Antitumor Immunity Induced after α Irradiation

Gorin, Jean‐Baptiste; Ménager, Jérémie; Gouard, Sébastien; Maurel, Catherine; Guilloux, Yannick; Faivre-Chauvet, Alain; Morgenstern, Alfred; Bruchertseifer, Frank; Chérel, Michel; Davodeau, François; Gaschet, Joëlle

doi:10.1016/j.neo.2014.04.002

Cited by 71 publications

(63 citation statements)

References 41 publications

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“…22 It turned out that the unsuspected ability of doxorubicin (an anthracycline employed for the treatment of various carcinomas) to trigger ICD as a standalone intervention, hence converting dying cancer cells into a vaccine that is efficient in the absence of adjuvants, is shared by a relatively restricted set of lethal triggers. [28][29][30][31][32][33] These include, but perhaps are not limited to, mitoxantrone and epirubicin (2 other anthracyclines currently used in the clinic), [34][35][36][37] bleomycin (a glycopeptide antibiotic endowed with antineoplastic properties), 38 oxaliplatin (a platinum derivative generally employed against colorectal carcinoma), [39][40][41][42] cyclophosphamide (an alkylating agent approved for the treatment of neoplastic and autoimmune conditions), [43][44][45][46][47][48] etoposide (a topoisomerase inhibitor currently used for the treatment of several neoplasms) combined with the chemical inhibitor of glycolysis 2-deoxyglucose, 49,50 patupilone (a microtubular inhibitor that has not yet been approved for use in humans), [51][52][53] septacidin (an antifungal antibiotic produced by Streptomyces fibriatus) 54,55 specific forms of radiation therapy, 34,[56][57][58][59][60][61][62][63][64] photodynamic therapy (a clinically approved antican...…”

Section: Introductionmentioning

confidence: 99%

Consensus guidelines for the detection of immunogenic cell death

et al. 2014

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Section: Introductionmentioning

confidence: 99%

Consensus guidelines for the detection of immunogenic cell death

et al. 2014

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“…The mechanism of this effect is not fully understood but is hypothesized to result from extracellular reactive oxygenated species, chromosomal instabilities, or other abnormalities. Finally, the abscopal effect, resulting from a radiation-induced immune response, is characterized by a therapeutic response in remote lesions (9). Importantly, compared with b-particle radiotherapy, which relies mainly on the formation of reactive oxygen species, the cell-killing efficiency of a-particles was shown to be independent of cellular oxygenation (10).…”

Section: α-Emitting Isotope Radiochemistrymentioning

confidence: 99%

α-Emitters for Radiotherapy: From Basic Radiochemistry to Clinical Studies—Part 1

et al. 2018

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Learning Objectives: On successful completion of this activity, participants should be able to (1) cite α-emitter families available for therapeutic use and understand their current production limit; (2) consider radiation safety concerns when handling α-emitters; and (3) overcome radiolabeling and daughter redistribution hurdles with the approaches described in this educational review. CME Credit: SNMMI is accredited by the Accreditation Council for Continuing Medical Education (ACCME) to sponsor continuing education for physicians. SNMMI designates each JNM continuing education article for a maximum of 2.0 AMA PRA Category 1 Credits. Physicians should claim only credit commensurate with the extent of their participation in the activity. For CE credit, SAM, and other credit types, participants can access this activity through the SNMMI website (http://www.snmmilearningcenter.org) through June 2021.With a short particle range and high linear energy transfer, α-emitting radionuclides demonstrate high cell-killing efficiencies. Even with the existence of numerous radionuclides that decay by α-particle emission, only a few of these can reasonably be exploited for therapeutic purposes. Factors including radioisotope availability and physical characteristics (e.g., half-life) can limit their widespread dissemination. The first part of this review will explore the diversity, basic radiochemistry, restrictions, and hurdles of α-emitters. Radi onuclide strategies for curative therapy, disease control, or palliation are positioned to constitute a major portion of nuclear medicine. The range of available therapeutic radioisotopes, including a, b, or Auger electron emission, has considerably expanded over the last century (1). Matching the particle decay pathway, effective range, and relative biological effectiveness to tumor mass, size, radiosensitivity, and heterogeneity is the primary consideration for maximizing therapeutic efficacy. b-emitting radioisotopes have the longest particle pathlength (#12 mm) and lowest linear energy transfer (LET) (;0.2 keV/mm), supporting their effectiveness in medium to large tumors (Fig. 1). Although the long b-particle range is advantageous in evenly distributing radiation dose in heterogeneous tumors, it can also result in the irradiation of healthy tissue surrounding the tumor site. Conversely, Auger electrons have high LET (4-26 keV/mm) but a limited pathlength of 2-500 nm that restricts their efficacy to single cells, thus requiring the radionuclide to cross the cell membrane and reach the nucleus. Finally, a-particles have a moderate pathlength (50-100 mm) and high LET (80 keV/mm) that render them especially suitable for small neoplasms or micrometastases. A recent clinical study highlighted the ability of a-radiotherapy to overcome treatment resistance to b-particle therapy, prompting a paradigm shift in the approach toward radionuclide therapy (2).For optimized therapeutic efficacy, the a-cytotoxic payload is expected to accumulate selectively in diseased tissue and deliver a suf...

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“…À la surface des cellules tumorales, les molécules qui peuvent être modifiées par de telles doses de rayonnements ionisants correspondent aux antigènes associés aux tumeurs, aux molécules SYNTHÈSE REVUES DAMP (danger associated molecular pattern) comme la protéine de choc thermique Hsp70 et HMGB1 (highmobility group box 1), une protéine constitutive de la chromatine qui joue un rôle dans l'inflammation, comme cela se produit dans les mécanismes de mort immunogène [42,43]. Ces DAMP permettent, entre autre, l'activation des cellules dendritiques pour le développement de l'immunité antitumorale dépendante des cellules T, ainsi que la mise en place d'une mémoire immunitaire [41]. Cette étude démontre de nouvelles propriétés sur le mécanisme d'action des particules α ainsi que de la RITα.…”

Section: Le Cas Des Particules Alphaunclassified

“…Notre équipe a étudié les effets du bismuth-213 sur l'immunogénicité d'un modèle d'adénocarcinome colique murin (MC-38), dans la souris immunocompétente C57BL/6 [41]. L'irradiation α de cellules tumorales par le bismuth-213 permet, dans notre modèle, l'induction d'une immunité antitumorale durable et spécifique.…”

Section: (➜)unclassified

Radio-immunothérapie alpha

Ménager¹,

Gorin²,

Fichou³

et al. 2016

Med Sci (Paris)

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> La radioimmunothérapie alpha (RITα) est une thérapie anticancéreuse vectorisée utilisant généralement un anticorps monoclonal spécifique d'un antigène tumoral couplé à un émetteur de particules α. Les émetteurs α représentent un outil idéal pour éradiquer les tumeurs disséminées ou les métastases. De récentes données démontrent que les rayonnements ionisants, en plus de leur cytotoxicité directe, peuvent aussi induire une immunité antitumorale efficace. Les effets biologiques de l'irradiation pourraient donc être utilisés pour potentialiser la réponse à différents types d'immunothérapie, et ainsi ouvrir la voie au développement de nouvelles thérapies combinant RITα et immunothérapies. < radionucléide. Le choix du radionucléide repose sur des considérations pratiques (le coût, la disponibilité, le type de techniques de radiomarquage et la facilité d'utilisation), le type d'émission du radioélément, le transfert d'énergie linéique (TEL : quantité d'énergie transférée au milieu par la particule incidente, par unité de longueur de la trajectoire en keV 1 /µm) et la demi-vie physique du radioisotope (durée nécessaire pour que la moitié des noyaux radioactifs d'une source se soient désintégrés) [2]. Cette dernière doit être, autant que possible, en adéquation avec la pharmacocinétique du vecteur utilisé, afin de délivrer la plus grande dose possible de radioactivité à la tumeur après l'injection. Une demi-vie trop courte entraînera un nombre élevé de désintégrations avant d'atteindre la cible. À l'inverse, une demi-vie trop longue engendrera un grand nombre de désintégrations du radionucléide pendant la phase d'éli-mination du vecteur, rendant le radioimmunoconjugué plus toxique. La demi-vie doit également être compatible avec les applications cliniques et la prise en charge du patient. Ainsi, le temps nécessaire au transfert du radionucléide du site de production jusqu'à l'hôpital, 1 1 keV (kiloélectronvolts) = 10 3 eV ; 1 MeV (megaélectonvolts) = 10 6 eV.

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Antitumor Immunity Induced after α Irradiation

Cited by 71 publications

References 41 publications

Consensus guidelines for the detection of immunogenic cell death

Consensus guidelines for the detection of immunogenic cell death

α-Emitters for Radiotherapy: From Basic Radiochemistry to Clinical Studies—Part 1

Radio-immunothérapie alpha

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