Tissue Distribution Studies of Protein Therapeutics Using Molecular Probes: Molecular Imaging

Williams, Simon‐Peter

doi:10.1208/s12248-012-9348-3

Cited by 46 publications

(47 citation statements)

References 70 publications

(62 reference statements)

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“…The same can be said for imaging studies which used a variety of probes (e.g., IR800 or 89 Zr). 23,24 A notable exception is the work by Alley et al using both double labeled methods ( 3 H antibody and a 14 C labeled MMAF payload) and more recently Cohen et al ( 89 Zr on the traztuzumab antibody and 131 I on the tubulysin payload) that allows for distinction of the payload-related distribution from that of the antibody. 9,25 Although the dual radiolabeled approach is an important tool, the ability to use LC-MS/MS methodology for payload distribution assessment is flexible and has the potential to be utilized in the discovery and screening side of ADC development as well as any potential clinical applicability.…”

Section: ■ Discussionmentioning

confidence: 99%

Preclinical Development of an anti-5T4 Antibody–Drug Conjugate: Pharmacokinetics in Mice, Rats, and NHP and Tumor/Tissue Distribution in Mice

et al. 2015

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The pharmacokinetics of an antibody (huA1)-drug (auristatin microtubule disrupting MMAF) conjugate, targeting 5T4-expressing cells, were characterized during the discovery and development phases in female nu/nu mice and cynomolgus monkeys after a single dose and in S-D rats and cynomolgus monkeys from multidose toxicity studies. Plasma/serum samples were analyzed using an ELISA-based method for antibody and conjugate (ADC) as well as for the released payload using an LC-MS/MS method. In addition, the distribution of the Ab, ADC, and released payload (cys-mcMMAF) was determined in a number of tissues (tumor, lung, liver, kidney, and heart) in two tumor mouse models (H1975 and MDA-MB-361-DYT2 models) using similar LBA and LC-MS/MS methods. Tissue distribution studies revealed preferential tumor distribution of cys-mcMMAF and its relative specificity to the 5T4 target containing tissue (tumor). Single dose studies suggests lower CL values at the higher doses in mice, although a linear relationship was seen in cynomolgus monkeys at doses from 0.3 to 10 mg/kg with no evidence of TMDD. Evaluation of DAR (drug-antibody ratio) in cynomolgus monkeys (at 3 mg/kg) indicated that at least half of the payload was still on the ADC 1 to 2 weeks after IV dosing. After multiple doses, the huA1 and conjugate data in rats and monkeys indicate that exposure (AUC) increases with increasing dose in a linear fashion. Systemic exposure (as assessed by Cmax and AUC) of the released payload increased with increasing dose, although exposure was very low and its pharmacokinetics appeared to be formation rate limited. The incidence of ADA was generally low in rats and monkeys. We will discuss cross species comparison, relationships between the Ab, ADC, and released payload exposure after multiple dosing, and insights into the distribution of this ADC with a focus on experimental design as a way to address or bypass apparent obstacles and its integration into predictive models.

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Section: ■ Discussionmentioning

confidence: 99%

Preclinical Development of an anti-5T4 Antibody–Drug Conjugate: Pharmacokinetics in Mice, Rats, and NHP and Tumor/Tissue Distribution in Mice

et al. 2015

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“…Selecting a suitable radionuclide generally starts by matching the serum half-life of the mAb or antibodyrelated therapeutic and the physical half-life of the radionuclide. This step is essential to ensure that radioactivity can be detected long enough for the drug to reach its target while minimizing the duration of exposure to harmful radiation (6). The serum half-life mainly depends on the structure and size of the mAb or antibody-related therapeutic.…”

Section: Chelation and Radiolabeling For Molecular Antibody Imagingmentioning

confidence: 99%

Theranostics Using Antibodies and Antibody-Related Therapeutics

et al. 2017

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In theranostics, radiolabeled compounds are used to determine a treatment strategy by combining therapeutics and diagnostics in the same agent. Monoclonal antibodies (mAbs) and antibody-related therapeutics represent a rapidly expanding group of cancer medicines. Theranostic approaches using these drugs in oncology are particularly interesting because antibodies are designed against specific targets on the tumor cell membrane and immune cells as well as targets in the tumor microenvironment. In addition, these drugs are relatively easy to radiolabel. Noninvasive molecular imaging techniques, such as SPECT and PET, provide information on the whole-body distribution of radiolabeled mAbs and antibodyrelated therapeutics. Molecular antibody imaging can potentially elucidate drug target expression, tracer uptake in the tumor, tumor saturation, and heterogeneity for these parameters within the tumor. These data can support drug development and may aid in patient stratification and monitoring of the treatment response. Selecting a radionuclide for theranostic purposes generally starts by matching the serum half-life of the mAb or antibody-related therapeutic and the physical half-life of the radionuclide. Furthermore, PET imaging allows better quantification than the SPECT technique. This information has increased interest in theranostics using PET radionuclides with a relatively long physical half-life, such as 89 Zr. In this review, we provide an overview of ongoing research on mAbs and antibodyrelated theranostics in preclinical and clinical oncologic settings. We identified 24 antibodies or antibody-related therapeutics labeled with PET radionuclides for theranostic purposes in patients. For this approach to become integrated in standard care, further standardization with respect to the procedures involved is required.

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“…[25][26][27] 99m Tc is the most widely used radioisotope for SPECT imaging because of its ideal physical properties (Half-life: 6.02 h, γ-Energy: 141 keV (89 %)) and easy availability by a generator system. [28,29] In general, reduced 99m Tc can be combined with a bifunctional chelating agent, such as DTPA (diethylenetriaminepentaacetic acid) and HYNIC (2-hydrazinonicotinic acid), or other chemical groups (such as COO − , OH, NH 2 , and SH). PEI is known for its potential in eliminating metal ions from wastewater by coordination of metal ions with secondary or tertiary amino groups in PEI.…”

Section: Doi: 101002/adma201601064mentioning

confidence: 99%

Superfluorinated PEI Derivative Coupled with ^99mTc for ASGPR Targeted ¹⁹F MRI/SPECT/PA Tri‐Modality Imaging

et al. 2016

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Fluorinated polyethylenimine derivative labeled with radionuclide (99m) Tc is developed as a (19) F MRI/SPECT/PA multifunctional imaging agent with good asialoglycoprotein receptors (ASGPR)-targeting ability. This multifunctional agent is safe and suitable for (19) F MRI/SPECT/PA imaging and has the potential to detect hepatic diseases and to assess liver function, which provide powerful support for the development of personalized and precision medicine.

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Tissue Distribution Studies of Protein Therapeutics Using Molecular Probes: Molecular Imaging

Cited by 46 publications

References 70 publications

Preclinical Development of an anti-5T4 Antibody–Drug Conjugate: Pharmacokinetics in Mice, Rats, and NHP and Tumor/Tissue Distribution in Mice

Preclinical Development of an anti-5T4 Antibody–Drug Conjugate: Pharmacokinetics in Mice, Rats, and NHP and Tumor/Tissue Distribution in Mice

Theranostics Using Antibodies and Antibody-Related Therapeutics

Superfluorinated PEI Derivative Coupled with ^99mTc for ASGPR Targeted ¹⁹F MRI/SPECT/PA Tri‐Modality Imaging

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Tissue Distribution Studies of Protein Therapeutics Using Molecular Probes: Molecular Imaging

Cited by 46 publications

References 70 publications

Preclinical Development of an anti-5T4 Antibody–Drug Conjugate: Pharmacokinetics in Mice, Rats, and NHP and Tumor/Tissue Distribution in Mice

Preclinical Development of an anti-5T4 Antibody–Drug Conjugate: Pharmacokinetics in Mice, Rats, and NHP and Tumor/Tissue Distribution in Mice

Theranostics Using Antibodies and Antibody-Related Therapeutics

Superfluorinated PEI Derivative Coupled with 99mTc for ASGPR Targeted 19F MRI/SPECT/PA Tri‐Modality Imaging

Contact Info

Product

Resources

About

Superfluorinated PEI Derivative Coupled with ^99mTc for ASGPR Targeted ¹⁹F MRI/SPECT/PA Tri‐Modality Imaging