Physicochemical Stability of the Antibody−Drug Conjugate Trastuzumab-DM1: Changes due to Modification and Conjugation Processes

Wakankar, Aditya A.; Feeney, Maria; Rivera, Javier; Chen, Yan; Kim, Michael T.; Sharma, Vikas; Wang, Y. John

doi:10.1021/bc900434c

Cited by 170 publications

(167 citation statements)

References 18 publications

(29 reference statements)

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“…Inside of the cell, most linkers are labile; however, some are stable, requiring degradation of the antibody and linker to release the cytotoxic agent. Thus, linkers are a key component of antibody-conjugate structures (42)(43)(44)(45). Currently used linkers most frequently react with lysine side chains or sulfhydryls in the hinge regions of the antibody.…”

Section: Antibody-drug Conjugatesmentioning

confidence: 99%

Antibody Conjugate Therapeutics: Challenges and Potential

Teicher

Chari²

2011

Clinical Cancer Research

373

281

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Antibody conjugates are a diverse class of therapeutics consisting of a cytotoxic agent linked covalently to an antibody or antibody fragment directed toward a specific cell surface target expressed by tumor cells. The notion that antibodies directed toward targets on the surface of malignant cells could be used for drug delivery is not new. The history of antibody conjugates is marked by hurdles that have been identified and overcome. Early conjugates used mouse antibodies; cytotoxic agents that were immunogenic (proteins), too toxic, or not sufficiently potent; and linkers that were not sufficiently stable in circulation. Investigators have explored 4 main avenues using antibodies to target cytotoxic agents to malignant cells: antibody-protein toxin (or antibody fragment-protein toxin fusion) conjugates, antibody-chelated radionuclide conjugates, antibody-small-molecule drug conjugates, and antibody-enzyme conjugates administered along with small-molecule prodrugs that require metabolism by the conjugated enzyme to release the activated species. Only antibody-radionuclide conjugates and antibody-drug conjugates have reached the regulatory approval stage, and nearly 20 antibody conjugates are currently in clinical trials. The time may have come for this technology to become a major contributor to improving treatment for cancer patients.

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Section: Antibody-drug Conjugatesmentioning

confidence: 99%

Antibody Conjugate Therapeutics: Challenges and Potential

Teicher

Chari²

2011

Clinical Cancer Research

373

281

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“…As with any ligand binding assay, the biophysical properties (including charge, hydrophobicity, and solubility) and conformation of critical target reagents have profound effects on assay characteristics. Labeling and choice of assay buffers have been proven relevant for the use of mAbs as reagents in routine ADA immunoassays and are more critical now that the protein therapeutic in question has already been through one round (or more) of conjugation to a small-molecule drug (see (33,34) for examples of the consequences of conjugation on mAb biophysical properties). For example, if both conjugation and labeling chemistry utilize amine groups of lysine residues, the net positive charge of the doubly labeled ADC reagent may be reduced.…”

Section: Bioanalytical Strategies For Immunogenicity Assessmentmentioning

confidence: 99%

Immunogenicity of Antibody Drug Conjugates: Bioanalytical Methods and Monitoring Strategy for a Novel Therapeutic Modality

Hock

Thudium

Carrasco‐Triguero³

et al. 2014

AAPS J

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Abstract. Immunogenicity (the development of an adaptive immune response reactive with a therapeutic) is a well-described but unwanted facet of biotherapeutic development. There are commonly applied procedures for immunogenicity risk assessment, testing strategies, and bioanalysis. With some modifications, these can be applied to new biotherapeutic modalities. For novel therapies such as antibody-drug conjugates (ADCs), the unique structural components may contribute additional complexities to both immunologic responses and bioanalytical methods. US product inserts (USPIs) for two commercially available ADCs detail the incidence of immunogenicity; however, the body of literature on immunogenicity of ADCs is limited. We recently participated in a conference session on this topic (Annual meeting of the American Association of Pharmaceutical Scientists, held November 2013 in San Antonio, TX, USA. The meeting featured the Symposium: Immunogenicity Assessment for Novel Antibody Drug Conjugates, Nonclinical to Clinical) which prompted an effort to share our perspectives on how immunogenicity risk assessment, testing strategies, and bioanalytical methods can be adapted to reflect the complexity of ADC therapeutics.

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“…In addition, proper folding and stability of the CH3 domain could also contribute to the monomer-dimer equilibrium, 45 thus a stable CH3 heterodimer improves the homogeneity of the engineered antibody. From an application perspective, the next generation of antibody designs could very well involve bispecific antibodies that are themselves antibody drug conjugates, 46 and given that drug conjugation reactions tend to affect the stability and observed Tm of the parent antibody, 47 a more stable heterodimeric Fc can improve the manufacturability of these classes of therapeutics.…”

Section: Figure 1 (A)mentioning

confidence: 99%