DOCSLIB.ORG

Published Data in Intrahepatic Cholangiocarcinoma

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Published Data in Intrahepatic Cholangiocarcinoma Published Data in Intrahepatic Cholangiocarcinoma The following tables summarize the prospective and retrospective studies on the use of SIR-Spheres Y-90 resin microspheres in the treatment of intrahepatic cholangiocarcinoma. Tumor response and/or survival results are listed accordingly. For studies in which multiple tumor types were investigated, outcomes include all tumor types, unless otherwise noted. Prospective studies Median Survival Treatment/Line of Therapy Median survival N (n) ORRa SDa From Treatment Reference (n) from diagnosis (or PFS) SIR-Spheresb ≥1st line (45); 61 nr nr PFS: 2.8 mo 8.7 mo White, 2019 TheraSpherec ≥1st line (16) SIR-Spheres 1st line (2) 82.3% 17.6% 17 14.8 mod,e nr Filippi, 2015 SIR-Spheres ≥2nd line (15) (PET) (PET) 21 0%; SIR-Spheres ≥2nd line (21) nr 16.3 mo nr Camacho, 2014 37.5%, (mRECIST) SIR-Spheres ≥2nd line (19) 19 11% 68% 11.5 mo 25.1 mo Rafi, 2013 SIR-Spheres 1st line (6); SIR-Spheres ≥2nd line (20); 23 22% 65% 11.7 mo 36.6 mo Haug, 2011 follow-up MRI available for 23 patients SIR-Spheres 1st line (6); 25 24% 48% 9.3 mo 20.4 mo Saxena, 2010 SIR-Spheres 2nd line (19) Retrospective studies Median Survival Treatment/Line of Therapy Median survival N (n) ORRa SD From Treatment Reference (n) from diagnosis (or PFS) SIR-Spheres ≥2nd line 9 100%c nr 16.5±1.4 mo nr Filippi, 2019 SIR-Spheres 1st line PFS: 2.4 mo (2 HCC-CC, 13 HCC); 154; mRECIST: mRECIST: (HCC-CC); TheraSphere 1st line 14.5 mo HCC-CC (10), 30% (HCC-CC) 30% (3/10 HCC-CC) 7.4 mo (HCC; (4 HCC); (HCC-CC); Huang, 2019 HCC (124), 71% (HCC; P=0.02) 24% (26/107 HCC) P <0.0001); Y-90 microspheres, nr (HCC and PSM HCC (20) 50% (PSM HCC; 35% (7/20 PSM 6.0 mo unspecified type (3 PSM PSM HCC) P=0.35) HCC) (PSM HCC; HCC) P=0.017) Other LRTs 1st line SIR-Spheres >1st line (58) 58 nr nr nr 10.3 mo Levillain, 2019 All tumor types (38) 11.1% (PR; HCC HCC (23); group) 83.3% (HCC group) NETLM (7); 42.9% (PR; non- 57.1% (non-HCC 14.4 mo (HCC CRCLM (3); HCC group) group) group) SIR-Spheres ≥2nd line (38) ICC (2); 0% (PR, qEASL; 94.4% (qEASL; HCC nr Schobert, 2019 19.0 mo (non- melanoma LM (1); HCC group) group) HCC group) prostate cancer 28.6% (PR, 71.4% (qEASL; LM (1); qEASL; non-HCC non-HCC group) leiomyosarcoma group) LM (1) SIR-Spheres 1st line (21) 21 4.8% (PR) 42.9% nr 15.0 mo Reimer, 2018 Median Survival Treatment/Line of Therapy Median survival N (n) ORRa SD From Treatment Reference (n) from diagnosis (or PFS) 33.6 mo SIR-Spheres and SIR-Spheres ≥1st line (9) TheraSphere or 17 nr nr nr Shaker, 2018 PFS: 15.6 mo TheraSphere ≥1st line (8) SIR-Spheres; 2.4 mo TheraSphere All tumor types SIR-Spheres ≥1st line (366) 366f nr nr 11.4 mo nr Ingrisch, 2017 CC (35) SIR-Spheres 2nd line (24) 24 36.4% (PR) 45.5% 9.0 mo 24.0 mo Jia, 2017 All tumor types 389 Total 11.7 mog; CRCLM (136); CRCLM 9.1 mo; HCC (66); HCC 12.7 mo; SIR-Spheres ≥2nd line (389) NETLM (56); 22% 41% NETLM na; nr Paprottka, 2017 BCLM (40); BCLM 7.5 mo; CC (35); CC 14.1 mo; LM from other other nr cancers (56) 9.1 mo SIR-Spheres SIR-Spheres ≥1st line (17) 11.5% 61.5% and or 26.1 mo 29 PR, SIR-Spheres SIR-Spheres TheraSphere TheraSphere ≥1st line (12); SIR-Spheres and Swinburne, 2017 and TheraSphere and TheraSphere 7.5 mo SIRT 1st line (8); TheraSphere SIR-Spheres; SIRT ≥2nd line (21) 13.9 mo TheraSphere SIR-Spheres 1st line (4); 15%; 30%; 23 17.9 mo nr Mosconi, 2016 ≥2nd line (19) 45% (mRECIST) 15% (mRECIST) SIR-Spheres 1st line (4); 16 31% nr 9.6 mog nr Soydal, 2016 SIR-Spheres 2nd line (12) SIR-Spheres ≥2nd line (33) 33 36.4% 51.5% 22.0 mo 43.7 mo Hoffmann, 2012 In an effort to facilitate the review of data in this table, data originally reported as days/weeks were converted to months. BCLM: breast cancer liver metastases; CC: cholangiocarcinoma (as defined by the study authors); CRCLM: colorectal cancer liver metastases; HCC: hepatocellular carcinoma; HCC-CC: hepatocellular carcinoma-cholangiocarcinoma; ICC: intrahepatic cholangiocarcinoma (as defined by the study authors); LM: liver metastases; LRT: locoregional therapy; mo: months; mRECIST: modified Response Evaluation Criteria In Solid Tumors; n/a: not applicable; NETLM: neuroendocrine tumor liver metastases; nr: not reported; ORR: objective response rate (complete response [CR] + partial response [PR]); PERCIST: Positron Emission Tomography Response Criteria In Solid Tumors; PFS: progression- free survival; PR: partial response evaluated only; PSM: propensity score–matched; qEASL: Quantitative European Association for the Study of the Liver criteria; SD: stable disease; SIRT: selective internal radiation therapy. a. By RECIST unless otherwise indicated. b. SIR-Spheres Y-90 resin microspheres. c. TheraSphere Yttrium-90 Glass Microspheres. d. By PERCIST. e. Months calculated from weeks using Google calculator: 1 week = 0.230137 months. f. Data represent a subset of data from Paprottka 2017. g. Months calculated from days using Google calculator: 1 day = 0.0328767 months. References: 1. White J et al. J Vasc Interv Radiol 2019; 30: 1185–1192. 2. Filippi L et al. Nucl Med Biol 2015; 42: 59–64. 3. Camacho JC et al. J Vasc Interv Radiol 2014; 25: 256–265. 4. Rafi S et al. Cardiovasc Intervent Radiol 2013; 36: 440–448. 5. Haug AR et al. Eur J Nucl Med Mol Imaging 2011; 38: 1037–1045. 6. Saxena A et al. Ann Surg Oncol 2010; 17: 484–491. 7. Filippi L et al. Cancer Biother Radiopharm. Published online: February 13, 2019. (doi:10.1089/cbr.2018.2718). 8. Huang YH et al. J Vasc Interv Radiol 2019; 30: 1317–1324. 9. Levillain H et al. Eur J Nucl Med Mol Imaging 2019; 46: 2270–2279. 10. Schobert I et al. J Nucl Med Published Online: January 17, 2019. (doi:10.2967/jnumed.118.219691). 11. Reimer P et al. Cardiovasc Intervent Radiol Published Online: January 17, 2018. (doi:10.1007/s00270-017-1871-2). 12. Shaker TM et al. Am J Surg Published Online: February 2, 2018. (doi:10.1016/j.amjsurg.2017.11.022). 13. Ingrisch M et al. J Nuc Med Published Online: November 16, 2017.(doi:10.2967/jnumed.117.200758). 14. Jia Z et al. J Cancer Res Clin Oncol 2017; 143: 481–489. 15. Paprottka KJ et al. Eur J Nucl Med Mol Imaging 2017; 44: 1185–1193. 16. Swinburne NC et al. Cancer Biother Radiopharm 2017; 32: 161–168. 17. Mosconi C et al. Br J Cancer 2016; 115: 297–302. 18. Soydal C et al. Ann Nucl Med 2016; 30: 29–34. 19. Hoffmann RT et al. Cardiovasc Intervent Radiol 2012; 35: 105–116. SIR-Spheres® is a registered trademark of Sirtex SIR-Spheres Pty Ltd Sirtex Medical Europe GmbH Last update with data identified through September 30, 2019. Joseph-Schumpeter-Allee 33, 53227 Bonn, Germany 219-EUA-0919 www.sirtex.com.
Load more

Recommended publications
  • Investigation Study Radiation Profile on a 20 Gbq Therasphere Dose Vial
    Attachment 14 NUCLEAR MEDICINE M Nordion KANATA OPERATIONS INVESTIGATION STUDY PD99099003.08 Page No: I of 4 Investigation Study Radiation Profile on a 20 GBq TheraSphere Dose Vial I Signatures Prepared by: Date: ý - Al -; Approved by:. Date: 2•-O--c "Y (Richard Decaire CAHT) Document History Date Version''• •Comments Prepared by . Reviewed by Approved by PD99099003.08 Page Investigation No: 2 of 4 Study Radiation Profile on a 20 GBq TheraSphere Dose Vial 1. INTRODUCTION The United States Nuclear Regulatory Commission had requested information to support MDS Nordion application for the registration of TheraSphere. This request is contained in a letter dated November 23, 1999 from a Dr John P. Jankovich. This report contains data collected to address question 7 parts a, b, and c. The question poised is as follows: "Regarding external radiation levels, NRC needs information on the device itself, not on the radiation levels around the patient as addressed in the application. Therefore, please specify: a. External radiation levels around the lucite vial containing the maximum dose of 20 GBq (540 mCi). Provide the data, preferably, at the surface, and at 5, 30, and 100 cm. If there are no meaningful readings at these locations, please state so. b. Provide similar external radiation levels, if any, outside the lead pot with the lucite vial inside containing a maximum dose of microspheres. c. Please specify the instrument which you used to perform the radiation profile measurements by listing the instrument manufacturers, model numbers, calibration dates, sensitivity, etc." To address these questions, information was provided from previous development work.
    [Show full text]
  • 3Rd Quarter 2001 Bulletin
    In This Issue... Promoting Colorectal Cancer Screening Important Information and Documentaion on Promoting the Prevention of Colorectal Cancer ....................................................................................................... 9 Intestinal and Multi-Visceral Transplantation Coverage Guidelines and Requirements for Approval of Transplantation Facilities12 Expanded Coverage of Positron Emission Tomography Scans New HCPCS Codes and Coverage Guidelines Effective July 1, 2001 ..................... 14 Skilled Nursing Facility Consolidated Billing Clarification on HCPCS Coding Update and Part B Fee Schedule Services .......... 22 Final Medical Review Policies 29540, 33282, 67221, 70450, 76090, 76092, 82947, 86353, 93922, C1300, C1305, J0207, and J9293 ......................................................................................... 31 Outpatient Prospective Payment System Bulletin Devices Eligible for Transitional Pass-Through Payments, New Categories and Crosswalk C-codes to Be Used in Coding Devices Eligible for Transitional Pass-Through Payments ............................................................................................ 68 Features From the Medical Director 3 he Medicare A Bulletin Administrative 4 Tshould be shared with all General Information 5 health care practitioners and managerial members of the General Coverage 12 provider/supplier staff. Hospital Services 17 Publications issued after End Stage Renal Disease 19 October 1, 1997, are available at no-cost from our provider Skilled Nursing Facility
    [Show full text]
  • Variations in the Practice of Molecular Radiotherapy and Implementation Of
    Sjögreen Gleisner et al. EJNMMI Physics (2017) 4:28 EJNMMI Physics DOI 10.1186/s40658-017-0193-4 ORIGINAL RESEARCH Open Access Variations in the practice of molecular radiotherapy and implementation of dosimetry: results from a European survey Katarina Sjögreen Gleisner1* , Emiliano Spezi2, Pavel Solny3, Pablo Minguez Gabina4, Francesco Cicone5, Caroline Stokke6, Carlo Chiesa7, Maria Paphiti8, Boudewijn Brans9, Mattias Sandström10, Jill Tipping11, Mark Konijnenberg12 and Glenn Flux13 * Correspondence: [email protected] Abstract 1Department of Medical Radiation Physics, Clinical Sciences Lund, Background: Currently, the implementation of dosimetry in molecular radiotherapy Lund University, Lund, Sweden (MRT) is not well investigated, and in view of the Council Directive (2013/59/Euratom), Full list of author information is there is a need to understand the current availability of dosimetry-based MRT in clinical available at the end of the article practice and research studies. The aim of this study was to assess the current practice of MRT and dosimetry across European countries. Methods: An electronic questionnaire was distributed to European countries. This addressed 18 explicitly considered therapies, and for each therapy, a similar set of questions were included. Questions covered the number of patients and treatments during 2015, involvement of medical specialties and medical physicists, implementation of absorbed dose planning, post-therapy imaging and dosimetry, and the basis of therapy prescription. Results: Responses were obtained from 26 countries and 208 hospitals, administering in total 42,853 treatments. The most common therapies were 131I-NaI for benign thyroid diseases and thyroid ablation of adults. The involvement of a medical physicist (mean over all 18 therapies) was reported to be either minority or never by 32% of the responders.
    [Show full text]
  • Implantable Beta-Emitting Microspheres for Treatment of Malignant Tumors
    UnitedHealthcare® Commercial Medical Policy Implantable Beta-Emitting Microspheres for Treatment of Malignant Tumors Policy Number: 2021T0445S Effective Date: August 1, 2021 Instructions for Use Table of Contents Page Related Commercial Policy Coverage Rationale ........................................................................... 1 • Abnormal Uterine Bleeding and Uterine Fibroids Documentation Requirements......................................................... 1 Definitions ........................................................................................... 2 Community Plan Policy Applicable Codes .............................................................................. 2 • Implantable Beta-Emitting Microspheres for Treatment of Malignant Tumors Description of Services ..................................................................... 3 Clinical Evidence ............................................................................... 3 Medicare Advantage Coverage Summary U.S. Food and Drug Administration ..............................................15 • Brachytherapy Procedures References .......................................................................................15 Policy History/Revision Information..............................................18 Instructions for Use .........................................................................19 Coverage Rationale Transarterial radioembolization (TARE) using yttrium-90 (90Y) microspheres is proven and medically necessary for the following: • When used
    [Show full text]
  • Of Richard Martin on Yttrium-90 Microsphere Brachytherapy
    Page 1 of 1 As of: 2/8/18 2:05 PM Received: February 08, 2018 Status: Pending~Post PUBLIC SUBMISSION Tracking No. lk2-91du-ys8n Comments Due: February 08, 2018 Submission Type: Web Docket: NRC-2017-0215 Yttrium-90 Microsphere Brachytherapy Sources and Devices Therasphere and SIR-Spheres Comment On: NRC-2017-0215-0024 Yttrium-90 Microsphere Brachytherapy Sources and Devices TheraSphere and SIR-Spheres; Draft Guidance; Extension of Comment Period Document: NRC-2017-0215-DRAFT-0132 Comment on FR Doc# 2017-28271 Submitter Information Name: Richard Martin Organization: American Association of Physicists in Medicine General Comment See attached file(s) Attachments AAPM Comment NRC Y-90 Guidance Final RM SUNSI Review Complete Template= ADM - 013 E-RIDS= ADM-03 · Add= l.1 SCA.\), m )11 1lJ:. C) lch) K~~-t.ri11"1 MP.P ( Kris!) https://www.fdms.gov/fdms/getcontent?objectld=0900006482f01e40&format=xml&showorig=false 02/08/2018 ''l, :~:~~.::. ' ••• ·: ·.~ ••~ ~ •'<",• ··:. : •• · 1 • ~ • • • • • ' • • • j db AMERICAN ASSOCIATION ~l7ef PHYSICISTS IN MEDICINE February 8, 2018 May Ma Office of Administration Mail Stop: OWFN-2-A13 U.S. Nuclear Regulatory Commission Washington, DC 20555-0001 RE: Request for Comment: Yttrium-90 Microsphere Brachytherapy Sources and Devices TheraSphere and SIR-Spheres Draft Guidance (NRC-2017-0215) Dear Ms. Ma: The American Association of Physicists in Medicine (AAPM)1 is pleased to submit comments to the U.S. Nuclear Regulatory Commission (NRC) regarding Yttrium-90 Microsphere Brachytherapy Sources and Devices TheraSphere and SIR-Spheres Draft Licensing Guidance (Revision 10). The AAPM commends the NRC on its work in providing the NRC with a set of standard criteria for evaluating a medical use license application for the use of TheraSpheres and SIR-Spheres.
    [Show full text]
  • MG Selective Internal Radiation Therapy
    Selective Internal Radiation Therapy Last Review Date: May 7, 2021 Number: MG.MM.RA.12d Medical Guideline Disclaimer Property of EmblemHealth. All rights reserved. The treating physician or primary care provider must submit to EmblemHealth the clinical evidence that the patient meets the criteria for the treatment or surgical procedure. Without this documentation and information, EmblemHealth will not be able to properly review the request for prior authorization. The clinical review criteria expressed below reflects how EmblemHealth determines whether certain services or supplies are medically necessary. EmblemHealth established the clinical review criteria based upon a review of currently available clinical information (including clinical outcome studies in the peer reviewed published medical literature, regulatory status of the technology, evidence-based guidelines of public health and health research agencies, evidence-based guidelines and positions of leading national health professional organizations, views of physicians practicing in relevant clinical areas, and other relevant factors). EmblemHealth expressly reserves the right to revise these conclusions as clinical information changes and welcomes further relevant information. Each benefit program defines which services are covered. The conclusion that a particular service or supply is medically necessary does not constitute a representation or warranty that this service or supply is covered and/or paid for by EmblemHealth, as some programs exclude coverage for services or supplies that EmblemHealth considers medically necessary. If there is a discrepancy between this guideline and a member's benefits program, the benefits program will govern. In addition, coverage may be mandated by applicable legal requirements of a state, the Federal Government or the Centers for Medicare & Medicaid Services (CMS) for Medicare and Medicaid members.
    [Show full text]
  • Nuclear Physics for Medicine
    Nuclear Physics European Collaboration Committee (NuPECC) Nuclear Physics for Medicine European Science Foundation (ESF) Nuclear Physics European Collaboration The European Science Foundation (ESF) was Committee (NuPECC) established in 1974 to provide a common platform NuPECC is an Expert Committee of the European for its Member Organisations to advance European Science Foundation. The aim of NuPECC is to research collaboration and explore new directions for strengthen collaboration in nuclear science by research. It is an independent organisation, owned by promoting nuclear physics, and its trans-disciplinary 66 Member Organisations, which are research funding use and application, in collaborative ventures between organisations, research performing organisations European research groups, and particularly those from and academies from 29 countries. ESF promotes countries linked to the European Science Foundation collaboration in research itself, in funding of research (ESF). NuPECC encourages the optimal use of a and in science policy activities at the European level. network of complementary facilities across Europe, Currently ESF is reducing its research programmes provides a forum for discussing the provision of future while developing new activities to serve the science facilities and instrumentation, and advises and makes community, including peer review and evaluation recommendations to the ESF and other bodies on the services. development, organisation, and support of European nuclear research, particularly on new projects. The
    [Show full text]
  • Radiation Therapy Cancer
    TYPES OF RADIATION ABOUT OHC THERAPY OFFERED At OHC, the search for new treatments is relentless, THROUGH OHC’S the drive to provide superior care runs deep and the COMPREHENSIVE fight against cancer is personal. Our independent, PROGRAM physician-led practice is recognized for going beyond clinical excellence, providing unrestricted • 3-D conformal – Three-dimensional treatment personal support and genuine emotional caring • Cesium - 131 Brachytherapy in neighborhood locations throughout the region. • CyberKnife Robotic Radiosurgery System OHC has been fighting cancer on the front lines • Gamma Knife Radiosurgery (Administered for more than three decades. At its heart, our exclusively through OHC) approach to cancer care is simple – we treat you like • HDR Brachytherapy – Internal Radiation family and surround you with everything you need so you can focus on what matters most: beating • IGRT – Image Guided Radiation Therapy cancer. • IMRT – Intensity Modulated Radiation Therapy • SBRT – Stereotactic Body Radiation Therapy • SRS – Stereotactic Radiosurgery • TheraSphere • Xofigo With a combined approach, you and your OHC radiation doctor will determine which type of RADIATION treatment is best for your diagnosis. To learn more about OHC’s radiation oncology services, please call 1-888-649-4800 or visit ohcare.com. THERAPY For more information, call toll free OHC radiation oncologists harness the power of 1-888-649-4800 or visit ohcare.com. advanced technology for targeted cancer care OHC. Start here. Research Nurses: Specially-trained registered nurses who work directly with a patient’s doctor to coordinate care and treatment if you are participating in a clinical trial . Medical Assistant: The person who takes your vital signs and completes an assessment before WHAT IS RADIATION you see the doctor THERAPY? .
    [Show full text]
  • Radioactive Materials (RAM) Program New / Renewal Medical License Checklist Licensee______Lic
    Radioactive Materials (RAM) Program New / Renewal Medical License Checklist Licensee__________________________________ Lic. #__________________________________ Submit 1 copy only. Number all pages sequentially that are submitted for review. Review the NUREG-1556 Volume 9 It can be used as guidance to complete this checklist. Submit all Policy and Procedures to the Nevada Radiation Control Program. http://www.nrc.gov/reading-rm/doc-collections/nuregs/staff/sr1556/ Submit the Application signed by executive management or a person authorized to sign original documents. If the licensee is an IC participant, all information is minimum Official Use Only. Treat all information regarding this licensee with the appropriate caution and sensitivity. Financial Assurance, Decommissioning and Emergency Plans: If financial assurance is required, submit documentation required by NAC 459.1955. If emergency Plan is required per NAC 459.1951, submit the plan required by NAC 459.195. Mark all materials below that are requested, and submit the use for each selection. Radioactive Material Form Max Quantity Any radioactive material Any As needed permitted by 10 CFR 35.100 Any radioactive material Any As needed permitted by 10 CFR 35.200; except gases, generators and PET radioisotopes PET_________________ Liquid ( or other form) _____ millicuries ( _____GBq); permitted by _____ millicuries ( _____GBq) 10 CFR 35.200 per dose Gasses_____________ Gas _____ millicuries ( _____GBq); permitted by _____ millicuries ( _____GBq) 10 CFR 35.200 per dose Technetium-99m
    [Show full text]
  • Therasphere Yttruim-90 Glass Microspheres
    * .'. .. __ ,____ M•DDS'Nordion SekMxCtAdvtneing Health Package Insert TheraSohere@ Yttrium-90 Glass Microspheres Humanitarian Device. Authorized by Federal Law for use In radiation treatment or as a neoadjuvant to surgery or transplantation in patients with unresectable hepatocellular carcinoma (HCC) who can have placement of appropriately positioned hepatic arterial catheters. The effectiveness of this device for this use has not been demonstrated. CAUTION: Federal (USA) law restricts this device to sale by or on the order of a physician with approprate training and experience. DESCRIPTION TheraSphere® consists of insoluble glass microspheres where yttrium-90 is an integral constituent of the glass [1]. The mean sphere diameter ranges from 20 to 30 Jim. Each milligram contains between 22,000 and 73,000 microspheres. TheraSphere® is supplied in 0.05 mL of sterile, pyrogen-free water contained in a 0.3 mL vee-bottom vial secured within a 12 mm clear acrylic vial shield. A pre-assembled single use administration set is provided with each dose. TheraSphere® Is available in four dose sizes: 3 GBq (81 mCI), 5 GBq (135 mCi), 10 GBq (270 mCi), and 20 GBq (540 mC!). Yttrium-90, a pure beta emitter, decays to stable zirconium-90 with a physical half-life of 64.2 hours (2.68 days). The average energy of the beta emissions from yttrium-90 is 0.9367 MeV. Following embolization of the yttnum-90 glass microspheres In tumorous liver tissue, the beta radiation emitted provides a therapeutic effect [2-6]. The spheres are delivered into the liver tumor through a catheter placed into the hepatic artery that supplies blood to the tumor.
    [Show full text]
  • Summary and Concluding Remarks
    Chapter 10 Summary and concluding remarks 168 169 Chapter 10 Summary and concluding remarks 1. Summary This thesis describes the research that was conducted necessary to start a clinical sation with magnetic resonance imaging (MRI) [6]. The possibility to visualise a trial involving patients suffering from liver malignancies to be treated with therapeutic radionuclide with both a gamma camera and MRI is unique and radioactive holmium loaded microspheres. As discussed in the introduction of makes holmium-166 a very attractive radionuclide for oncological diagnostic this thesis, only the minority of the patients can be treated by surgery or ablation and treatment applications. methods. External beam irradiation would be a very effective way to treat liver As demonstrated in a previous thesis from our department, holmium-loaded tumours, but the required radiation dosages results in too much damage to the microspheres (Ho-PLLA-MS) have proven to be very suitable for treatment of surrounding liver tissue [1,2]. In order to irradiate liver tumours in a selective liver malignancies [7]. However, after having shown the feasibility of this radio- way, internal radionuclide microsphere therapies have been developed [3]. These nuclide therapy, further studies were necessary before Ho-PLLA-MS can be cli- therapies make use of the delivery of radionuclide-loaded microspheres near the nically applied in patients. Parallel to the pharmaceutical work also new dia- tumours by catheterisation of the hepatic artery. Yttrium-90 (Emax= 2.28 MeV; gnostic and therapeutic particles were developed in order to exploit the very half-life 64.1 h) loaded glass microspheres (TheraSphere®, MDS Nordion) and attractive characteristics of holmium for multimodality imaging and cancer therapy.
    [Show full text]
  • Yttrium-90 Selective Internal Radiation Therapy with Glass Microspheres
    Review Article | Intervention http://dx.doi.org/10.3348/kjr.2016.17.4.472 pISSN 1229-6929 · eISSN 2005-8330 Korean J Radiol 2016;17(4):472-488 Yttrium-90 Selective Internal Radiation Therapy with Glass Microspheres for Hepatocellular Carcinoma: Current and Updated Literature Review Edward Wolfgang Lee, MD, PhD1*, Lourdes Alanis, MD, MPH1*, Sung-Ki Cho, MD2*, Sammy Saab, MD3* 1Division of Interventional Radiology, Department of Radiology, UCLA Medical Center, David Geffen School of Medicine at UCLA, Los Angeles, CA 90095, USA; 2Division of Interventional Radiology, Department of Radiology, Samsung Medical Center, Sungkyunkwan University School of Medicine, Seoul 06351, Korea; 3Division of Hepatology, Department of Medicine, Pfleger Liver Institute, University of California at Los Angeles, Los Angeles, CA 90024, USA Hepatocellular carcinoma is the most common primary liver cancer and it represents the majority of cancer-related deaths in the world. More than 70% of patients present at an advanced stage, beyond potentially curative options. Ytrrium-90 selective internal radiation therapy (Y90-SIRT) with glass microspheres is rapidly gaining acceptance as a potential therapy for intermediate and advanced stage primary hepatocellular carcinoma and liver metastases. The technique involves delivery of Y90 infused glass microspheres via the hepatic arterial blood flow to the appropriate tumor. The liver tumor receives a highly concentrated radiation dose while sparing the healthy liver parenchyma due to its preferential blood supply from portal venous blood. There are two commercially available devices: TheraSphere® and SIR-Spheres®. Although, Y90-SIRT with glass microspheres improves median survival in patients with intermediate and advanced hepatocellular carcinoma and has the potential to downstage hepatocellular carcinoma so that the selected candidates meet the transplantable criteria, it has not gained widespread acceptance due to the lack of large randomized controlled trials.
    [Show full text]