches were contaminated with MeNP, ranging from 0.7-5.1 ppm. However, application of rifampicin containing up to 5 ppm MeNP was recommended by the regulatory authorities for the post-exposure prophylaxis of leprosy. In the 1990s the aminoglycoside antibiotic gentamicin attracted attention after causing fatalities in the USA, but the causative agent was never identified unequivocally. The related substance sisomicin was recognized as a lead impurity by the Holzgrabe lab at the University of W{\"u}rzburg: sisomicin was accompanied by a variety of other impurities and batches containing sisomicin had caused the fatalities. In 2016, anaphylactic reactions were reported after application of gentamicin. A contamination of the medicinal products with histamine, an impurity of the raw material fish peptone used upon the production, could be identified as the cause of the adverse effects. Batches of gentamicin sulfate, which had been stored at the University of W{\"u}rzburg since the earlier investigations, were analyzed regarding their contamination with histamine to determine whether the biogenic amine was responsible for the 1990s fatalities as well. Furthermore, a correlation with the lead impurity sisomicin was checked. Histamine could be detected in all analyzed batches, but at a lower level than in the batches responsible for the anaphylactic reactions. Moreover, there is no correlation of histamine with the lead impurity sisomicin. Hence, the causative agent for the 1990s fatalities was not histamine and remains unknown. Another source of impurities is the reaction of APIs with excipients, e.g. the esterification of naproxen with PEG 600 in soft gel capsules. The influence of the formulation's composition on this reaction was investigated by means of LC-UV. Therefore, the impurity naproxen-PEG-ester (NPEG) was synthesized and used for the development of a method suitable for the analysis of soft gel capsule formulations. Different formulations were stressed for 7 d at 60 °C and the relative amount of NPEG was determined. The formation of NPEG was influenced by the concentrations of water and lactic acid, the pH, and the drug load of the formulation, which can easily be explained by the chemistry behind esterification reactions. Keeping in mind the huge variety of sources of impurities, it might be impossible to predict all potential impurities of a drug substance/product. Targeted and untargeted approaches were combined in the impurity profiling of bisoprolol fumarate. Eight versions of an LC-HRMS method were developed to enable the detection of a maximum number of impurities: an acidic and a basic buffered LC was coupled to MS detection applying ESI and APCI, both in positive in negative mode. MS and MS/MS data were acquired simultaneously by information dependent acquisition. In the targeted approach, potential impurities were derived from a reaction matrix based on the synthesis route of the API, while the untargeted part was based on general unknown comparative screening to identify additional signals. 18 and 17 impurities were detected in the targeted and the untargeted approach, respectively. The molecular formulae were assessed based on the exact mass and the isotope pattern. Theoretical fragment spectra generated by in silico fragmentation were matched with experimental data to estimate the plausibility of proposed/elucidated structures. Moreover, the detected impurities were quantified with respect to an internal standard.},
  subject      = {LC-MS},
  language  = {en}
}
@phdthesis{Pawellek2021,
  author    = {Pawellek, Ruben},
  title     = {Charged Aerosol Detector Performance Evaluation and Development of Optimization Strategies for the Analysis of Amino Acids},
  doi       = {10.25972/OPUS-24319},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-243197},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {The charged aerosol detector (CAD) is an aerosol-based detector employed in liquid chromatography which has become established in the field of pharmaceutical analysis due to its outstanding performance characteristics, e.g. the almost uniform response for nonvolatile analytes. Owing to its principle of detection, the response of the CAD depends on the volatility of a compound and is inherently nonlinear. However, the newly implemented instrumental settings evaporation temperature and power function value (PFV) are valuable tools to overcome some of these drawbacks and can even enhance the detector's capabilities when adjusted properly. This thesis aimed to evaluate the impact of the new instrumental settings on the CAD performance. Additionally, the influence of modern separation techniques for small polar compounds on the CAD was assessed and the applicability of hyphenated UV-CAD techniques explored. The optimization strategies derived from the evaluation procedures and the conjunction of the instrumental and chromatographic techniques investigated were utilized for the challenging impurity profiling of amino acids and amino acid-like drugs. The results of the method validation procedures confirmed the broad applicability of the CAD in the pharmaceutical analysis of nonvolatile compounds, supported by satisfactory sensitivity and reproducibility for meeting the regulatory requirements with respect to the ICH guidelines Q2(R1) and Q3A(R2). The limits of applicability include the analysis of semivolatile compounds, and the method transfer between current and legacy CAD models. Further advances in the definition and standardization of allowed ranges for the instrumental settings and the establishment of general optimization procedures in the method development could lead to a more widespread use of the detection technique in compendial methods.},
  subject      = {Instrumentelle Analytik},
  language  = {en}
}
@phdthesis{HebronMwalwisi2018,
  author    = {Hebron Mwalwisi, Yonah},
  title     = {Assessment of Counterfeit and Substandard Antimalarial Medicines using High Performance Thin Layer Chromatography and High Performance Liquid Chromatography},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-145821},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2018},
  abstract  = {Although the prevalence of substandard and counterfeit pharmaceutical products is a global problem, it is more critical in resource-constrained countries. The national medicines regulatory authorities (MNRA) in these countries have limited resources to cater for regular quality surveillance programmes aimed at ensuring that medicines in circulation are of acceptable quality. Among the reasons explained to hinder the implementation of these strategies is that compendial monographs are too complicated and require expensive infrastructures in terms of environment, equipment and consumables. In this study it was therefore aimed at developing simple, precise, and robust HPLC and HPTLC methods utilizing inexpensive, readily available chemicals (methanol and simple buffers) that can determine the APIs, other API than declared one, and which are capable of impurity profiling. As an outcome of this study, three isocratic and robust HPLC and two HPTLC methods for sulfadoxine, sulfalene, pyrimethamine, primaquine, artesunate, as well as amodiaquine have been developed and validated. All HPLC methods are operated using an isocratic elution mode which means they can be implemented even with a single pump HPLC system and standard C18 columns. The densitometric sulfadoxine/sulfalene and pyrimethamine method utilizes standard TLC plates as well as inexpensive, readily available and safe chemicals (toluene, methanol, and ethyl acetate), while that for artesunate and amodiaquine requires HPTLC plates as well as triethylamine and acetonitrile due to challenges associated with the analysis of amodiaquine and poorly the detectable artesunate. These HPTLC methods can be implemented as alternative to those requiring HPLC equipment e.g. in countries that already have acquired densitometer equipment. It is understood that HPTLC methods are less sensitive, precise and accurate when compared to HPLC methods, but this hindrance can easily be addressed by sending representative samples to third party quality control laboratories where the analytical results are verified using compendial HPLC methods on a regular basis. It is therefore anticipated that the implementation of these methods will not only address the problem of limited resources required for medicines quality control but also increase the number of monitored targeted antimalarial products as well as the number of resource- constrained countries participating in quality monitoring campaigns. Moreover, the experiences and skills acquired within this work will be applied to other API groups, e. g. antibiotics, afterwards.},
  subject      = {Instrumentelle Analytik},
  language  = {en}
}
@phdthesis{Wahl2016,
  author    = {Wahl, Oliver},
  title     = {Impurity Profiling of Challenging Active Pharmaceutical Ingredients without Chromophore},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-137205},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2016},
  abstract  = {The impurity profiling of pharmaceutical ingredients can oppose many challenges. The best part of active pharmaceutical ingredients (APIs) and the related substances are detectable by UV detection, a very common detection principle. However, if an API lacks a suitable chromophore other means of detection are necessary. The corona charged aerosol detector (CAD) is a detector capable of detecting substances independent of their chemical structure. This "universal" detector has only one limitation: The analyte has to have a sufficiently low vapor pressure. Another important challenge that comes often together with the lack of a chromophore concerns the separation. These substances (e.g. most amino acids and derivatives) often contain structures that make them difficult to retain on conventional reversed phase columns. Possible solutions to overcome these challenges, like the application of the CAD and the benefit of so-called mixed-mode stationary phases in impurity profiling for pharmacopoeial purposes were explored in this work. The related substances analyzed in this thesis comprise amino acids, inorganic ions, bisphosphonic acids, basic and acidic derivatives of amino acids (esters and amides). The successful development and validation of mixed-mode liquid chromatography methods with CAD detection for carbocisteine and ibandronate sodium might help to increase the acceptance of this versatile detector in the pharmaceutical industry and in official authorities dealing with the determination of related substances. The combination of UV and CAD detection proved very useful during the analysis of Bicisate. Most of the related substances and some unidentified impurities were detectable by CAD whereas a synthesis by-product, a semi-volatile ester, was only detectable in the UV trace. The simple combination covers all relevant impurities in a single analysis. Two truly orthogonal methods regarding separation and detection for the enantiomeric purity of magnesium-L-aspartate helped to find the reason for elevated D aspartic acid content in the drug substance. A very quick and sensitive indirect separation using the OPA derivatization with NAC was developed as a powerful screening tool, whereas the direct separation of D- and L-CBQCA-Asp derivatives confirmed the results. Both methods were optimized in order to do without substances mentioned on the REACH list, like sodium tetraborate which is very frequently applied in standard derivatization protocols and CE separations. The importance of orthogonal detection principles in the determination of related substances of amino acids was discussed in a review article dealing with the revision of amino acid monographs in the Ph. Eur..},
  subject      = {Chromatographie},
  language  = {en}
}