Actinium-225 in Targeted Alpha-Particle Therapeutic Applications

Scheinberg, David A.; McDevitt, Michael R.

doi:10.2174/1874471011104040306

Cited by 140 publications

(124 citation statements)

References 49 publications

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“…71 Like GO and vadastuximab talirine, 225 Ac-lintuzumab ( 225 Ac-HuM195) is an ADC that binds CD33 and is rapidly internalized, liberating the radioisotope 225 Ac, which is retained inside the cell. 72 Frontline studies of 225 Ac-lintuzumab are ongoing, with phase 1 results of an ongoing phase 1/ 2 study showing significant clinical activity with minimal extramedullary toxicity when the ADC was given in combination with LDAC. Because all clinical responses occurred in the first treatment cycle, the authors concluded that LDAC did not contribute to response rates, and phase 2 development of the ADC as a single agent in untreated AML patients who are not candidates for induction chemotherapy is ongoing.…”

Section: Targeted Chemotherapy Deliverymentioning

confidence: 99%

The role of targeted therapy in the management of patients with AML

Perl

2017

Blood Advances

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Drug therapy for acute myeloid leukemia (AML) is finally undergoing major changes in 2017. This is due to the US Food and Drug Administration's approval of several new, targeted agents (midostaurin, enasidenib, and gemtuzumab ozogamicin). Paired with the recent approval of a novel liposomal formulation of daunorubicin/cytarabine (CPX-351/Vyxeos), the standard of care is changing rapidly in AML for subgroups. This review will focus on currently approved agents and promising novel agents in development and will highlight controversial areas in targeted treatment.

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Section: Targeted Chemotherapy Deliverymentioning

confidence: 99%

The role of targeted therapy in the management of patients with AML

Perl

2017

Blood Advances

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“…Only a few are considered useful as therapeutics agents. These include bismuth-213 (generator produced), 20 astatine-211 (cyclotron produced), 21 actinium-225 (generator produced) 22 and thorium-227 (generator produced). 23 These radiolabelled therapeutic agents transported by bio-vectors such as monoclonal antibodies can be utilized in the treatment of a variety of cancers such as lymphomas, leukaemia and melanomas.…”

Section: Radionuclides Targeting Cancermentioning

confidence: 99%

Application of Radionuclides and Antibody-Drug Conjugates to Target Cancer

Kitson¹

2014

Cancer Stud Mol Med Open J

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Radionuclide therapy and antibody-drug conjugates are used to locate and kill cancer cells by the utilisation of monoclonal antibodies. These bio-vectors are able to transport a cytotoxic drug payload and/or radiation in the form of alpha or beta particles to bind onto antigen specific cancer cells initiating apoptosis. This inaugural article aims to deliver a brief account of these targeted therapies in the treatment of oncological disease states such as leukaemia, non-Hodgkin's lymphoma, neuroendocrine tumours, breast cancer and prostate cancer bone metastases.

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“…The relative biological effectiveness is designed to relate the absorbed dose of the reference radiation (often low-LET delivered acutely) and absorbed dose of the test radiation (in this case high-LET α particles) that are required to cause equal biological effect (18): either a same surviving fraction of cells for cellular in vitro studies or a same measure of toxicity or therapeutic efficacy in organs or tumors, respectively. The basic equation that defines this concept is: (3) This principle is illustrated in Fig. 1, where a same given surviving fraction of cells from the same cell line is obtained after delivery of an absorbed dose from either a high-LET radiation such as an α particle (D H ) or a low-LET radiation (D L ), given as a single fraction.…”

Section: Conventional Definition Of Relative Biological Effectivenessmentioning

confidence: 99%

“…Advances in the targeted delivery of radionuclides and radionuclide conjugation chemistry, and the increased availability of alpha emitters appropriate for clinical use, have recently led to a resurgence of preclinical studies and a number of clinical trials using radiopharmaceuticals labeled with these radionuclides (1)(2)(3)(4)(5). The same characteristics that make these radiopharmaceuticals attractive for targeting disseminated disease, namely the high-linear energy transfer (LET) and short range (<80 μm in water) of the α particles, also render their dosimetry complex.…”

Section: Introductionmentioning

confidence: 99%

Redefining Relative Biological Effectiveness in the Context of the EQDX Formalism: Implications for Alpha-Particle Emitter Therapy

Hobbs¹,

Howell²,

Song³

et al. 2013

Radiation Research

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Alpha-particle radiopharmaceutical therapy (αRPT) is currently enjoying increasing attention as a viable alternative to chemotherapy for targeting of disseminated micrometastatic disease. In theory, αRPT can be personalized through pre-therapeutic imaging and dosimetry. However, in practice, given the particularities of α-particle emissions, a dosimetric methodology that accurately predicts the thresholds for organ toxicity has not been reported. This is in part due to the fact that the biological effects caused by α-particle radiation differ markedly from the effects caused by traditional external beam (photon or electron) radiation or β-particle emitting radiopharmaceuticals. The concept of relative biological effectiveness (RBE) is used to quantify the ratio of absorbed doses required to achieve a given biological response with alpha particles versus a reference radiation (typically a beta emitter or external beam radiation). However, as conventionally defined, the RBE varies as a function of absorbed dose and therefore a single RBE value is limited in its utility because it cannot be used to predict response over a wide range of absorbed doses. Therefore, efforts are underway to standardize bioeffect modeling for different fractionation schemes and dose rates for both nuclear medicine and external beam radiotherapy. Given the preponderant use of external beams of radiation compared to nuclear medicine in cancer therapy, the more clinically relevant quantity, the 2 Gy equieffective dose, EQD2(α/β), has recently been proposed by the ICRU. In concert with EQD2(α/β), we introduce a new, redefined RBE quantity, named RBE2(α/β), as the ratio of the two linear coefficients that characterize the α particle absorbed dose-response curve and the low-LET megavoltage photon 2 Gy fraction equieffective dose-response curve. The theoretical framework for the proposed new formalism is presented along with its application to experimental data obtained from irradiation of a breast cancer cell line. Radiobiological parameters are obtained using the linear quadratic model to fit cell survival data for MDA-MB-231 human breast cancer cells that were irradiated with either α particles or a single fraction of low-LET 137 Cs γ rays. From these, the linear coefficient for both the biologically effective dose (BED) and the EQD2(α/β) response lines were derived for fractionated irradiation. The standard RBE calculation, using the traditional single fraction reference radiation, gave RBE values that ranged from 2.4 for a surviving fraction of 0.82-6.0 for a surviving fraction of 0.02, while the dose-independent RBE2(4.6) value was 4.5 for all surviving fraction values. Furthermore, bioeffect modeling with RBE2(α/β) and EQD2(α/β) demonstrated ©2014 by Radiation Research Society. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript the capacity to predict the surviving fraction of cells irradiated with acute and fractionated low-LET radiation, α particles and chronic exponentially decreasing dose rates of low-...

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Actinium-225 in Targeted Alpha-Particle Therapeutic Applications

Cited by 140 publications

References 49 publications

The role of targeted therapy in the management of patients with AML

The role of targeted therapy in the management of patients with AML

Application of Radionuclides and Antibody-Drug Conjugates to Target Cancer

Redefining Relative Biological Effectiveness in the Context of the EQDX Formalism: Implications for Alpha-Particle Emitter Therapy

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