DOCSLIB.ORG

Fluorous Nanoparticle Platform for Cancer Imaging And

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Fluorous Nanoparticle Platform for Cancer Imaging And FLUOROUS NANOPARTICLE PLATFORM FOR CANCER IMAGING AND TREATMENT By JAQUELINE DIANE WALLAT Dissertation Advisor: Dr. Jonathan K. Pokorski For the degree of Doctor of Philosophy Department of Macromolecular Science & Engineering CASE WESTERN RESERVE UNIVERSITY January, 2018 CASE WESTERN RESERVE UNIVERSITY SCHOOL OF GRADUATE STUDIES We hereby approve the thesis/dissertation of Jaqueline Diane Wallat candidate for the degree of Doctor of Philosophy. * Thesis defense date : October 31, 2017 ______________________________ Dr. Jonathan K. Pokorski ______________________________ Dr. David Schiraldi ______________________________ Dr. Gary E. Wnek ______________________________ Dr. Horst A. von Recum *We also certify that written approval has been obtained for any proprietary material contained therein. Signed copy can be viewed in Graduate Studies at Case Western Reserve University. 2 Copyright © 2017 by JAQUELINE DIANE WALLAT All rights reserved 3 Table of Contents List of Figures ................................................................................................................9 List of Tables..................................................................................................................21 Abstract...........................................................................................................................25 Chapter I ........................................................................................................................27 Introduction to Fluorinated Systems for MR Imaging and Drug Delivery: From Perfluorocarbon Emulsions to Multifunctional Fluorinated Polymeric Architectures 1.1. Overview..................................................................................................................28 1.2. A Brief History of Fluorine......................................................................................28 1.3. Fluorine in Biomedical Applications........................................................................29 1.4. Magnetic Resonance Imaging of Fluorinated Nuclei...............................................31 1.5. PFCs in 19F MRI.......................................................................................................33 1.6. Polymeric Materials in 19F Imaging.........................................................................36 1.7. Responsive 19F Contrast Agents...............................................................................39 1.8. Fluorinated Systems for Delivery and Imaging.......................................................41 1.8.1. Multifunctional Fluorine Polymer from CRP Methods................................42 1.9. Conclusions .............................................................................................................48 1.10. Referencecs ...........................................................................................................50 Chapter II........................................................................................................................64 Optical and Magnetic Resonance Imaging by Fluorous Colloidal Nanoparticles 2.1. Background..............................................................................................................65 2.2. Results and Discussion.............................................................................................68 2.2.1. Polymer Synthesis and Characterization........................................................68 4 2.2.2. Investigation of Copolymer Molecular Weight on Size and Imaging Feasibility...............................................................................................................72 2.2.3. Phantom MRI Studies..................................................................................77 2.2.4. Cell Viability and Uptake in Macrophages .................................................79 2.2.5. Tumor Targeting...........................................................................................82 2.3. Conclusions ………………………………………………...…………………….86 2.4. Experimental Methods ……………………………………...……………………87 2.4.1. Reagents ……………………………………………..……………………87 2.4.2. Instrumentation ……………………………………......…………………..87 2.4.3. Synthesis of azide-functionalized ATRP initiator (A)...…………………...88 2.4.4. Synthesis of OEGMEMA/TFEMA Copolymer (1). ..……………………..89 2.4.5. Dynamic Light Scattering …………………….……..………………….....90 2.4.6. Transmission Electron Microscopy …………………………………….....90 2.4.7. Synthesis of Cy5-Labeled Polymer (2) ………………..…………………..90 2.4.8. 19F Magnetic Resonance Imaging Spectroscopy………..……………….... 91 2.4.9. 19F Magnetic Resonance Imaging Phantoms……………..………….......... 91 2.4.10. Cell Culture………………………………………………..…………….. 92 2.4.11. Flow Cytometry ……………………………………………..……………93 2.4.12. Cytotoxicity Assays…………………………………………..…………...93 2.4.13. Confocal Microscopy …………………………………………..…………94 2.4.14. TNBC Targeting………………………………………………...………...94 2.4.15. OCVA Targeting ………………………………………………...………..94 2.5. Supplemental Figures ……………………………………………………...………95 5 2.6. Acknowledgements ………………………………………………………...…….101 2.7. Exploratory Studies………………………………………………………...……..101 2.7.1.Synthetisis Optimization……………………………………………...…….101 2.7.2 Attempted 19F NMR and MRI of Particle Taken Up By Macrophages...…..104 2.8. References ……………………………………………………………………..…109 Chapter III. …………………………………………………………………………....118 Fluorinated Polymer–Photosensitizer Conjugates Enable Improved Generation of ROS for Anticancer Photodynamic Therapy 3.1. Background ………………………………………………………………………119 3.2. Results and Discussion …………………………………………………………...121 3.2.1. Polymer Synthesis and Characterization …………………………………..121 3.2.2. Conjugate Synthesis and Characterization ………………………………...122 3.2.3. Accessing Efficacy of Copolymer-Conjugate 3…………………………....126 3.3. Conclusions …………………………………………………………………….....131 3.4. Experimental Methods…………………………………………………………......132 3.4.1. Reagents…………………………………..………………………………...132 3.4.2. Instrumentation …………………………………..………………………...133 3.4.3. Copolymer (1) Synthesis…………………………………..………………..133 3.4.4. Synthesis of ZnEpPor-Labeled Polymer (3) ....………………………….....134 3.4.5. UV/Visible Spectroscopy ……...…………………………...........................134 3.4.6. Dynamic Light Scattering .............................................................................135 3.4.7. Gel Permeation Chromatography..................................................................135 1 3.4.8. Detection of O2 by ABDA............................................................................135 6 3.4.9. Cell Culture ..................................................................................................136 3.4.10. Confocal Microscopy .................................................................................137 3.4.11. Cytotoxicity Assays ....................................................................................137 3.4.12. LIVE/DEAD Assay.....................................................................................137 3.4.13. MTT Assay .................................................................................................137 3.5. Supplemental Figures ..............................................................................................138 3.6. Exploratory Studies .................................................................................................144 3.7. References ...............................................................................................................146 Chapter IV. .....................................................................................................................152 Fluorous Copolymer Delivers DOX to Cancer Cell 4.1. Background..............................................................................................................153 4.2. Results and Discussion............................................................................................156 4.2.1. Conjugate Synthesis and Characterization....................................................156 4.2.2. In Vitro Cell Studies......................................................................................160 4.3. Conclusions..............................................................................................................165 4.4. Experimental Section ..............................................................................................166 4.4.1. Reagents .......................................................................................................166 4.4.2. Instrumentation ............................................................................................167 4.4.3. Synthesis of tert-butyl-2-(pent-4-ynoyl)hydrazinecarboxylate.....................167 4.4.4. Synthesis of pent-4-ynehydrazine.................................................................168 4.4.5. Synthesis of hydrazone-DOX-alkyne............................................................168 4.4.6. Synthesis of hydrazone-DOX-copolymer.....................................................169 4.4.7. Polymer Characterization..............................................................................169 7 4.4.8. Determination of DOX concentration on the copolymer...............................169 4.4.9. Release Study.................................................................................................170 4.4.10. Cell Culture .................................................................................................170 4.4.11. Tracking DOX in cells.................................................................................170
Load more

Recommended publications
  • Historical Group
    Historical Group NEWSLETTER and SUMMARY OF PAPERS No. 64 Summer 2013 Registered Charity No. 207890 COMMITTEE Chairman: Prof A T Dronsfield | Prof J Betteridge (Twickenham, 4, Harpole Close, Swanwick, Derbyshire, | Middlesex) DE55 1EW | Dr N G Coley (Open University) [e-mail [email protected]] | Dr C J Cooksey (Watford, Secretary: Prof. J. W. Nicholson | Hertfordshire) School of Sport, Health and Applied Science, | Prof E Homburg (University of St Mary's University College, Waldegrave | Maastricht) Road, Twickenham, Middlesex, TW1 4SX | Prof F James (Royal Institution) [e-mail: [email protected]] | Dr D Leaback (Biolink Technology) Membership Prof W P Griffith | Dr P J T Morris (Science Museum) Secretary: Department of Chemistry, Imperial College, | Mr P N Reed (Steensbridge, South Kensington, London, SW7 2AZ | Herefordshire) [e-mail [email protected]] | Dr V Quirke (Oxford Brookes Treasurer: Dr J A Hudson | University) Graythwaite, Loweswater, Cockermouth, | Prof. H. Rzepa (Imperial College) Cumbria, CA13 0SU | Dr. A Sella (University College) [e-mail [email protected]] Newsletter Dr A Simmons Editor Epsom Lodge, La Grande Route de St Jean, St John, Jersey, JE3 4FL [e-mail [email protected]] Newsletter Dr G P Moss Production: School of Biological and Chemical Sciences, Queen Mary University of London, Mile End Road, London E1 4NS [e-mail [email protected]] http://www.chem.qmul.ac.uk/rschg/ http://www.rsc.org/membership/networking/interestgroups/historical/index.asp 1 RSC Historical Group Newsletter No. 64 Summer 2013 Contents From the Editor 2 Obituaries 3 Professor Colin Russell (1928-2013) Peter J.T.
    [Show full text]
  • The Automated Flow Synthesis of Fluorine Containing Organic Compounds
    The automated flow synthesis of fluorine containing organic compounds by CHANTAL SCHOLTZ Submitted in partial fulfilment of the requirements for the degree PHILOSOPHAE DOCTOR In the Faculty of Natural & Agricultural Sciences UNIVERSITY OF PRETORIA PRETORIA Supervisor: Dr D.L. Riley February 2019 DECLARATION I, Chantal Scholtz declare that the thesis/dissertation, which I hereby submit for the degree PhD Chemistry at the University of Pretoria, is my own work and has not previously been submitted by me for a degree at this or any other tertiary institution. Signature :.......................................... Date :..................................... ii ACKNOWLEDGEMENTS I would herewith sincerely like to show my gratitude to the following individuals for their help, guidance and assistance throughout the duration of this project: My supervisor, Doctor Darren Riley, for his knowledge and commitment. Thank you for being a fantastic supervisor and allowing me the opportunity to learn so many valuable skills. My husband, Clinton, for all your love, support and patience and for always being there for me. You are the best. My family, for all the encouragement and support you gave me as well as always believing in me. I will always appreciate what you have done for me. Mr Drikus van der Westhuizen and Mr Johan Postma for their assistance at the Pelchem laboratories with product isolation and characterisation. Dr Mamoalosi Selepe for NMR spectroscopy services, Jeanette Strydom for XRF services and Gerda Ehlers at the UP library for her invaluable assistance. All my friends and colleagues for the continuous moral support, numerous helpful discussions and necessary coffee breaks. My colleagues at Chemical Process Technologies for their ongoing support and motivation, especially Dr Hannes Malan and Prof.
    [Show full text]
  • Dissertation
    DISSERTATION Titel Synthesis and Application of Fluorinated Carbohydrates and other Bioactive Compounds angestrebter akademischer Titel Doktorin der Naturwissenschaften (Dr. rer. nat.) Verfasserin: DI Michaela Braitsch Matrikelnummer: 9726189 Dissertationsgebiet Chemie Betreuer: Univ. Prof. Dr. Walther Schmid Wien im Oktober 2009 für Nicolas 7. 12. 1989 – 21. 2. 2008 Erfolgsrezept Ich will das Geheimnis verraten, dass mich zum Ziel geführt hat. Meine Stärke liegt einzig und allein in meiner Beharrlichkeit. LOUIS PASTEUR DANKSAGUNG Die vorliegende Arbeit entstand im Zeitraum von Feburar 2005 bis Oktober 2009 am Institut für Organische Chemie der Universität Wien. An dieser Stelle möchte ich mich bei allen, die zum Entstehen und Gelingen dieser Arbeit beigetragen haben, recht herzlich bedanken: Meinem Betreuer Prof. Walther Schmid für die interessante Themenstellung, sowie seine Hilfe und Unterstützung über die gesamte Zeit. Meinen Arbeitskollegen Michael Fischer, Stefan Hader, Ralph Hollaus, Christoph Lentsch, Roman Lichtenecker, Michael Nagl, Norberth Neuwirth, ChrisTina Nowikow, Christoph Schmölzer, Helga Wolf für die freundschaftliche Zusammenarbeit und das kollegiale Arbeitsklima. Den fleißigen Bienchen Gerlinde Benesch, Martina Drescher und Jale Özgur fürs Organisieren des Laborhaushaltes. Der NMR‐Abteilung Hanspeter Kählig, Lothar Brecker und Susanne Felsinger fürs Messen von zahlreichen Spektren. Der HPLC‐ und MS‐Abteilung Sabine Schneider und Peter Unteregger. Meiner Familie, im speziellen meinen Eltern und meiner Schwester Cornelia
    [Show full text]
  • The Fluorite System)
    TOCIASSIFIKD Geology and Mineralogy This document consists of 16 pages Series A UNITED STATES DEPARTMENT OF THE INTERIOR GEOLOGICAL SURVEI CONDITIONS OF THE FORMATION OF FLUORITE IN SEDIMENTARY ROCKS (The Fluorite System) By Ao V* Kazakov and E* I« Sokolova Source s Akade Nauk SSSR5 Institut Geolo Nauk Trudy5 vyp<> Geol e Seriia (no 0 1^0), p 0 22-61t, Moscow Translated by ¥e L0 Skits April Trace Elements Investigations Report 386 This preliminary report is distributed without editorial and technical review for conformity with official standards and nomenclature e It is not forjpublic inspection or quotation., 2 USGS - TEX-386 GEOLOGY AND MINERALOGY Distribution (Series A^ No. of copies American Gyanamid Company, 1/fi.nchester ..oo»o..o 1 1 2 Battelle Memorial Institute, Columbus «>e* 0 o. 0 «». 1 Carbide and Carbon Chemicals Company, Y-12 Area e c o 1 Division of Raw Materials, Albuquerque, e «.oe. 0 o 1 1 Division of Raw Materials, Denver « oo 1 Division of Raw Materials, Douglas c «, e « 0 c 0 o e » 1 Division of Raw Materials, Hot Springs. « 0 » . o o 1 6 Division of Raw Materials, Phoenix 0 o. 0 ..o« 0 e. I Division of Raw Materials, Richfield. e * c » e o » * . 1 Division of Raw Materials, Salt Lake City . o e 1 Division of Raw Materials, Washington 3 Division of Research, Washington,, eee.e.oo.o. 1 1 Exploration Division,, Grand Junction Operations Office, 1 Grand Junction Operations Office. e..«o.o»o«. 1 Technical Information Service, Oak Ridge e . o . * « o <» 6 1 Uo S 0 Geological Sfjtrveys Alaskan Geology Branch, Washington.
    [Show full text]
  • Volume 115, No. 10, October 2015
    VOLUME 115 NO. 10 OCTOBER 2015 advanced metals initiative 28–30 October 2015 our future through science advanced metals initiative ADVANCED METALS INITIATIVE TECHNOLOGY NETWORKS - expand the country’s technical The Advanced Metals Initiative (AMI) was The AMI’s technology networks include: capacity; established by the Department of Science • the Light Metals Development Network - develop the use of metals in new and Technology to facilitate research, (LMDN) for titanium and aluminium co- applications and more diverse ordinated by the Council for Scientific development and innovation across the industries; and and Industrial Research (CSIR); advanced metals value chain. - develop industrial localisation. • the Precious Metals Development Network (PMDN) for gold and the GOAL platinum group metals (PGMs), co- LIGHT METALS DEVELOPMENT NETWORK To target significant export income and new ordinated by Mintek; • Global demand for ultralight, industries for South Africa by 2020 through • the Nuclear Materials Development Network (NMDN) for hafnium, ultrastrong, recyclable metals is the country becoming a world leader in zirconium and monazite co-ordinated growing as the world switches to low- sustainable metals production and manu- by the Nuclear Energy Corporation of emission vehicles, energy-saving facturing via technological competence and South Africa (Necsa). devices and sustainable products. optimal, sustainable local manufacturing of • the Ferrous Metals Development • Aluminium demand is forecast to value-added products, while reducing Network (FMDN) for ferrous and base increase by 30% in the near future, environmental impact. metals, co-ordinated by Mintek. while for the emerging industrial light metal, titanium, the sky is the limit. To lead a global revolution in advanced metals generating significant export • For its part, South Africa has a mature STRATEGY income and new industries for South Africa aluminium industry, which is among the while reducing environmental impact.
    [Show full text]
  • The History of Fluorine-From Discovery to Commodity
    Educator Indian Journal of Chemical Technology Vol. 9. July 2002. pp. 363-372 The History of Fluorine-From discovery to commodity Jaime Wisniak* Department of Chemical Engineering. Ben-Gurian University of the Negev. Beer-Sheva. Israel 84105 Fluorine was the last of the halogens to be isolated. The extreme difficulties and dangers of handling it retarded substantial commercial applications until World War II when it became essential for the development of nuclear devices. Development of industrial processes for the manufacture of hydrogen Duoride and chloroDuorinated hydrocarbons turned Duorine and its derivatives into a major chemical commodity. The end use pattern of Duorine has reDected the changes in social appreciation of environmental protection and safety. Discovery offluorine An interesting aspect of the history of fluorine is The first historical reference regarding the use of that Andre-Marie Ampere (1775-1831) coined its fluorine compounds seems to be in the books of name before it was isolated. Ampere's interest in George Agricola (1494-1555), particularly in De Re chemistry led him to deduce that hydrogen fluoride l Metallica • When describing the manufacturing of was analogous to hydrogen chloride. He believed that metals, particularly iron, he wrote: Finally there now "silicated fluoric acid"(hydrofluoric acid) contained a remains those stones which I call stones which easiLy peculiar principle, analogous to chlorine and oxygen, meLt in the fire, because when thrown into hot united to the basis or silica, or silicum; the fluoboric furnaces they flow. According to Hoover and Hooverl acid of the same principle united to boron; and the there is little doubt that some of these stones included pure liquid fluoric acid as this principle united to fluorspar.
    [Show full text]
  • Fluorspar in 1999
    FLUORSPAR By M. Michael Miller Domestic survey data and tables were prepared by Cindy Chen, statistical assistant, and the world production table was prepared by Regina R. Coleman, international data coordinator. Traditionally, fluorspar has been considered to be vital to the fluorosilicic acid operations surveyed, 10 respondents reported Nation’s national security and economy. It is used directly or production, and 1 respondent reported zero production, indirectly to manufacture such products as aluminum, gasoline, representing 100% of the quantity reported. insulating foams, refrigerants, steel, and uranium fuel. Most Hastie Mining Co. washed, screened, and dried metallurgical- fluorspar consumption and trade involve either acid grade, and acid-grade fluorspar imported or purchased from the NDS. which is greater than 97% calcium fluoride (CaF2), or subacid Seaforth Mineral & Ore Co., Inc., dried and screened imported grade, which is 97% or less CaF2. The latter includes or NDS fluorspar at its facilities at Cave-In-Rock, IL, and East metallurgical and ceramic grades and is commonly called Liverpool, OH, as did Applied Industrial Materials Corp. at its metallurgical grade. facility at Aurora, IN. All domestic sources of fluorspar are derived from sales of In 1999, 5 companies operated 10 plants that processed material from the National Defense Stockpile (NDS) and from phosphate rock for the production of phosphoric acid and a small amount of synthetic fluorspar produced from industrial produced 69,200 t of byproduct fluorosilicic acid and sold or waste streams. Byproduct fluorosilicic acid production from used 69,100 t of byproduct fluorosilicic acid at a value of about some phosphoric acid producers supplements fluorspar as a $9.47 million.
    [Show full text]
  • Hydrochloricacid and Miscallaneous Inorganic Chemicals
    HYDROCHLORICACID AND MISCALLANEOUS INORGANIC CHEMICALS IRMAK ULUCAN SEDEF USLU ASIM KARAKUŞ TUĞRA BALCI AHMAD AYYASH INORGANIC CHEMICALS • Inorganic chemistry is the study of the synthesis and behavior of inorganic compounds. • Inorganic chemicals are substances of mineral origin that do not contain carbon in their molecular structures. • Many inorganic compounds are ionic compounds, consisting of cations and anions joined bu ionic bonding. • Inorganic chemistry is a highly practical area of science. • It has applications in every aspect of the chemical industry- including catalysis, materials science, pigments, surfactants, coatings, medicine, fuel, and agriculture. • Manufacturing inorganic chemicals involves many diverse processes to produce a wide variety of end products, including various degrees of purity and concentrations for each one. • Important classes of inorganic compounds include oxides, halides, carbonates and sulphates. List of inorganic chemicals with widespread use in various industries HYDROCHLORIC ACID • The chemical compound hydrochloric acid (or muriatic acid) is the aquaeos solution of hydrogen chloride gas. (Hydrogen chloride is very soluble in water.) • It is a highly corrosive, strong acid with many industrial uses. • Hydrogen chloride (HCl) is a monoprotic acid, which means it can ionize only once to give up one H+ ion (a single proton). In aqueous hydrochloric acid, the H+ joins a water molecule to form a hydronium + ion, H3O : + − HCl + H2O → H3O + Cl History of Hydrochloric Acid • Hydrogen chloride was discovered in the fifteenth century by Basilius Valentinius. • Commercial production of hydrochloric acid began in England when legislation was passed prohibiting the indiscriminate discharge of HCl in to the atmosphere. • As more uses of hydrochoric acid were discovered, plants were built solely for its production.
    [Show full text]
  • Taming the Dragon Called Φθόριο (Fluorine)
    F2 Taming the Dragon Called φθόριο Huaiju Wang Joint Group Meeting Mar. 30, 2018 Fragile organic molecules Mineral Sources of Fluorine Fluorite (fluorspar) Fluorapatite Cryolite CaF2 Ca5(PO4)3F Na3AlF6 Antozonite CaF2 Kraus, F.; et al. ACIE 2012, 51, 7847 History of Fluorine I think hydrofluoric acid My glass got corroded! has H and another 1771 element similar to Cl. Circa 1810 Carl Wilhelm Scheele Humphry Davy 1764 1810 Andreas Sigismund Marggraf André-Marie Ampère Mine too! It must be Let's call it "fluor-ine", an acid, say, "fluss- because, you know, spats-syran." chlor-ine. History of Fluorine Electrolysis of KHF2•HF 1886 in cooled platinum/iridium cell Henri Moissan Air F2 Cl2 History of Fluorine UF6 and fluorocarbons Freon and Teflon Circa 1940 Circa 1930 Manhattan Project GM and DuPont 4614 BIGELOW,PEARSON. COOK AND MILLER,JR. Val. 55 [CONTRIBUTION FROM THE CHEMICAL LABORATORYOB DUKE UNIVERSITY] The Action of Elementary Fluorine upon Certain Aromatic Organic Compounds under Various Conditions. I BY LUCIIJSA. BIGELOW,J. HERBERTPEARSON, LOUIS B. COOKAND WILLIAMT. MILLER,JR. Fluorine is the most reactive, as well as the most electronegative, of all the elements, and it is surprising, therefore, to find that the direct fluorination of organic compounds has received scant attention from Early Attempts with F2 earlier investigat0rs.l This is due in part to the enormous reactivity of the fluorine, which combines explosively with most organic compounds when the two are brought in contact; and in Dart also to the fact that the reactions of free fluorine, at least upon aromatic compounds, do F O O not seem to follow well-recog-F2 Me OH nized linesMe whichOH might be pre- O CCl , 0 ºC 4 F dicted by analogy and studied OH readily.
    [Show full text]
  • HYDROFLUORIC ACID 7664-39-3 F CAS N ° MANAGEMENT of EYE and SKIN CHEMICAL SPLASHES 2010 Edition
    HF Doc produit EN.qxd 3/06/10 15:04 Page 2 H PRODUCT FILE HYDROFLUORIC ACID ° 7664-39-3 F CAS n MANAGEMENT OF EYE AND SKIN CHEMICAL SPLASHES 2010 Edition ANTICIPATE AND SAVE Toxicology Laboratory & Chemical Risk Management www.prevor.com HF Doc produit EN.qxd 3/06/10 15:04 Page 2 H TABLE OF CONTENTS HYDROFLUORIC ACID MANAGEMENT OF EYE AND F SKIN CHEMICAL SPLASHES 1. KEY POINTS p3 1.1. Background p3 1.2. Names p3 1.3. Uses p3 2. LABELLING p4 2.1. Hazard levels according to concentration p4 2.2. Other classification p5 3. CHEMICAL CHARACTERISTICS p5 4. CORROSIVITY OF HYDROFLUORIC ACID p6 4.1 Chemical mechanisms p6 4.1.1. Corrosive effect p6 4.1.2. Toxic effect p6 4.2 Chemical injuries due to hydrofluoric acid p7 4.2.1. Cutaneous exposure p7 4.2.2. Ocular exposure p9 5. MANAGING ASSOCIATED RISKS p10 6. EMERGENCY RESPONSE TO HYDROFLUORIC ACID SPLASHES p11 6.1. Evaluation of washing methods p11 6.2. Experimental evidence p13 6.2.1. In vitro studies p13 6.2.2. Ex vivo studies p14 6.2.3. In vivo studies p16 6.3. Feedback on the use of Hexafluorine® p19 7. IN CONCLUSION, HOW SHOULD HEXAFLUORINE® BE USED? p24 8. DOCUMENTS AND REFERENCES p27 2 MANAGEMENT OF EYE AND SKIN CHEMICAL SPLASHES HF Doc produit EN.qxd 3/06/10 15:04 Page 3 S 1. KEY-POINTS 1.1. Background The history of hydrofluoric acid is linked to the history of fluorine because hydrogen fluoride was synthesized for the first time by C.W.
    [Show full text]
  • Magic Fluorine Chemistry for Medicinal Chemistry Applications
    NEACT 72 nd Annual Summer Conference St. Joseph’s College, Maine. August 1-4, 2011 Magic Fluorine Chemistry for Medicinal Chemistry Applications Wei Zhang University of Massachusetts Boston [email protected] Presentation Outline • Fluorine facts • History background • Commercial applications • Medicinal chemistry - Organofluorine Chemistry - Fluorous Chemistry Fluorine Facts Atomic Number: 9 Relative Atomic Mass: 18.998 Group # VIIA (halogens) Quantum # I = ½ (19 F NMR, MRI) 19 F Abundance ≈ 100% Element Van der Waals Electronegativity radii ( Å) (Pauling) F 1.47 3.98 Bond Average Average Bond O 1.52 3.44 Bond Strength Length N 1.55 3.04 (KJ/Mol) (Å) C 1.70 2.55 C-F 485 1.39 H 1.20 2.2 C-C 356 1.53 C-O 336 1.43 C-H 416 1.09 History of Fluorine • Hydrogen fluoride (HF) was first reported by Scheele in 1771. • In 1836 Dumas and Pelig reported the synthesis of organofluorine compound fluoromethane . • In 1886 Henri Moissan isolated molecular elemental fluorine gas (F 2). • Belgian chemist Swarts’ work between 1890 and 1938 on simple aliphatic fluorocarbons is widely considered as establishing the foundations of organofluorine chemistry . • The chemistry of perfluorinated (fully fluorinated) organic compounds began in 1926 when Lebeau and Damiens synthesized carbon tetrafluoride (CF 4). History of Fluorine (continue) • In the 1930’s, Midgley and Henne extended Swarts’ exchange reaction methods for chlorofluorocarbon (CFC). • In WWII, Uranium hexafluoride (UF 6) used in the U-235 enrichment process for making atomic bombs. • DuPont and GM were the pioneers of the application of CFCs as refrigerants . Later CFC’s found diverse applications as fire extinguishers, blowing/cleaning agents.
    [Show full text]
  • Hydride Transfer Reactions of Trifluoromethylated Allylic Alcohols
    Hydride transfer reactions of trifluoromethylated allylic alcohols and ketimines & nucleophilic trifluoromethylthiolation of Morita-Baylis-Hillman Carbonates Xiaoyang Dai To cite this version: Xiaoyang Dai. Hydride transfer reactions of trifluoromethylated allylic alcohols and ketimines & nucleophilic trifluoromethylthiolation of Morita-Baylis-Hillman Carbonates. Organic chemistry. INSA de Rouen, 2014. English. NNT : 2014ISAM0018. tel-01205406 HAL Id: tel-01205406 https://tel.archives-ouvertes.fr/tel-01205406 Submitted on 25 Sep 2015 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. THESE Présentée à : L’Institut National des Sciences Appliquées de Rouen En vue de l’obtention du grade de : Docteur en « Chimie Organique » Par Xiaoyang DAI Hydride Transfer Reactions of Trifluoromethylated Allylic Alcohols and Ketimines & Nucleophilic Trifluoromethylthiolation of Morita-Baylis-Hillman Carbonates Date de soutenance 12 Décembre 2014 Devant le jury composé de : Dr Thierry BILLARD (Rapporteur) Directeur de recherche CNRS, Université de Lyon 1 Dr Barbara MOHAR (Rapporteur) Directrice de recherche, National Institute of Chemistry, Ljubljana, Slovénie Dr Christine BAUDEQUIN (Examinatrice) Maître de conférences, Université de Rouen Dr Dominique CAHARD (Directeur de thèse) Directeur de recherche CNRS, Université de Rouen Acknowledgements Acknowledgements First and foremost, I would like to express my sincere appreciation to the juries of my PhD defense: Dr.
    [Show full text]