DOCSLIB.ORG

List of Cancer Drugs (The First Batch) Ⅰ.Cancer Drugs

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
List of Cancer Drugs (The First Batch) Ⅰ.Cancer Drugs Appendix - Unofficial English translation by Deloitte List of Cancer Drugs (the first batch) Ⅰ.Cancer drugs Generic name of active Approved dosage by NO. HS code ingredient CFDA 1 Anastrozole Tablet 30049090 2 Cytarabine Injection 30021900 3 Axitinib Tablet 30049090 4 Azacitidine Injection 30049090 5 Oxaliplatin Injection 30049090 6 Oteracil/Gimeracil/Tegafur Capsule, Tablet 30049090 7 Busulfan Tablet, Injection 30049090 8 Chlorambucil Tablet 30049090 9 Bicalutamide Tablet, Capsule 30049090 10 Epirubicin Injection 30042090 11 Abiraterone Acetate Tablet 30043900 12 Octreotide acetate Injection 30043900 13 Goserelin acetate Implant 30043200 14 Leuprorelin acetate Injection 30043900 15 Triptorelin Acetate Injection 30043200 16 Dacarbazine Injection 30049090 17 Dasatinib Tablet 30049090 18 Decitabine Injection 30049090 19 Docetaxel Injection 30049090 Injection,Tablet,Oral Emulsion,Emulsifiabl 20 Fluorouracil 30041090 e paste,Implant,Oral Solution 21 Flutamide Tablet, Capsule 30049090 22 Fulvestrant Injection 30043200 23 Formestane Injection 30043900 24 Fotemustine Injection 30049090 25 Tamoxifen citrate 30049090 Tablet,Oral Solution 26 Toremifene citrate Tablet 30049090 27 Cytoxan Injection,Tablet 30049090 28 Gefitinib Tablet 30049090 29 Methotrexate Injection 30049090 lapatinib ditosylate 30 Tablet 30049090 monohydrate 31 Sorafenib tosylate Tablet 30049090 Page 1 32 Apatinib Mesylate Tablet 30049090 33 Osimertinib Mesylate Tablet 30049090 34 Imatinib Mesylate Capsule,Tablet 30049090 35 Vinorelbine Tartrate Capsule, Injection 30044900 36 Carboplatin Injection 30049090 37 Carmofur Tablet 30049090 38 Capecitabine Tablet 30049090 39 Cladribine Injection 30049090 40 Crizotinib Capsule 30049090 41 lenalidomide Capsule 30049090 42 Letrozole Tablet 30049090 43 Raltitrexed Injection 30049090 44 Estradiol phosphate Capsule 30043900 45 Fludarabine Phosphate Tablet, Injection 30049090 46 Ruxolitinib Phosphate Tablet 30049090 47 Etoposide phosphate Injection 30049090 48 Vindesine sulfate Injection 30044900 49 Vincristine Sulphate Injection 30044900 50 Lobaplatin Injection 30049090 51 Afatinib dimaleate Tablet 30049090 52 Melphalan Tablet 30049090 53 Asparaginase Injection 30049090 54 Nedaplatin Injection 30049090 55 Nilotinib Capsule 30049090 56 Pemetrexed disodium Injection 30049090 57 Pegaspargase Injection 30049090 58 Pazopanib Tablet 30049090 59 Bortezomib Injection 30049090 60 Sunitinib Malate Capsule 30049090 61 Hydroxycamptothecin Injection 30044900 62 Mercaptopurine Tablet 30049090 Tablet, Capsule, 63 Doxifluridine 30049090 Dispersible Tablet 64 Regorafenib Tablet 30049090 65 Triptorelin pamoate Injection 30043900 66 Cisplatin Injection 30049090 67 Mitomycin Injection 30042090 68 Tegafur Tablet, Injection 30049090 69 Temozolomide Capsule 30049090 70 Teniposide Injection 30049090 71 Vemurafenib Tablet 30049090 72 Chidamide Tablet 30049090 73 Calcium Folinate Injection 30049090 Page 2 74 Sodium folinate Injection 30049090 75 Cytarabine hydrochloride Injection 30049090 76 Icotinib hydrochloride Tablet 30049090 77 Pirarubicin hydrochloride Injection 30049090 78 Epirubicin hydrochloride Injection 30049090 79 Bleomycin hydrochloride Injection 30042090 80 Chlormethine hydrochloride Injection 30049090 81 Doxorubicin hydrochloride Injection 30042090 82 Erlotinib hydrochloride Tablet 30049090 83 Gemcitabine hydrochloride Injection 30049090 84 Nimustine hydrochloride Injection 30049090 Pingyang mycin 85 Injection 30042090 hydrochloride 86 Daunorubicin hydrochloride Injection 30042090 87 Topotecan Hydrochloride Injection 30044900 88 Idarubicin hydrochloride Capsule, Injection 30042090 89 Irinotecan Hydrochloride Injection 30049090 90 Ibrutinib Capsule 30049090 91 Etoposide Capsule, Injection 30049090 92 Everolimus Tablet 30049090 93 Exemestane Tablet 30043200 94 Ifosfamide Injection 30049090 95 Vinorelbine Bitartrate Injection 30044900 96 Paclitaxel Injection 30049090 97 Calcium levofolinate Injection 30049090 98 Uracil/ Tegafur Tablet, Capsule 30049090 99 Bevacizumab for Injection Injection 30021500 100 Rituximab for Injection Injection 30021500 101 Cetuximab for Injection Injection 30021200 102 Trastuzumab for Injection Injection 30021500 103 Nimotuzumab for lnjection Injection 30021500 Ⅱ.Active Pharmaceutical Ingredient Generic name of active NO. HS code ingredient 1 Anastrozole 29339900 2 Oxaliplatin 28439000 3 Potassium oxonate 29336990 4 Busulfan 29053990 5 Bicalutamide 29309090 6 Pirarubicin 29419090 7 Triptorelin Acetate 29371900 Page 3 8 Dasatinib 29341090 9 Decitabine 29349990 10 Docetaxel 29329990 11 Floxuridine 29349990 12 Flutamide 29242990 13 Formestane 29372319 14 Cytoxan 29349990 15 Gefitinib 29349990 16 Gimeracil 29333990 17 Apatinib Mesylate 29333990 18 Imatinib Mesylate 29335990 19 Vinorelbine Tartrate 29397990 20 Carboplatin 28439000 21 Capecitabine 29349990 22 lenalidomide 29337900 23 Letrozole 29339900 24 Raltitrexed 29349990 25 Fludarabine Phosphate 29349990 26 Vincristine Sulphate 29397990 27 Azathioprine 29335990 28 Asparaginase 35079090 29 Nedaplatin 28439000 30 Pemetrexed disodium 29335990 31 Bortezomib 29339900 32 Cisplatin 28439000 33 Mitomycin 29419090 34 Tegafur 29349990 35 Temozolomide 29339900 36 Chidamide 29333990 37 Cytarabine hydrochloride 29349990 38 Icotinib hydrochloride 29349990 39 Epirubicin hydrochloride 29419090 40 Doxorubicin hydrochloride 29419090 41 Gemcitabine hydrochloride 29349990 42 Mitoxantrone hydrochloride 29225090 Pingyang mycin 43 29419090 hydrochloride 44 Daunorubicin hydrochloride 29419090 45 Topotecan hydrochloride 29397990 46 Idarubicin hydrochloride 29419090 47 Irinotecan hydrochloride 29397990 48 Exemestane 29372900 49 Ifosfamide 29349990 Page 4 50 Paclitaxel 29329990 51 Calcium levofolinate 29335990 Deloitte refers to one or more of Deloitte Touche Tohmatsu Limited, a UK private company limited by guarantee (“DTTL”), its network of member firms, and their related entities. DTTL and each of its member firms are legally separate and independent entities. DTTL (also referred to as “Deloitte Global”) does not provide services to clients. Please see About Deloitte for a more detailed description of DTTL and its member firms. Privacy Thank you for your interest in Deloitte China services. Deloitte China would like to continue to use your personal information (in particular name and contact details) for the purpose of sending you marketing and regulatory updates, invitations to seminars and other events organized, sponsored or promoted by Deloitte China. If you do not wish to receive further communications from Deloitte China, please send a return email to the sender with the word “Unsubscribe” in the subject line. If you would like to update your personal information, please click here. Deloitte China refers to Deloitte Touche Tohmatsu in Hong Kong, Deloitte Touche Tohmatsu in Macau, Deloitte Touche Tohmatsu Certified Public Accountants LLP in the Chinese Mainland and their respective affiliates practising in Hong Kong, Macau and the Chinese Mainland. This communication contains general information only, and none of Deloitte Touche Tohmatsu Limited, its member firms, or their related entities (collectively the “Deloitte Network”) is by means of this communication, rendering professional advice or services. Before making any decision or taking any action that may affect your finances or your business, you should consult a qualified professional adviser. No entity in the Deloitte Network shall be responsible for any loss whatsoever sustained by any person who relies on this communication. © 2018 Deloitte Touche Tohmatsu in Hong Kong, Deloitte Touche Tohmatsu in Macau, and Deloitte Touche Tohmatsu Certified Public Accountants LLP in the Chinese Mainland. All rights reserved. Page 5.
Load more

Recommended publications
  • A Phase II Study of Paclitaxel and Capecitabine As a First-Line Combination Chemotherapy for Advanced Gastric Cancer
    British Journal of Cancer (2008) 98, 316 – 322 & 2008 Cancer Research UK All rights reserved 0007 – 0920/08 $30.00 www.bjcancer.com A phase II study of paclitaxel and capecitabine as a first-line combination chemotherapy for advanced gastric cancer Clinical Studies HJ Kang1, HM Chang1, TW Kim1, M-H Ryu1, H-J Sohn1, JH Yook2,STOh2, BS Kim2, J-S Lee1 and Y-K Kang*,1 1 2 Division of Oncology, Department of Medicine, University of Ulsan College of Medicine, Asan Medical Center, Seoul, Korea; Department of Surgery, University of Ulsan College of Medicine, Asan Medical Center, Seoul, Korea Paclitaxel and capecitabine, which have distinct mechanisms of action and toxicity profiles, have each shown high activity as single agents in gastric cancer. Synergistic interaction between these two drugs was suggested by taxane-induced upregulation of thymidine phosphorylase. We, therefore, evaluated the antitumour activity and toxicities of paclitaxel and capecitabine as first-line therapy in patients with advanced gastric cancer (AGC). Patients with histologically confirmed unresectable or metastatic AGC were treated À2 À2 with capecitabine 825 mg m p.o. twice daily on days 1–14 and paclitaxel 175 mg m i.v. on day 1 every 3 weeks until disease progression or unacceptable toxicities. Between June 2002 and May 2004, 45 patients, of median age 57 years (range ¼ 38–73 years), were treated with the combination of capecitabine and paclitaxel. After a median 6 cycles (range ¼ 1–9 cycles) of chemotherapy, 43 were evaluable for toxicity and response. A total of 2 patients showed complete response and 20 showed partial response making the overall response rate 48.9% (95% CI ¼ 30.3–63.5%).
    [Show full text]
  • 996.Full-Text.Pdf
    Published OnlineFirst April 6, 2010; DOI: 10.1158/1535-7163.MCT-09-0960 Research Article Molecular Cancer Therapeutics Potent Preclinical Impact of Metronomic Low-Dose Oral Topotecan Combined with the Antiangiogenic Drug Pazopanib for the Treatment of Ovarian Cancer Kae Hashimoto1, Shan Man1, Ping Xu1, William Cruz-Munoz1, Terence Tang1, Rakesh Kumar3, and Robert S. Kerbel1,2 Abstract Low-dose metronomic chemotherapy has shown promising activity in many preclinical and some phase II clinical studies involving various tumor types. To evaluate further the potential therapeutic impact of met- ronomic chemotherapy for ovarian cancer, we developed a preclinical model of advanced human ovarian cancer and tested various low-dose metronomic chemotherapy regimens alone or in concurrent combination with an antiangiogenic drug, pazopanib. Clones of the SKOV-3 human ovarian carcinoma cell line expressing a secretable β-subunit of human choriogonadotropic (β-hCG) protein and firefly luciferase were generated and evaluated for growth after orthotopic (i.p.) injection into severe combined immunodeficient mice; a high- ly aggressive clone, SKOV-3-13, was selected for further study. Mice were treated beginning 10 to 14 days after injection of cells when evidence of carcinomatosis-like disease in the peritoneum was established as assessed by imaging analysis. Chemotherapy drugs tested for initial experiments included oral cyclophos- phamide, injected irinotecan or paclitaxel alone or in doublet combinations with cyclophosphamide; the re- sults indicated that metronomic cyclophosphamide had no antitumor activity whereas metronomic irinotecan had potent activity. We therefore tested an oral topoisomerase-1 inhibitor, oral topotecan, at optimal biological dose of 1 mg/kg/d. Metronomic oral topotecan showed excellent antitumor activity, the extent of which was significantly enhanced by concurrent pazopanib, which itself had only modest activity, with 100% survival values of the drug combination after six months of continuous therapy.
    [Show full text]
  • Assessment of Overall Survival, Quality of Life, And
    Supplementary Online Content Salas-Vega S, Iliopoulos O, Mossialos E. Assesment of overall survival, quality of life, and safety benefits associated with new cancer medicines [published online December 29, 2016]. JAMA Oncol. doi:10.1001/jamaoncol.2016.4166 eTable 1. Therapeutic profile of all cancer medicines approved by the FDA between 2003- 2013 eTable 2. Regulatory evidence in support of classification of drug clinical benefits eFigure 1. Number of cancer drugs that were evaluated by all three HTA agencies, sorted by magnitude of clinical benefits eTable 3. Interagency agreement–Krippendorff’s alpha coefficients eMethods This supplementary material has been provided by the authors to give readers additional information about their work. Online-Only Supplement © 2016 American Medical Association. All rights reserved. Downloaded From: https://jamanetwork.com/ on 09/25/2021 Clinical value of cancer medicines Contents eExhibits ......................................................................................................................................................... 3 eTable 1. Therapeutic profile of all cancer medicines approved by the FDA between 2003- 2013 (Summary of eTable 2) ................................................................................................................... 3 eTable 2. Regulatory evidence in support of classification of drug clinical benefits ....................... 6 eFigure 1. Number of cancer drugs that were evaluated by all three HTA agencies, sorted by magnitude of clinical benefits
    [Show full text]
  • Phenotype Microarrays Panels PM-M1 to PM-M14
    Phenotype MicroArrays™ Panels PM-M1 to PM-M14 for Phenotypic Characterization of Mammalian Cells Assays: Energy Metabolism Pathways Ion and Hormone Effects on Cells Sensitivity to Anti-Cancer Agents and for Optimizing Culture Conditions for Mammalian Cells PRODUCT DESCRIPTIONS AND INSTRUCTIONS FOR USE PM-M1 Cat. #13101 PM-M2 Cat. #13102 PM-M3 Cat. #13103 PM-M4 Cat. #13104 PM-M5 Cat. #13105 PM-M6 Cat. #13106 PM-M7 Cat. #13107 PM-M8 Cat. #13108 PM-M11 Cat. #13111 PM-M12 Cat. #13112 PM-M13 Cat. #13113 PM-M14 Cat. #13114 © 2016 Biolog, Inc. All rights reserved Printed in the United States of America 00P 134 Rev F February 2020 - 1 - CONTENTS I. Introduction ...................................................................................................... 2 a. Overview ................................................................................................... 2 b. Background ............................................................................................... 2 c. Uses ........................................................................................................... 2 d. Advantages ................................................................................................ 3 II. Product Description, PM-M1 to M4 ................................................................ 3 III. Protocols, PM-M1 to M4 ................................................................................. 7 a. Materials Required .................................................................................... 7 b. Determination
    [Show full text]
  • BC Cancer Benefit Drug List September 2021
    Page 1 of 65 BC Cancer Benefit Drug List September 2021 DEFINITIONS Class I Reimbursed for active cancer or approved treatment or approved indication only. Reimbursed for approved indications only. Completion of the BC Cancer Compassionate Access Program Application (formerly Undesignated Indication Form) is necessary to Restricted Funding (R) provide the appropriate clinical information for each patient. NOTES 1. BC Cancer will reimburse, to the Communities Oncology Network hospital pharmacy, the actual acquisition cost of a Benefit Drug, up to the maximum price as determined by BC Cancer, based on the current brand and contract price. Please contact the OSCAR Hotline at 1-888-355-0355 if more information is required. 2. Not Otherwise Specified (NOS) code only applicable to Class I drugs where indicated. 3. Intrahepatic use of chemotherapy drugs is not reimbursable unless specified. 4. For queries regarding other indications not specified, please contact the BC Cancer Compassionate Access Program Office at 604.877.6000 x 6277 or [email protected] DOSAGE TUMOUR PROTOCOL DRUG APPROVED INDICATIONS CLASS NOTES FORM SITE CODES Therapy for Metastatic Castration-Sensitive Prostate Cancer using abiraterone tablet Genitourinary UGUMCSPABI* R Abiraterone and Prednisone Palliative Therapy for Metastatic Castration Resistant Prostate Cancer abiraterone tablet Genitourinary UGUPABI R Using Abiraterone and prednisone acitretin capsule Lymphoma reversal of early dysplastic and neoplastic stem changes LYNOS I first-line treatment of epidermal
    [Show full text]
  • Drug Name Plate Number Well Location % Inhibition, Screen Axitinib 1 1 20 Gefitinib (ZD1839) 1 2 70 Sorafenib Tosylate 1 3 21 Cr
    Drug Name Plate Number Well Location % Inhibition, Screen Axitinib 1 1 20 Gefitinib (ZD1839) 1 2 70 Sorafenib Tosylate 1 3 21 Crizotinib (PF-02341066) 1 4 55 Docetaxel 1 5 98 Anastrozole 1 6 25 Cladribine 1 7 23 Methotrexate 1 8 -187 Letrozole 1 9 65 Entecavir Hydrate 1 10 48 Roxadustat (FG-4592) 1 11 19 Imatinib Mesylate (STI571) 1 12 0 Sunitinib Malate 1 13 34 Vismodegib (GDC-0449) 1 14 64 Paclitaxel 1 15 89 Aprepitant 1 16 94 Decitabine 1 17 -79 Bendamustine HCl 1 18 19 Temozolomide 1 19 -111 Nepafenac 1 20 24 Nintedanib (BIBF 1120) 1 21 -43 Lapatinib (GW-572016) Ditosylate 1 22 88 Temsirolimus (CCI-779, NSC 683864) 1 23 96 Belinostat (PXD101) 1 24 46 Capecitabine 1 25 19 Bicalutamide 1 26 83 Dutasteride 1 27 68 Epirubicin HCl 1 28 -59 Tamoxifen 1 29 30 Rufinamide 1 30 96 Afatinib (BIBW2992) 1 31 -54 Lenalidomide (CC-5013) 1 32 19 Vorinostat (SAHA, MK0683) 1 33 38 Rucaparib (AG-014699,PF-01367338) phosphate1 34 14 Lenvatinib (E7080) 1 35 80 Fulvestrant 1 36 76 Melatonin 1 37 15 Etoposide 1 38 -69 Vincristine sulfate 1 39 61 Posaconazole 1 40 97 Bortezomib (PS-341) 1 41 71 Panobinostat (LBH589) 1 42 41 Entinostat (MS-275) 1 43 26 Cabozantinib (XL184, BMS-907351) 1 44 79 Valproic acid sodium salt (Sodium valproate) 1 45 7 Raltitrexed 1 46 39 Bisoprolol fumarate 1 47 -23 Raloxifene HCl 1 48 97 Agomelatine 1 49 35 Prasugrel 1 50 -24 Bosutinib (SKI-606) 1 51 85 Nilotinib (AMN-107) 1 52 99 Enzastaurin (LY317615) 1 53 -12 Everolimus (RAD001) 1 54 94 Regorafenib (BAY 73-4506) 1 55 24 Thalidomide 1 56 40 Tivozanib (AV-951) 1 57 86 Fludarabine
    [Show full text]
  • Identification of Repurposed Drugs for Chordoma Therapy
    Identification of Repurposed Drugs for Chordoma Therapy. Menghang Xia, Ph.D. Division of Pre-Clinical Innovation National Center for Advancing Translational Sciences National Institutes of Health Fourth International Chordoma Research Workshop Boston, March 22, 2013 NIH Chemical Genomics Center Founded in 2004 • National Center for Advancing Translational Sciences (NCATS) • >100 staff: Biologists, Chemists, Informatics and Engineers Robotic HTS facility Mission • Development of chemical probes for novel biology • Novel targets, rare/neglected diseases • New technologies/paradigms for assay development, screening, informatics, chemistry Collaborations • >200 investigators worldwide • 60% NIH extramural • 25% NIH intramural • 15% Foundations, Research Consortia, Pharma/Biotech Steps in the drug development process Make Create Test modifications Test in Test in testing >100,000 to active animals for humans for system chemicals for chemicals to safety, safety, (aka, activity on make suitable effectiveness effectiveness “assay”) target for human use Two approaches to therapeutics for rare and neglected diseases 1-2 years? >400,000 compounds, 15 yrs Lead Preclinical Clinical Screen Hit Lead Optimization Development Trials 3500 drugs The NCGC Pharmaceutical Collection Procurement in Drug Source In house process Total US FDA* 1635 182 1817 UK/EU/Canada/Japan 756 177 933 Total Approved 2391 359 2750 Investigational 928 3953 4881 Total 3319 4312 7631 * These counts include approved veterinary drugs Informatics sources for NPC o US FDA: Orange Book, OTC, NDC, Green Book, Drugs at FDA o Britain NHS o EMEA o Health Canada o Japan NHI Physical sources for NPC o Procurement from >70 suppliers worldwide o In-house purification of APIs from marketed forms Drug plate composition o Synthesis Comprehensive Drug Repurposing Library Access to the NPC (http://tripod.nih.gov/npc/) Chordoma Screening Project • Cell lines Chordoma cell lines screened: U-CH1 and U-CH2B .
    [Show full text]
  • Relevance Network Between Chemosensitivity and Transcriptome in Human Hepatoma Cells1
    Vol. 2, 199–205, February 2003 Molecular Cancer Therapeutics 199 Relevance Network between Chemosensitivity and Transcriptome in Human Hepatoma Cells1 Masaru Moriyama,2 Yujin Hoshida, topoisomerase II ␤ expression, whereas it negatively Motoyuki Otsuka, ShinIchiro Nishimura, Naoya Kato, correlated with expression of carboxypeptidases A3 Tadashi Goto, Hiroyoshi Taniguchi, and Z. Response to nimustine was associated with Yasushi Shiratori, Naohiko Seki, and Masao Omata expression of superoxide dismutase 2. Department of Gastroenterology, Graduate School of Medicine, Relevance networks identified several negative University of Tokyo, Tokyo 113-8655 [M. M., Y. H., M. O., N. K., T. G., H. T., Y. S., M. O.]; Cellular Informatics Team, Computational Biology correlations between gene expression and resistance, Research Center, Tokyo 135-0064 [S. N.]; and Department of which were missed by hierarchical clustering. Our Functional Genomics, Graduate School of Medicine, Chiba University, results suggested the necessity of systematically Chiba 260-8670 [N. S.], Japan evaluating the transporting systems that may play a major role in resistance in hepatoma. This may provide Abstract useful information to modify anticancer drug action in Generally, hepatoma is not a chemosensitive tumor, hepatoma. and the mechanism of resistance to anticancer drugs is not fully elucidated. We aimed to comprehensively Introduction evaluate the relationship between chemosensitivity and Hepatoma is a major cause of death even in developed gene expression profile in human hepatoma cells, by countries, and its incidence is increasing (1). Despite the using microarray analysis, and analyze the data by progress of therapeutic technique (2), the efficacy of radical constructing relevance networks. therapy is hampered by frequent recurrence and advance of In eight hepatoma cell lines (HLE, HLF, Huh7, Hep3B, the tumor (3).
    [Show full text]
  • Title Second-Line Chemotherapy for Small-Cell Lung Cancer
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by Kyoto University Research Information Repository Second-line chemotherapy for small-Cell Lung Cancer Title (SCLC). Author(s) Kim, Young Hak; Mishima, Michiaki Citation Cancer treatment reviews (2011), 37(2): 143-150 Issue Date 2011-04 URL http://hdl.handle.net/2433/137220 Right © 2010 Elsevier Ltd Type Journal Article Textversion author Kyoto University Second-line Chemotherapy for Small-Cell Lung Cancer (SCLC) Young Hak Kim and Michiaki Mishima Department of Respiratory Medicine, Graduate School of Medicine, Kyoto University, 54 Shogoin-Kawaharacho, Sakyo-ku, Kyoto 606-8507, Japan For reprints and all correspondence: Young Hak Kim Department of Respiratory Medicine, Graduate School of Medicine, Kyoto University, 54 Shogoin-Kawaharacho, Sakyo-ku, Kyoto 606-8507, Japan Phone: +81-75-751-3830; Fax: +81-75-751-4643; E-mail: [email protected] Running title: Second-line Chemotherapy for SCLC Key words: small-cell lung cancer, relapsed, chemotherapy, second line, sensitive, refractory 1 Abstract Although small-cell lung cancer (SCLC) generally shows an excellent response to initial chemotherapy, most patients finally relapse and salvage chemotherapy is considered. Usually, the response to salvage chemotherapy significantly differs between sensitive and refractory relapse. Sensitive relapse is relatively chemosensitive and re-challenge with the same drugs as used in the initial chemotherapy has been used historically, while refractory relapse is extremely chemoresistant and its prognosis has been abysmal. To date, a number of clinical trials have been carried out for relapsed SCLC; however, the number of randomized trials is quite limited.
    [Show full text]
  • A Phase II Study of Adjuvant Chemotherapy of Tegafur–Uracil For
    ANTICANCER RESEARCH 36 : 6505-6510 (2016) doi:10.21873/anticanres.11250 A Phase II Study of Adjuvant Chemotherapy of Tegafur –Uracil for Patients with Breast Cancer with HER2-negative Pathologic Residual Invasive Disease After Neoadjuvant Chemotherapy SATORU TANAKA 1, MITSUHIKO IWAMOTO 2, KOSEI KIMURA 2, YUKO TAKAHASHI 3, HIYOYA FUJIOKA 2, NAYUKO SATO 4, RISA TERASAWA 2, KANAKO KAWAGUCHI 2, AYANA IKARI 2, TOMO TOMINAGA 2, SAKI MAEZAWA 2, NODOKA UMEZAKI 2, JUNNA MATSUDA 2 and KAZUHISA UCHIYAMA 2 1Breast Surgery, National Hospital Organization Osaka-Minami Medical Center, Kawachinagano, Japan; 2Breast and Endocrine Surgery, Osaka Medical College Hospital, Takatsuki, Japan; 3Breast and Endocrine Surgery, Hirakata City Hospital, Hirakata, Japan; 4Breast Surgery, Saiseikai Suita Hospital, Suita, Japan Abstract. Background: There is no consensus on the need an opportunity for down-staging to avoid mastectomy for for adjuvant chemotherapy for patients with pathological inoperable tumors or breast-conserving surgery in cases residual invasive breast cancer (non-pCR) after neoadjuvant originally requiring mastectomy (1, 2). Anthracyclines and chemotherapy (NAC). We evaluated the tolerability and taxanes have been used as the standard chemotherapeutic safety of tegafur-uracil (UFT) as adjuvant chemotherapy for regimens for breast cancer, however, tumoral estrogen patients with human epidermal growth factor receptor 2- receptor (ER) and human epidermal growth factor receptor negative breast cancer that resulted in non-pCR after NAC. 2 (HER2) statuses are important predictors of response to Patients and Methods: We treated patients with 270 mg/m 2 chemotherapy (3-5). Sensitivity to NAC is lower in ER- UFT per day for 2 years after definitive surgery and positive and HER2-negative cancer than in other subtypes.
    [Show full text]
  • Synthesis of Antitumor Fluorinated Pyrimidine Nucleosides
    UOPP #1290994, VOL 49, ISS 2 Synthesis of Antitumor Fluorinated Pyrimidine Nucleosides Patrizia Ferraboschi, Samuele Ciceri, and Paride Grisenti QUERY SHEET This page lists questions we have about your paper. The numbers displayed at left can be found in the text of the paper for reference. In addition, please review your paper as a whole for correctness. There are no Editor Queries in this paper. TABLE OF CONTENTS LISTING The table of contents for the journal will list your paper exactly as it appears below: Synthesis of Antitumor Fluorinated Pyrimidine Nucleosides Patrizia Ferraboschi, Samuele Ciceri, and Paride Grisenti Organic Preparations and Procedures International, 49:1–85, 2017 Copyright Ó Taylor & Francis Group, LLC ISSN: 0030-4948 print / 1945-5453 online DOI: 10.1080/00304948.2017.1290994 Synthesis of Antitumor Fluorinated Pyrimidine Nucleosides Patrizia Ferraboschi, Samuele Ciceri, and Paride Grisenti Dipartimento di Biotecnologie Mediche e Medicina Traslazionale, Universita 5 degli Studi di Milano, Via Saldini 50, 20141 Milano, Italy Introduction Nucleosides, due to their biological role as constituents of nucleic acids, are main targets in the development of analogues aimed at antimetabolite-based therapy. Modified nucleo- sides can disrupt biological processes causing the death of cancer or virally-infected cells. 10 Fluorinated analogues of biologically active compounds are often characterized by a dramatic change in their activity, compared with the parent molecules. Fluorine, the most electronegative element, is isosteric with a hydroxy group, the C-F bond length (1.35 A) being similar to the C-O bond length (1.43 A). In addition, it is the second smallest atom and it can mimic hydrogen in a modified structure; its van der Waals radius (1.47 A) is intermedi- 15 ate between that of hydrogen (1.20 A) and that of oxygen (1.52 A).
    [Show full text]
  • Anticancer Alkylating Agents-Part-I.Pdf
    Anticancer Agents Medicinal Chemistry III B Pharm Dr. bilal al-jaidi Assistant Professor, Pharmaceutical Medicinal Chemistry Faculty of Pharmacy, Philadelphia University-Jordan Email: [email protected] Learning Outcome At the end of this lesson students will be able to – Outline the current status, causes and treatment strategies of cancer – Explain the mechanism of action, SAR, therapeutic uses and side effects of following classes of anti-cancer agents: • Alkylating Agents QUIZ = 20 Marks • Heavy metal compounds (Metallating Agents) • Anti-metabolite • Antibiotics • Plant Extracts • Topoisomerase inhibitors • Hormones • Combination of chemotherapy with other treatments • Others First Examination= 20 Marks The Status of Cancer • Cancer is a leading cause of death worldwide, accounting for 12.6 million new cases and 7.6 million deaths every year. THIS IS EQUIVALENT TO ONE PERSON, EVERY 5 SECONDS OF EVERYDAY Source: GLOBOCAN 2008 By 2020 the World Health Organisation (WHO) expects this rise to 16 million. Cancer • A new growth of tissue in which multiplication of cells is uncontrolled and progressive (tumour). • Abnormal cells can spread to other parts of the body (metastasise). Cancer Types Cancer types are categorized based on the functions/locations of the cells from which they originate: Carcinoma: a tumor derived from epithelial cells, those cells that line the inner or outer surfaces of our skin and organs (80-90% of all cancer cases reported) Sarcoma: a tumor derived from muscle, bone, cartilage, fat or connective tissues. Leukemia: a cancer derived from white blood cells or their precursors. Lymphoma: a cancer of bone marrow derived cells that affects the lymphatic system. Myelomas: a cancer involving the white blood cells responsible for the production of antibodies (B lymphocytes).
    [Show full text]