Global ETD Search

1	Development of a novel antibody drug conjugate for the treatment of pancreatic adenocarcinoma Gromisch, Christopher Marr 07 October 2019 (has links) Pancreatic ductal adenocarcinoma (PDAC) is the most lethal common cancer in the United States: in 2017 there will be around 54,000 new cases and 43,000 patient deaths. (SEER, 2017) The high mortality of PDAC is related to late disease presentation and aggressiveness; nearly 52% of patients present with metastatic disease at the time of diagnosis. (SEER, 2017) Current treatments have marginal improvements on survival, with the most efficacious treatment, gemcitabine and nab-paclitaxel, having a median survival of 12.2 months. (Wu 2018) Failure of current PDAC treatments is attributed to the inefficacy of systemic chemotherapeutics and the development of resistance. (Rahib, 2014) The Dual Endothelin1/Signal PeptideVEGF receptor (DEspR), represents a promising therapeutic target for the treatment of PDAC: it is a highly expressed, specific tumor antigen, which is involved in tumor vasculogenesis and cancer stem cell (CSC) survival. DEspR is a developmentally crucial receptor, responsible for early angiogenesis and neural crest migration, with minimal expression in normal adult tissue. In vitro and in vivo studies of anti-DEspR therapy in PDAC have shown efficacy in decreasing CSC survival, tumor angiogenesis, and improving overall survival in xenograft models of PDAC, with anti-DEspR therapy being a promising candidate for clinical use. Furthermore, anti-DEspR therapy seems to augment chemotherapeutic therapy in vitro and in vivo, suggesting that a DEspR-targeted antibody drug conjugate (ADC) would be highly effective. ADCs are a re-emerging drug class with significant promise. Initial failures of ADCs in clinic were related to poor antigen specificity and failures in drug conjugation chemistry to minimally impact the antibody. To develop our ADC, I have developed a novel method of site-specific conjugation that relies on a novel method of supramolecular assembly. My system employs two specific protein sequences that do not self-interact, and tightly assemble through coulombic and hydrophobic interactions, allowing site-specific, stoichiometric self-assembly. To facilitate stable drug delivery, I have synthesized a novel enzymatically cleavable tyrosine-clickable linker, which prevents drug release prior to tumor delivery. Both further investigation into the efficacy of anti-DEspR therapy, and the development of a stoichiometric, site-specific, stable method for drug loading will provide an advancement in anti-cancer therapy. Pharmacology Antibody drug conjugates Pancreatic cancer Supramolecular assembly
2	New bacterial transglutaminase Q-tag substrate for the development of site-specific Antibody Drug Conjugates / Nouveaux subtrats Q-tag pour le développement d’ADCs site spécifique par activité enzymatique transglutaminase Sivado, Eva 04 December 2018 (has links) Es ADCs (Antibody-Drug Conjugates) correspondent à une nouvelle stratégie thérapeutique anti-tumorale particulièrement prometteuse. Néanmoins, les ADCs actuellement utilisés en clinique sont obtenus par conjugaisons chimiques, resultant en des mixtures hétérogènes impactant négativement leurs pharmacocinétiques et leurs performances in vivo.Récemment, différentes strategies de couplage site-spécifique ont été développées afin de réduire cette hétérogénéité. Dans cette thèse, nous rapportons le développement d’une nouvelle technologie CovIsoLink™ (Covalently Isopeptide Crosslinking) permettant la génération d’ADCs par utilisation de nouveaux peptides glutamine Q-Tag présentant des affinités optimisées par rapport à des peptides disponibles (ZQG, LLQG) pour une enzyme bactérienne la transglutaminase (mTG).La preuve de concept de cette technologie a été réalisée par insertion de ces peptides Q-Tag en C-ter de la région codant pour la chaine lourde des anticorps anti-HER2 (Trastuzumab). Nous avons ainsi pu démontrer la conjugaison homogène et reproductible de différentes drogues sans contamination par des chaines d’anticorps non conjuguées. Nous avons pu montrer que l’immunoréactivité et la capacité d’internalisation de ces ADCs n’étaient pas altérées par la conjugaison et qu’ils présentaient in vitro et in vivo, des propriétés de lyse de cellules tumorales similaires au Trastuzumab emtansine (Kadcyla®), actuellement en clinique. Par ailleurs, afin de généraliser notre technologie à différents formats d’anticorps nous avons générés des fragments Fab et scFv et évalué leur fonctionnalité. Ainsi, nous avons pu prouver que l’utilisation de nouveaux peptides optimisés Q-Tag substrat de la transglutaminase permettait une stratégie de couplage alternative plus homogène par couplage de différentes molécules sans espèce contaminante non couplée / Antibody-drug conjugates (ADCs) are a powerful class of therapeutic agents, demonstrating success in the treatment of several malignancies. The currently approved ADCs are produced by chemical conjugations and exist as heterogeneous mixtures that negatively influence the pharmacokinetics and in vivo performance. Recently many of site-specific conjugation technologies have been developed to reduce heterogeneity and batch-to batch variability. Microbial transglutaminase (mTG) has been demonstrated as efficient tool for site-specific conjugation. In this thesis we report the development CovIsoLink™ (Covalently Isopeptide Crosslinking) technology for the generation of homogenous immunoconjugates using a novel glutamine donor peptides (Q-tag) with improved affinity compared to the known peptides (ZQG, LLQG). As a proof of concept, the peptides sequences were engineered into the heavy chain C-terminal of Trastuzumab antibody. We demonstrated the reproducible and homogeneous conjugation of Q-tagged Trastuzumab with different payloads, without any unconjugated species. The ADCs were evaluated in series of in vitro and in vivo assays. We confirmed that the immunoreactivity and internalisation are not altered by the conjugation. Furthermore similar in vitro and in vivo tumor cell killing potency was demonstrated than Trastuzumab emtansine (Kadcyla®), which is already used in the clinic. Morover we extend our site-specific conjugation technology to antibody fragments (Fab and scFv), evaluating their functionality by conjugation with AlexaFluor488-cadaverine and in antigen binding assays. Thus, using novel glutamine donor peptides, our technology provides an alternative enzymatic conjugation strategy for the engrafment of different payloads resulting in homogeneous batches, without unconjugated species Antibody-Drug Conjugates Couplage site-spécifique Transglutaminase Fragments d’anticorps Antibody-drug conjugates Site-specific conjugation Microbial transglutaminase Antibody fragments 570
3	Theoretical Models for Drug Delivery to Solid Tumors Burton III, Jackson Kemper, Burton III, Jackson Kemper January 2016 (has links) A cancer drug's effectiveness is contingent upon on its ability to reach all parts of the tumor. The distribution of drug in the tumor depends on several transport processes and depends on the physicochemical properties of the drug. These factors can lead to highly heterogeneous distributions of drug in the tumor interstitial space, leaving parts of the tumor unreached, and make it difficult to predict cellular exposure and understand its dependence on key system parameters. Theoretical models are powerful tools that can provide insight by simulating conditions that cannot be achieved or observed experimentally. Here, a Green's function method is utilized to simulate three-dimensional time-dependent diffusion and uptake of drugs in solid tumors with realistic vascular geometry. Regimes dependent on the time scales for transport are used to determine whether spatial and temporal effects must be resolved to predict cellular exposure. Simulations are performed to show the relationship between the plasma pharmacokinetics and cellular exposure for these regimes. Steep gradients in concentration arise when time scales for diffusion and uptake are comparable, implying that models based on well mixed compartments are inaccurate. Effects of linear and nonlinear kinetics of drug uptake on cellular exposure are demonstrated. The drug doxorubicin is commonly used against solid tumors. Cellular exposure to doxorubicin is complicated in vivo by its transport and physicochemical properties. The Green's function method is used to describe the in vivo transport and kinetics of doxorubicin, using parameters derived from in vitro results. Simulations show agreement with observed in vivo distributions of doxorubicin in tumor tissue as well as in vitro kinetics, and provide a link between the two types of experimental observations. The method is applied to the class of cancer drugs called antibody-drug conjugates (ADCs) which consist of a humanized antibody conjugated to extremely toxic small molecular weight drugs. ADCs exhibit complex in vivo kinetics dependent on many design parameters. A phenomenon exhibited by ADCs is the bystander effect, i.e. non-targeted cell killing, which is difficult to analyze based on in vivo observations. Simulations results agree with the observed in vivo distribution of ADCs in tumor tissue and with experimentally observed bystander effects. In summary, the the models presented here provide a novel approach for simulating the complex transport and cellular uptake kinetics exhibited by several cancer drugs. The models give a mechanistic basis for predicting cellular exposure to drugs which can aid, explain, and direct experimental approaches for improving cancer treatment. Diffusion Doxorubicin Drug Transport Mathematical Models Pharmacokinetics Applied Mathematics Antibody-Drug Conjugates
4	Solid-phase synthesis of duocarmycin analogues and the effect of C-terminal substitution on biological activity Stephenson, M.J., Howell, L.A., O'Connell, M.A., Fox, K.R., Adcock, C., Kingston, J., Sheldrake, Helen M., Pors, Klaus, Collingwood, S.P., Searcey, M. 10 September 2015 (has links) Yes / The duocarmycins are potent antitumour agents with potential in the development of antibody drug conjugates (ADCs) as well as being clinical candidates in their own right. In this paper, we describe the synthesis of a duocarmycin monomer (DSA) that is suitably protected for utilisation in solid phase synthesis. The synthesis was performed on a large scale and the resulting racemic protected Fmoc-DSA subunit was separated by supercritical fluid chromatography (SFC) into the single enantiomers. Application to solid phase synthesis methodology gave a series of monomeric and extended duocarmycin analogues with amino acid substituents. The DNA sequence selectivity was similar to previous reports for both the monomeric and extended compounds. The substitution at the C-terminus of the duocarmycin caused a decrease in antiproliferative activity for all of the compounds studied. An extended compound containing an alanine at the C-terminus was converted to the primary amide or to an extended structure containing a terminal tertiary amine but this had no beneficial effects on biological activity. / MJS was funded by Novartis and UEA. We thank the EPSRC Mass Spectrometry Service, Swansea. We thank Richard Robinson and Julia Hatto at Novartis for help in the large scale synthesis.
5	Studies towards a second-generation synthesis of the aplyronines Anzicek, Nika January 2017 (has links) The aplyronines are a family of 24-membered macrolides of polyketide origin, isolated from the Japanese sea hare Aplysia kurodai. They exhibit an exceptional biological activity profile, acting through an actin and tubulin dual-targeting mechanism, with subnanomolar growth inhibitory potency against a diverse range of cancer cell lines. These characteristics render the aplyronines ideal payloads for antibody-drug conjugates but their prohibitively low natural abundance calls for an efficient total synthesis to overcome the supply issue. This dissertation describes the efforts towards developing a second-generation Paterson synthesis of the macrocyclic core of the aplyronines, focused on improving the scalability and selectivity of key transformations. Chapter 1 details the isolation, biological background and previous synthetic efforts towards the aplyronines to illustrate their therapeutic potential and the challenges associated with material sourcing by chemical synthesis. Chapter 2 presents the existing body of work on the aplyronine project within the Paterson group, highlighting the lessons learned over the past two decades and shortcomings to be addressed. Chapter 3 discusses a revised protecting group strategy towards the C1-C27 macrocyclic alcohol 159 with fewer manipulation steps. A refined reaction sequence featuring titanium aldol methodology and an enzymatic desymmetrisation process delivered multigram stocks of the C15-C27 aldehyde 161 upon scale- up, testifying to the robustness of the devised route. Synthesis of the C1-C14 northern fragment 253 closely followed the existing boron aldol approach with optimisation of the C11-C12 alkylation step, geared towards enhancing the regioselectivity. Chapter 4 describes the coupling of the two major fragments using an Horner-Wadsworth-Emmons reaction to assemble the C1-C27 backbone of the cyclic aplyronine core and suitably adjusted endgame steps to enable a one-step oxidative unmasking of the macrolactonisation sites. The first-generation intermediate 159 was accessed via site-specific Yamaguchi esterification and orthogonal deprotection of the C27 allyl carbonate. Discussion in Chapter 5 includes the appendage of the C28-C34 side chain 118, prepared by the known sequence, and suggestions for the future direction of the second-generation route with the outlook of linker appendage for the purposes of antibody-drug conjugate development. 547
6	Antibody conjugates : integrated approach towards selective, stable and controllable bioconjugation / Conjugués d'anticorps : approche intégrative pour une bioconjugaison plus sélective, stable et contrôlable Dovgan, Igor 21 September 2017 (has links) Au cours de la dernière décennie, les anticorps conjugués à des médicaments cytotoxiques ou des oligonucléotides ont acquis une grande attention dans la communauté scientifique en raison des propriétés uniques des anticorps, tels que leur long temps de circulation dans le sérum et leur sélectivité élevée par rapport à leur cible. Par exemple, les conjugués d'anticorps (ACs) sont de plus en plus appliqués en thérapie ciblée contre le cancer ou en bioimagerie. Par conséquent, le développement de méthodologies fiables pour la préparation des AC est actuellement en pleine expansion. Cependant, la conjugaison et la préparation contrôlables des ACs avec une structure définie rencontrent encore de nombreux obstacles en raison de l'excès élevé et de la variété des groupes réactifs dans la structure des anticorps, qui sont accessibles pour la conjugaison. En outre, les technologies de liaison actuelles sont basées sur la réaction de maléimide-thiol, produisant des adduits, qui sont instables dans le sang. Ce travail se concentre sur les approches chimiques pour la fonctionnalisation fiable des anticorps, qui permettent la préparation d'ACs stables présentant un ratio anticorps/principe actif bien défini. La première partie est consacrée à la conception et au développement du réactif maléimide-dioxane, solution auto-hydrolysable et stable dans le sérum, comme alternative à la chimie classique du maléimide. La deuxième partie est consacrée à l'évaluation de la réactivité sélective des différents acides aminés portés par les anticorps par spectrométrie de masse native à haute résolution. Finalement, une nouvelle technologie permettant d’obtenir des ACs stables avec un ratio anticorps/principe actif contrôlé est présentée au lecteur dans une 3ème partie. / Within the last decade, antibodies conjugated to cytotoxic drugs or oligonucleotides have gained a great attention in scientific community owing to the unique properties of the antibodies, such as their long circulation time in serum and high selectivity against their target. For instance, antibody conjugates (ACs) are increasingly applied for targeted cancer therapy or bioimaging. Consequently, the development of reliable methodologies for ACs preparation is currently of high demand. However, the controllable conjugation and preparation of ACs with defined structure are still challenging due to high excess and variety of reactive groups in antibody structure, which are accessible for conjugation. Moreover, current linker technologies are based on the maleimide-thiol reaction, yielding adducts, which are unstable during circulation in blood.This work is focused on chemical approaches for the reliable antibody functionalisation, which enable the preparation of stable ACs with well-defined payload to antibody ratios. The first part is devoted to design and development of maleimide-dioxane reagents as self-hydrolysable and serum-stable alternative to classical maleimide chemistry. The second part is dedicated to a screening approach for evaluation of residue-selective functionalities in reactions with an antibody using high resolution native mass spectrometry. Finally, in the third part the reader is introduced with a novel technology, which enables efficient preparation of stable ACs with a defined degree of conjugation and particularly mono-functionalisation of antibodies. Bioconjugation Conjugués d'anticorps Arginine Lysine Bioconjugation Antibody-drug conjugates Antibody-oligonucleotide conjugates Mono-functionalisation of proteins Arginine conjugation Lysine conjugation 547.7
7	Déterminants moléculaires de la pharmacocinétique des anticorps thérapeutiques / Molecular determinants of monoclonal antibody pharmacokinetics Brachet, Guillaume 04 December 2017 (has links) La pharmacocinétique (PK) des anticorps monoclonaux (mAbs) est sujette à d’importantes variations interindividuelles. Le récepteur néonatal au Fc des IgG (FcRn) et le statut immun à l’encontre de ces mAbs sont des déterminants de cette PK. La bioconjugaison des mAbs à des cytotoxiques entraîne une altération de leur PK. Nous montrons que le taux de couplage modifie l’affinité de ces espèces pour le FcRn à pH6. La proportion d’agrégats au sein des solutions d’anticorps armés augmente avec le taux de couplage et pourrait entraîner une altération de leur PK. Par ailleurs, cette agrégation est impliquée dans l’immunogénicité des mAbs, et nous avons donc cherché à identifier des acides aminés impliqués dans l’agrégation de mAbs indiqués en clinique. Il apparait que la nature biochimique de résidus des paratopes pourrait augmenter cette agrégation. Les anti-TNF- présentent très peu d'agrégats et figurent pourtant parmi les plus immunogènes chez l’Homme. Nous avons donc exploré le rôle des complexes immuns dans leur immunogénicité chez la souris. Il apparait que la présence du FcRn n’est pas à l’origine de l’immunisation contre ces mAbs, contrairement à celle des complexes immuns. Ces résultats donnent des pistes pour la production de mAbs plus efficients et mieux tolérés. / The pharmacokinetic (PK) profile of monoclonal antibodies (mAbs) shows interindividudal variability. The neonatal Fc receptor (FcRn) and the immounogenicity of these mAbs are determinative factors of mAb PK. Generation of antibody-drug-conjugates alters their PK profile. We show that the the affinity for FcRn at pH6 increases with the drug-to-mAb ratio, as does the amount of aggregates inside the mAb-drug-conjugate. The amount of aggregates could be responsible for an avidity effect towards FcRn. These aggregates are known to cause immunogenicity, so we studied biochemical determinants inside the aminoacid sequence of marketed mAbs. We show that the biochemical nature of some aminoacids inside the paratope has an impact on the amount of aggregation. Anti-TNF- mAbs show very little aggregation but are very immunogenic in humans. We studied the role of the formation of immune complexes in the immunization against anti-TNF- mAbs in mice, and showed that immune complexes, but not FcRn are essential in the immunization process against anti- TNF- mAbs. These results give leads towards the generation of more efficient, better tolerated mAbs. Pharmacocinétique Anticorps monoclonaux thérapeutiques Anticorps armés Récepteur néonatal au Fc des IgG Agrégats Complexes immuns Pharmacokinetics Therapeutic monoclonal antibodies Antibody-drug-conjugates Neonatal Fc receptor Aggregates Immune complexes
8	Optimisation de méthodes bidimensionnelles en ligne LCxLC-UV/MS et LCxSFC-UV pour l’analyse d’échantillons complexes / Optimization of on-line two-dimensional LCxLC-UV/MS and LCxSFC-UV methods for the analysis of complex matrices Sarrut, Morgan 17 October 2016 (has links) La chromatographie en phase liquide bidimensionnelle « comprehensive » en ligne (LCxLC) est une technique à très haut pouvoir de séparation. Après avoir établi son intérêt mais aussi les enjeux liés au développement de méthodes et les conditions expérimentales utilisées, une attention particulière est portée à l'optimisation des méthodes en LCxLC. Une procédure d'optimisation basée une méthode « Pareto-optimal » est décrite. Les conditions optimales prédites sont ensuite appliquées à la séparation RPLCxRPLC d'un mélange complexe de peptides et comparée avec la 1D-RPLC en termes de capacité de pics, temps d'analyse et facteur de dilution démontrant l'avantage fournit par la RPLCxRPLC. L'optimisation d'une méthode HICxRPLC-UV/MS en ligne permettant la caractérisation exhaustive d'un anticorps conjugué est réalisée soulignant, entre autres, la grande complémentarité entre les différents modes de détection employés en 1D et 2D.Enfin, la possibilité de développer un couplage RPLCxSFC est explorée dans le but d'augmenter l'espace de séparation pour des composés neutres. La méthode RPLCxSFC optimisée est comparée avec une séparation RPLCxRPLC optimisée pour l'analyse d'une bio-huile montrant qu'elle peut-être considérée comme une alternative crédible pour la séparation de tels échantillons / Comprehensive two-dimensional liquid chromatography is a powerful but complex separative technique. After detailing the interest of such a technique, the method development issues and the experimental conditions employed throughout this work, a particular attention is paid to the optimization of LCxLC methods. Accordingly an optimization procedure based on Pareto-optimal method is described. The predicted optimal conditions are then applied to experimental RPLCxRPLC separations of complex samples of peptides and compared with 1D-RPLC in terms of peak capacity, analysis time and sensitivity clearly showing the advantage of RPLCxRPLC approach.The optimization of a HICxRPLC-UV/MS method for the exhaustive characterization of an antibody-drug conjugate is achieved highlighting the high complementarity of the different detection modes used both in 1D and 2D. Finally, a proof of concept concerning the implementation of RPLCxSFC coupling is achieved with the aim of increasing the separation space coverage for neutral compounds. The optimized RPLCxSFC separation is then compared with an optimized RPLCxRPLC approach for the analysis of a bio-oil sample showing that RPLCxSFC is a credible alternative for the separation of such a sample LCxLC en ligne Peptides Anticorps conjugués (ADC) Biomolécules SFC RPLC HIC Spectrométrie de masse On-line LCxLC Peptides Antibody-drug conjugates (ADC) Biomolécules SFC RPLC HIC Mass spectrometry 543
9	STUDY FOR THE MECHANISM OF PROTEIN SEPARATION IN REVERSED-PHASE LIQUID CHROMATOGRAPHY Yun Yang (9179615) 28 July 2020 (has links) <p>Liquid chromatography coupling with mass spectrometry (LC/MS) plays an important role in pharmaceutical characterization because of its ability to separate, identify, and quantify individual compounds from the mixture. Polymer brush layer bonded to the silica surface is designed as a novel stationary phase to improve the LC resolution and MS compatibility. The polymer thickness can be controlled to shield the analyte from interacting with the active silanol on the surface and reduce peak tailing. The functional group of the polymer can be changed to tune the selectivity in different separation modes. </p><p> </p><p>Two projects on LC/MS method development for biomolecule characterization using polymer-shell column are discussed in this work. In the first project, a polymer-shell column is used for disulfide bonds and free thiol subspecies identification, which is a major type of structural heterogeneities in IgG1. Compared with commercial columns, the polymer-shell column is able to resolve the free thiol variants without the presence of trifluoroacetic acid and greatly improve the MS signal. In the second project, a polymer-shell column is used for characterizing the drug-loading profile for antibody-drug-conjugates (ADC) via online LC/MS. The separation employs a mobile phase of 50 mM ammonium acetate to keep the ADC intact, and a gradient of water/isopropanol for ADC elution. MS data show that all ADC species remained intact and native on the column. Positional isomers can be separated and identified with the new method as well. Furthermore, to understand the surface chemistry and protein separation behavior quantitatively, a chromatographic simulation study is performed. The result shows that protein separation in RPLC can be described by a bi-Langmuir adsorption isotherm with mixed-mode retention of strong and weak sites. Smaller fractions and lower equilibrium constant of the strong site, which is the active silanol, give less tailing for protein separation.</p> Liquid chromatography-mass spectrometry Liquid chromatography Reversed-phase chromatography Protein separation Monoclonal antibodies (mAbs) Antibody drug conjugates(ADC)
10	Solid-state Stability of Antibody-drug Conjugates Eunbi Cho (11192397) 28 July 2021 (has links) <p>Antibody-drug conjugates (ADCs) combine the cytotoxicity of traditional chemotherapy with the site-specificity of antibodies by conjugating payloads to antibodies with immunoaffinity. However, the conjugation alters the physicochemical properties of antibodies, increasing the risks of various types of degradation. The effects of common risk factors such as pH, temperature, and light on the stability of ADCs differ from their effects on monoclonal antibodies (mAb) due to these altered physicochemical properties. </p> <p>To date, ADC researchers have developed linkers with improved <i>in vivo</i> stability, and begun to understand the deconjugation mechanisms <i>in vivo</i>. In contrast, the <i>in vitro</i> stability of ADCs has not gained comparable attention. All nine of the U.S. FDA approved ADCs are lyophilized to minimize the potential for degradation. However, there are few studies on the solid-state stability of ADCs. To evaluate lyophilized solids, pharmaceutical development relies heavily on accelerated stability studies, which take months to determine the best formulation. Characterization methods that are often used orthogonally with accelerated studies include Fourier-transform infrared spectroscopy (FT-IR), Raman spectroscopy, near-infrared spectroscopy (NIR), differential scanning calorimetry (DSC), and x-ray powder diffraction (XRPD). Results from these methods are often poorly correlated with stability, however. Thus, stability evaluation of solid-state ADC products, and other recombinant protein drugs, is often a bottleneck in their development.</p> <p>To provide knowledge on how to improve the <i>in vitro</i> stability of lyophilized ADC formulations, the solid-state stability of ADC formulations with varying risk factors was studied in this dissertation project. The first study investigated interactions between an ADC and excipients in terms of solid-state stability enhancement. The second study investigated the process-driven instability of ADCs during lyophilization using various concentrations of ADCs. The first two studies incorporate a new method called solid-state hydrogen/deuterium exchange coupled with mass spectrometry (ssHDX-MS) as an analytical predictor of solid-state stability. The last study investigated the effects of pH on the stability of labile hydrazones, as a model for common linker chemistry used in ADCs. </p> Pharmaceutical Sciences antibody-drug conjugates solid-state stability solid-state hydrogen/deuterium exchange ssHDX linker stability aggregation accelerated stability studies ssHDX-MS characterization analytical in vitro stability physical stability

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