DOCSLIB.ORG

United States Patent 19 11 Patent Number: 5.675,038 Dolby Et Al

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
United States Patent 19 11 Patent Number: 5.675,038 Dolby Et Al USOO5675038A United States Patent 19 11 Patent Number: 5.675,038 Dolby et al. 45 Date of Patent: Oct. 7, 1997 54) LITHIUM AND AMNE DISSOLVING METAL Noordam et al. "Stereoselective synthesis (+)-pilocarpine, REDUCTION an imidazole alkaloid used in ophthalmology”. Recl. Trav. Chim. Pays-Bas 98, pp. 425-470, 75) Inventors: Lloyd J. Dolby; Nestor A. Fedoruk; Dey, A.N. “The Jaborandi Alkaloids. Part I. The Synthesis Shervin Esfandiari: Natalie C. of Homo-and isoHomo-pilopic Acids of r-Pilocarpine and Chamberlain, all of Eugene, Oreg.; r-isoPilocarpidine by New Methods and the Resolution of Michael E. Garst, Newport Beach, r-Pilocarpine". S. Chem. soc., (1937), pp. 1057-1065. Calif. Birch et al., "Reduction by Metal-Ammonia Solutions and Related Reagents”. Advanced Organic Chemistry, No. 8, pp. 73) Assignee: Allergan, Waco, Tex. 1-65 (1972). Benkeser et al. "Reduction of Organic Compounds by 21 Appl. No.: 685,902 Lithium in Low Molecular Weight Amines. VII. The Prepa 22 Filled: Jul. 18, 1996 ration of Dihydroaromatics. A Comparison of the Lithi um-Amine and Birch Reduction Systems". Journal of (51) Int. Cl. ............................. CO7C 291/00 Organic Chemistry, 28, pp. 1094-1096, 1972. (52) U.S. Cl. ........................... 564/253: 568/.303; 585/267 Kaiser, E.M., “A Comparison of Methods Using Lithium/ 58) Field of Search ............................ 585/267; 564/253; Amine and Birch Reduction Systems”. Synthesis, 1972, pp. 568/.303 39-415. 56 References Cited Primary Examiner-Mukund J. Shah U.S. PATENT DOCUMENTS Assistant Examiner-Bruck Kifle Attorney; Agent, or Firm-James M. Hoch; Robert J. Baran; 3,470.197 9/1969 VanDyke, Jr. .......................... 260/309 Martin A. Voet 5,055,467 10/1991 Albaugh....... S4/235.8 5,198,545 3/1993 Albaugh. ... 544/33 57 ABSTRACT 5,264449 11/1993 Albaugh. ..., 514/397 5,453,434 9/1995 Albaugh et al. ........................ 514/397 The invention is directed to a process for reducing or reductively cleaving an organic compound susceptible to OTHER PUBLICATIONS dissolving metal reduction comprising exposing the organic DeGraw, J.L. "Prostaglandins, An Improved Synthesis of compound to a solution of lithium in a polyamine including Pilocarpine.” Tetrahedron, vol. 28, 1972, pp. 967-972. at least two amino groups, selected from the group consist Koda et al., "Synthesis of Analogs related to Pilocarpine". ing of primary and secondary amino groups and mixtures Journal of Pharmaceutical Sciences, Dec. 1973, vol. 62, No. thereof, e.g. ethylenediamine and R-NH2, optionally con 12, pp. 2021-2023. taining a lower alkyl alcohol, wherein R is chosen from the Sauerberg et al., "Cyclic Carbamate Analogues of Pilo group consisting of ethyl, propyl, and butyl, including all carpine”. J. Med. Chem. 1989, 32, pp. 1322-1236. straight and branched chain isomers thereof, for a time Kondo et al. "Synthesis of y-Lactones By The Condensation sufficient to effect reduction. of 2-Alkene-1, 4-Diols With Orthocarboxylic Esters". Chemistry Letters, pp. 741-742, 1974. 35 Claims, No Drawings 5,675.038 1. 2 LTHUMAND AMNE DISSOLVING METAL from the solvent to form a radical which can in turn add REDUCTION another electron to form a further reduced anion and so forth until the reaction has reached completion. Alternatively, CROSS REFERENCE TO RELATED without an acidic proton source (i.e. a source of protons APPLICATIONS more acidic than ammonia or alkylamine) the reaction may proceed via a different route to form a less reduced or Commonly assigned U.S. patent application Ser. No. isomerically different product. 08/685,897, entitled "Process for Making Pilolactam and The use of lithium in a mixed solution of lower alkyl Derivatives Thereof" which has been filed on the same day amine and a polyamine, such as ethylenediamine, is a very as the present application in the names Lloyd J. Dolby, O Nestor A. Fedoruk, Sherwin Esfandiari, and Michael E. Garst potent reducing system which may be attributable to the is directed to a process of making an intermediate for the superior electron solvating ability of the ethylenediamine? synthesis of isopilolactam, pilolactam and derivatives alkyl amine solvent mixture. thereof. The contents of this copending application are A. J. Birch and G. Subba Rao reviewed many types of incorporated herein by reference in its entirety, dissolving metal reductions in a monograph entitled "Reduc 15 tion by Metal-Ammonia Solutions and Related Reagents" in BACKGROUND OF THE INVENTION Advanced Organic Chemistry, No. 8, pp. 1-65 (1972). R. A. Benkeser, et al., (Journal of Organic Chemistry; 28, FIELD OF THE INVENTION pp. 1094-96 (1962) described the use of low molecular weight amines in lithium metal reductions and compared the The invention described herein relates generally to the 20 field of reductive hydrogenation of organic compounds. In yields and regioisomers to reductions of the same group of particular, the invention relates to the treatment of organic compounds using Birch reduction conditions. compounds by lithium in a mixture of a lower molecular Edwin M. Kaiser wrote a review entitled “A Comparison weight amine and a polyamine including at least two amino of Methods Using Lithium/Amine and Birch Reduction groups, selected from the group consisting of primary and 25 Systems" Synthesis, 1972 pp. 391-415) which also com secondary amino groups and mixtures thereof, e.g. pares reports of yields and conditions for these two reaction ethylenediamine, to effect reduction. types. SUMMARY OF THE INVENTION BACKGROUND OF THE ART The invention is directed to a process for reducing or Reductions using alkali metals in ammonia or lower alkyl 30 reductively cleaving an organic compound susceptible to amines are synthetically useful reactions for the reduction of dissolving metal reduction comprising exposing the organic organic compounds. The metals commonly employed compound to lithium in a mixed solution of a polyamine include the alkali metals-lithium, sodium and potassium including at least two amino groups, selected from the group as well as calcium and magnesium and occasionally zinc and 35 consisting of primary and secondary amino groups and iron. The alkali metals and calcium dissolve into solutions in mixtures thereof, wherein said polyamine comprises from 2 liquid ammonia (b.p. -33°C.), in low molecular weight to 4. e.g. 2, nitrogen atoms and from 2 to about 30, e.g. from amines such as methylamine and ethylamine, or in certain 2 to about 20 carbon atoms, and may be selected from the ethers such as 1,2-dimethoxyethane. Reactions with metal group consisting of alkyl and cycloalkyl amines such as solutions in liquid ammonia often use a cosolvent such as ethylenediamine, N,N'-dimethylethylenediamine. ether, tetrahydrofuran, or 1,2-dimethoxyethane to increase piperazine, diaminopropane, diaminobutane, dimethyl the solubility of the organic substrate in the reaction mixture. diaminobutane, tris-(aminoethyl) amine, etc., e.g This sometimes has the disadvantage of resulting in a two ethylenediamine, and R-NH wherein R is selected from phase reaction mixture. the group consisting of lower alkyl radicals. having from 2 The Birch reduction is perhaps the best known form of 45 to 6 carbon atoms, preferably ethyl, propyl, and butyl, these metal reductions and utilizes sodium metal, liquid including all straight and branched chain isomers thereof, ammonia, and an alkyl alcohol such as n-butanol or optionally containing a lower alkyl alcohol, for a time t-butanol. The Benkeser reduction is another form of the sufficient to effect reduction. reduction which utilizes lithium metal and a lower alkyl The present process for reducing susceptible organic amine along with one of the already mentioned alcohols. 50 chemical compounds uses lithium metal as an electron These reductions as a class are called dissolving metal source, the above lower alkyl amines as solvent and the reductions; this term being descriptive since the metals above polyamine, e.g. ethylene diamine (1.2- dissolve into solution which is generally blue in color as a diaminoethane), as the cosolvent. Lithium is dissolved in the result of ionization of the metal atoms. alkyl amine along with at least one equivalent of said A proton source (frequently ethanol, isopropanol. 55 polyamine, e.g. ethylenediamine, per gram-atom of lithium. t-butanol, or water) may be necessary and present in the Optionally, a lower alkyl alcohol can be added to the reaction medium, and is added concurrently with the com solution to improve yields of desired products. A discussion pound to be reduced, or is added during the isolation. of these protonation mechanisms and reaction kinetics can An early hypothesis that dissolving metal reductions were be found in the review on dissolving metal reductions by effected by reaction of the "nascent'hydrogen liberated from Birch, et al. (vide supra). reduction of the hydroxylic solvent by the metal with the Examples of compounds susceptible of being reduced or molecule being reduced has since been dismissed as unten reductively cleaved by this system (products follow in able. In fact, the formation of hydrogen gas during these parentheses) are: anisoles (methoxycyclohexadienes), naph reactions is normally an undesirable side reaction which thalenes (isotetralins). O.B-unsaturated ketones (ketones), makes the use of excess metal necessary, Presently it is 65 ketoximes (amines), aldoximes (amines), thioanisoles believed that "solvated" electrons in the solution add to the (thiophenols), reduction of tertiary amides, cleavage of Substrate to form a radical anion which can add a proton sulfonate esters (to the alcohols) and reductions of 5,675,038 3 4 p-toluenesulfonamides (to amines, or in the case of tertiary solved into the solvent, the reaction is considered to have sulfonamides to the thiophenol). finished. Time spans of between 5 minutes and 24 hours are typically required. DETALED DESCRIPTION OF THE Once the reaction is complete, the solvent phase is cus INVENTION tomarily removed under reduced pressure, typically on a Preliminary experiments with lithium in lower alkyl rotary evaporator, which allows recovery of the solvents amines alone, such as in n-propylamine or isopropylamine from the reaction mixture.
Load more

Recommended publications
  • Supporting Information
    Electronic Supplementary Material (ESI) for Journal of Materials Chemistry C. This journal is © The Royal Society of Chemistry 2017 Supporting Information Colorimetric Sensor Array for Amines based on Responsive Lanthanide Complex Entrapment Peng Li, Zhiqiang Li, Decui Yao, and Huanrong Li* School of Chemical Engineering and Technology, Hebei University of Technology, Guang Rong Dao 8, Hongqiao District, Tianjin 300130, P. R. China. *E-mail: [email protected] 1 Figure S1 Molecular structure of HFA. Figure S2 XRD pattern of zeolite Y (ZY) Figure S3 SEM images of zeolite Y (ZY) 2 Figure S4 a) Emission spectra of Eu1Tb9(HFA)n@ZY after treatment with various amine vapors using an excitation wavelength of 302 nm. (Eu1Tb9(HFA)n@ZY (red line), aniline (green line), Benzylamine (blue line), Propylamine (cyan line), 1,3-Propanediamine (magenta line), Ethylenediamine (yellow line), Triethylamine (dark yellow line), Cyclohexylamine (navy line), Methylamine (purple line), N- Methylaniline (wine line), Butylamine (olive line), ammonia (dark cyan line), Tert-butylamine (royal line), Ethylamine (orange line)) b) The relative emission intensity at 612 nm and at 544 nm (IEu/ITb) of Eu1Tb9(HFA)n@ZY excitated at 302 nm upon treatment with various amine solvent vapors. (a: Eu1Tb9(HFA)n@ZY, b: Aniline, c: Benzylamine, d: Propylamine, e: 1,3-Propanediamine, f: Ethylenediamine, g: Triethylamine, h: Cyclohexylamine, i: Methylamine, j: N- Methylaniline , k: Butylamine, l: Ammonia, m: Tert-butylamine and n: Ethylamine) 3 Figure S5 a) Emission spectra of Eu0.5Tb9.5(HFA)n@ZY
    [Show full text]
  • Neighboring Hetero-Atom Assistance of Sacrificial Amines to Hydrogen Evolution Using Pt-Loaded Tio2-Photocatalyst
    Catalysts 2014, 4, 162-173; doi:10.3390/catal4020162 OPEN ACCESS catalysts ISSN 2073-4344 www.mdpi.com/journal/catalysts Article Neighboring Hetero-Atom Assistance of Sacrificial Amines to Hydrogen Evolution Using Pt-Loaded TiO2-Photocatalyst Masahide Yasuda 1,*, Takayuki Tomo 1, Shoichi Hirata 1, Tsutomu Shiragami 1 and Tomoko Matsumoto 2 1 Department of Applied Chemistry, Faculty of Engineering, University of Miyazaki, Gakuen-Kibanadai Nishi, Miyazaki 889-2192, Japan; E-Mails: [email protected] (T.T.); [email protected] (S.H.); [email protected] (T.S.) 2 Center for Collaborative Research and Community Cooperation, University of Miyazaki, Gakuen-Kibanadai Nishi, Miyazaki 889-2192, Japan; E-Mail: [email protected] * Author to whom correspondence should be addressed; E-Mail: [email protected]; Tel.:+81-985-7314. Received: 27 February 2014; in revised form: 12 May 2014 / Accepted: 13 May 2014 / Published: 26 May 2014 Abstract: Photocatalytic H2 evolution was examined using Pt-loaded TiO2-photocatalyst in the presence of amines as sacrificial agents. In the case of amines with all of the carbon attached to the hetero-atom such as 2-aminoethanol, 1,2-diamonoethane, 2-amino-1,3-propanediol, and 3-amino-1,2-propanediol, they were completely decomposed into CO2 and water to quantitatively evolve H2. On the other hand, the amines with both hetero-atoms and one methyl group at the β-positions (neighboring carbons) of amino group such as 2-amino-1-propanol and 1,2-diaminopropane were partially decomposed. Also, the photocatalytic H2 evolution using amines without the hetero-atoms at the β-positions such as ethylamine, propylamine, 1-butylamine, 1,3-diaminopropane, 2-propylamine, and 2-butylamine was inefficient.
    [Show full text]
  • Chemical Compatibility Storage Group
    CHEMICAL SEGREGATION Chemicals are to be segregated into 11 different categories depending on the compatibility of that chemical with other chemicals The Storage Groups are as follows: Group A – Compatible Organic Acids Group B – Compatible Pyrophoric & Water Reactive Materials Group C – Compatible Inorganic Bases Group D – Compatible Organic Acids Group E – Compatible Oxidizers including Peroxides Group F– Compatible Inorganic Acids not including Oxidizers or Combustible Group G – Not Intrinsically Reactive or Flammable or Combustible Group J* – Poison Compressed Gases Group K* – Compatible Explosive or other highly Unstable Material Group L – Non-Reactive Flammable and Combustible, including solvents Group X* – Incompatible with ALL other storage groups The following is a list of chemicals and their compatibility storage codes. This is not a complete list of chemicals, but is provided to give examples of each storage group: Storage Group A 94‐75‐7 2,4‐D (2,4‐Dichlorophenoxyacetic acid) 94‐82‐6 2,4‐DB 609-99-4 3,5-Dinitrosalicylic acid 64‐19‐7 Acetic acid (Flammable liquid @ 102°F avoid alcohols, Amines, ox agents see SDS) 631-61-8 Acetic acid, Ammonium salt (Ammonium acetate) 108-24-7 Acetic anhydride (Flammable liquid @102°F avoid alcohols see SDS) 79‐10‐7 Acrylic acid Peroxide Former 65‐85‐0 Benzoic acid 98‐07‐7 Benzotrichloride 98‐88‐4 Benzoyl chloride 107-92-6 Butyric Acid 115‐28‐6 Chlorendic acid 79‐11‐8 Chloroacetic acid 627‐11‐2 Chloroethyl chloroformate 77‐92‐9 Citric acid 5949-29-1 Citric acid monohydrate 57-00-1 Creatine 20624-25-3
    [Show full text]
  • Supplementary Information
    Electronic Supplementary Material (ESI) for Green Chemistry. This journal is © The Royal Society of Chemistry 2016 Supplementary Information 1 CAS No. Chemical Name Table1 Motivating example. Data for five properties and seven 30 109-56-8 2-Isopropylaminoethanol hypothetical solvents. 31 4620-70-6 2-(tert-Butylamino)ethanol CO Vapour Surface 2 Viscosity Acute Solubilit 32 1120-48-5 Di-n-octylamine Solvents Pressure Tension (cP) Toxicity y (mbar) (dyne/cm) 33 621-77-2 Tripentylamine (MPa0.5) A 0.57 9.98 21.69 0.37 36.4 34 2212-32-0 2-[2- B 1.32 6.37 34.28 0.20 17.4 dimethylaminoethyl(methyl)amino]ethanol C 0.77 4.51 27.51 0.12 8.9 35 622-93-5 3-Diethylamino-1-propanol D 1.18 5.97 23.26 0.17 23.7 36 100-37-8 N,N-Diethylethanolamine E 0.94 9.33 34.35 0.22 6.3 37 13330-96-6 4-(dimethylamino)-1-Butanol F 1.08 8.34 28.85 0.28 27.1 38 16369-21-4 2-(propylamino)ethanol G 1.8 7.55 33.66 0.28 32.5 39 5966-51-8 1,3-Bis(dimethylamino)-2-propanol 40 373-44-4 1,8-Diaminooctane Table2 CAS numbers and Chemical Name of 125 solvents. 41 646-19-5 1,7-Diaminoheptane 42 124-09-4 1,6-Hexanediamine CAS No. Chemical Name 43 462-94-2 1,5-Diaminopentane 1 110-18-9 N,N,N',N'-Tetramethylethylenediamine 44 110-60-1 1,4-Diaminobutane 2 110-96-3 Diisobutylamine 45 39884-48-5 4-Amino-2-butanol 3 626-23-3 Disec-butylamine 46 109-76-2 1,3-Diaminopropane 4 39099-23-5 N-Isopropylbutylamine 47 78-96-6 DL-1-Amino-2-propanol 5 20634-92-8 Ethyldi-N-propyl amine 48 13532-77-9 5-Amino-2,2-dimethylpentanol 6 4444-68-2 N,N-diethylbutan-1-amine 49 4048-33-3 6-Amino-1-hexanol 7 111-92-2
    [Show full text]
  • Isopropylamine 75-31-0
    Isopropylamine 75-31-0 Review of Toxicological Literature (Update of March 1997 Review) Prepared for Errol Zeiger, Ph.D. National Institute of Environmental Health Sciences PO Box 12233 Research Triangle Park, North Carolina 27709 Contract No. N01-ES-65402 Submitted by Raymond Tice, Ph.D. Integrated Laboratory Systems Post Office Box 13501 Research Triangle Park, North Carolina 27709 February 1998 EXECUTIVE SUMMARY Isopropylamine was nominated for testing based on its high production volume, ubiquitous natural occurrence, and the lack of chronic study data. Isopropylamine can be produced from the corresponding alcohol by reacting with ammonia in the presence of a dehydrating catalyst, from the chloride by reacting with ammonia under pressure, from acetone and ammonia, or from the acetone oxime. In the U.S., about 50,000 tons (45,000 Mg) of isopropylamine are produced annually. U.S. producers include Air Products and Chemicals, Inc. (Pace, Florida and St. Gabriel, Louisiana), Elf Atochem North America, Inc. (Riverview, Michigan), and Hoechst Celanese Corp. (Bucks, Alabama). Isopropylamine is used as a dehairing agent; as a solvent; as an intermediate in the production of insecticides, herbicides, bactericides, pharmaceuticals, dyes, and rubber accelerators; for the production of surface active agents, including dodecylbenzenesulfonic acid isopropylamine salt; and for the purification of penicillin and streptomycin. Isopropylamine is present in certain plants, foods, and in white wines. It is released into ambient air from cigarette smoke, effluents, and decomposing animal manure. Isopropylamine exists mainly in protonated form in aquatic environments, and based on its miscibility in water, absorption and bioconcentration are not expected to be important fate processes.
    [Show full text]
  • United States Patent Office Patented Apr
    3,658,836 United States Patent Office Patented Apr. 25, 1972 1. 2 the mol ratio of boric acid to amine and therefore if a 3,658,836 . mol ratio of less than 5:1, respectively, is used unreacted HYDROXYBOROXN-AMNE SALTS . amine will remain. Billy Dale Vineyard, St. Louis, Mo. assignor to Conveniently the preparation of the above-described Monsanto Company, St. Louis, Mo. - salts is conducted using a reaction medium which may No Drawing. Filed Apr. 16, 1964, Ser. No. 360,411 form a homogeneous or heterogeneous reaction mass. Int, C. C07d 49/34 Suitable reaction media are aromatic hydrocarbons such U.S. C. 260-309.7 6 Claims as benzene, toluene and xylene, alone or with water. Also an excess of the amine reactant will suffice as a reaction ABSTRACT OF THE DISCLOSURE O medium. The use of benzene is preferred since its use allows removal of water by azeotropic distillation at a This invention relates to hydroxyboroxin-amine Salts relatively low temperature after completing the reaction. which are prepared by reacting boric acid with an amine Typical materials which can be used to form the salts as described hereinafter. The compounds are useful inter of this invention are the mono-, di- and trialkyl amines alia as fungicides and additives for lubricating oils. 15 in which each alkyl group has from 1 to 20 carbons, such as methylamine, ethylamine, n-propylamine, isopropyl amine, n-butylamine, isobutylamine, sec-butylamine, amyl This invention relates to new hydroxyboroxin-amine amine, n-heptylamine, n-hexylamine, 1,1,3,3-tetramethyl salts which can be represented by the structure butylamine, n-octylamine, 2-ethylhexylamine, isooctyl C 20 amine, nonylamine, 2,2,4,4-tetramethylpentylamine, n-dec g EO - YB - Ois Y4 ylamine, isodecylamine, dodecylamine, 1,1,3,3,5,5-hexa Ba.
    [Show full text]
  • Consolidated List of Chemicals Subject to EPCRA + Section 112(R)
    United States Office of Land EPA 550-B-20-001 Environmental Protection and August 2020 Agency Emergency Management www.epa.gov/epcra LIST OF LISTS Consolidated List of Chemicals Subject to the Emergency Planning and Community Right- To-Know Act (EPCRA), Comprehensive Environmental Response, Compensation and Liability Act (CERCLA) and Section 112(r) of the Clean Air Act • EPCRA Section 302 Extremely Hazardous Substances • CERCLA Hazardous Substances • EPCRA Section 313 Toxic Chemicals • CAA 112(r) Regulated Chemicals for Accidental Release Prevention TABLE OF CONTENTS Introduction ..................................................................................................................................... 1 List of Lists: Consolidated List of Chemicals (By CAS Number) ................................................. 1 Appendix A: Consolidated List of Chemicals (By Alphabetical Name) .................................... A-1 Appendix B: Radionuclides Listed Under CERCLA ................................................................. B-1 Appendix C: RCRA Waste Streams and Unlisted Hazardous Wastes ....................................... C-1 Appendix D: EPCRA Section 313, Toxic Release Inventory (TRI) Chemical Categories ........ D-1 Appendix E: ................................................................................................................................. E-1 EPCRA Section 313 (TRI) PER- and Polyfluoroalkyl Substances CAS Number Listing ................... E-1 EPCRA Section 313 (TRI) PER- and Polyfluoroalkyl Substances
    [Show full text]
  • (12) United States Patent (10) Patent No.: US 8.445,726 B2 Wigbers Et Al
    USOO8445726B2 (12) United States Patent (10) Patent No.: US 8.445,726 B2 Wigbers et al. (45) Date of Patent: May 21, 2013 (54) PROCESS FOR PREPARING UNSYMMETRIC OTHER PUBLICATIONS SECONDARY TERT BUTYLAMINES IN THE U.S. Appl. No. 13/119,948, filed Mar. 18, 2011, Ernst, et al. LIQUID PHASE U.S. Appl. No. 13/080,885, filed Apr. 6, 2011, Mueller, et al. International Search Report issued May 24, 2011, in Patent Applica (75) Inventors: Christof Wilhelm Wigbers, Mannheim tion No. PCT/EP2011/055372 (with English Translation of Category (DE); Christoph Mueller, Mannheim of Cited Documents). (DE); Johann-Peter Melder, Leonard M. Weinstock, et al., “Synthesis of the B-Adrenergic Block Boehl-Iggelheim (DE); Bernd Stein, ing Agent Timolol from Optically Active Precursors”, Journal of Alsbach-Haehnlein (DE); Harald Organic Chemistry, vol. 41, No. 19, XP 2634073, 1976, pp. 3121 Meissner, Hassloch (DE); Gerd 3124. Haderlein, Gruenstadt (DE); Norbert Zhenliang Chen, et al., “The synthesis of baclofen and GABOB via Gutfrucht, Lambrecht (DE) Rh(II) catalyzed intramolecular C-H insertion of O-diazoacetamides', Tetrahedron, vol. 61, No. 6, XP 25382974, (73) Assignee: BASFSE, Ludwigshafen (DE) 2005, pp. 1579-1586. “Houben-Weyl, Methoden der organischen Chemie', Georg Thieme Verlag, 4' Edition, vol. XI/1, XP 2634072, 1959, pp. 618-634. (*) Notice: Subject to any disclaimer, the term of this Jeffrey C. Bottaro, et al., “Improved Synthesis of Cubane-1,2,4,7- patent is extended or adjusted under 35 tetracarboxylic Acid'. Journal of Organic Chemistry, vol. 56, 1991, U.S.C. 154(b) by 114 days. pp. 1305-1307.
    [Show full text]
  • Rev. 23 Table 2: Pacs by Chemical Name (Pdf)
    Table 2: Protective Action Criteria (PAC) Rev 23 based on applicable AEGLs, ERPGs, or TEELs (chemicals listed in alphabetical order) PAC Rev 23 – August 2007 Table 2 presents an alphabetical listing of the chemicals in the PAC data set and provides Chemical Abstracts Service Registry Numbers (CAS RNs)1, PAC data, and technical comments focusing on changes in the PACs since the previous version of the PAC/TEEL data set (Rev 21). PACs are provided for TEEL-0 (i.e., PAC-0), PAC-1, PAC-2, and PAC-3. Values are usually given in parts per million (ppm) for gases and volatile liquids and in milligrams per cubic meter (mg/m3) for particulate materials (aerosols) and nonvolatile liquids. The columns presented in Table 2 provide the following information: Heading Definition No. The ordered numbering of the chemicals as they appear in this alphabetical listing. Chemical The common name of the chemical compound. Compound CAS RN The Chemical Abstracts Service Registry Number for this chemical. TEEL-0 This is the threshold concentration below which most people will experience no appreciable risk of health effects. This PAC is always based on TEEL-0 because AEGL-0 or ERPG-0 values do not exist. PAC-1 Based on the applicable AEGL-1, ERPG-1, or TEEL-1 value. PAC-2 Based on the applicable AEGL-2, ERPG-2, or TEEL-3 value. PAC-3 Based on the applicable AEGL-3, ERPG-3, or TEEL-3 value. Units The units for the PAC values (ppm or mg/m3). Comments Technical comments by the developers of the PAC data set.
    [Show full text]