@phdthesis{Attia2003,
  author    = {Attia, Mohamad Ibrahim},
  title     = {Design, synthesis and pharmacological evaluation of certain GABAB agonists},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-7551},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2003},
  abstract  = {Ziel dieser Arbeit war die Synthese von (RS)-5-Amino-3-aryl(methyl)-pentans{\"a}ure Hydrochloride, 3-Aminomethyl-5-chlor-benzols{\"a}ure Hydrochlorid und(RS)-4-Amino-3-(4´-ethynyl(jod)-phenyl)-butans{\"a}ure Hydrochloride und die Testung der pharmakologischen Aktivit{\"a}t dieser Verbindungen. Die synthetisierten Verbindungen wurden als GABAB-Rezeptor Agonisten, in einem auf Ca2+-Messungen basierenden Funktional-Assay (in vitro tsA Zellen mit GABAB1b/GABAB2/G\&\#945;q-z5 transfektiert), getestet und daraus ein Struktur-Aktivit{\"a}ts Modell abgeleitet. Im allgemein Teil dieser Arbeit wird ein {\"U}berblick, {\"u}ber die Neurotransmitter- Rezeptoren (Liganden gesteuerte Ionen-Kanal-Rezeptoren und G Protein-gekoppelte Rezeptoren) des zentralen Nervensystems und deren Agonisten und Antagonisten, gegeben. Eine ausf{\"u}hrliche Diskussion zur Synthesestrategie der Verbindungen der Zwischenstufen und der Ausgangsmaterialien wird in den Schemata 2-6 beschrieben. Die synthetisierten Verbindungen wurden als GABAB Agonisten gepr{\"u}ft. Zus{\"a}tzlich wurden diese im 3D Homologie Modell mit FlexiDock Programm gedockt. Daraus wurde ein Modell zur Voraussage der Aktivit{\"a}t von Analogen und Homologen des Baclofens abgeleitet. Letztendlich wurde ein Pharmakophor-Modell f{\"u}r GABAB Agonisten mit DISCO (DIStance COmparisons) Programm erstellt.},
  subject      = {Baclofen},
  language  = {en}
}
@phdthesis{Kelm2002,
  author    = {Kelm, Bernd},
  title     = {A New Synthesis of enantiopure C-3-substituted Glutamates by Utilization of Ortho Ester protected (S)-Pyroglutamic acid},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-1296},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2002},
  abstract  = {Priority tasks of the present thesis were to generate various enantiopure C-3-substituted pyroglutamates as well as C-3-substituted glutamates, and furthermore to ameliorate the serious drawback of the bad atom-economy in the reaction sequence of previously published silylether-mediated procedures. To meet these requirements, the ortho ester functionality (OBO ester) developed by Corey was introduced. According to the plan of synthesis, the starting material, non-racemic (S)-pyroglutamic acid, was converted to the corresponding oxetane ester via a DCC-mediated esterification. The latter was N-protected to provide N-acceptor substituted pyroglutamic acid oxetane esters (Acceptor=Boc,Cbz,CO2Me). After rearrangement with boron trifluoride, the ortho ester derivatives (Acceptor=Cbz,CO2Me) were at hand and exclusively the N-Cbz derivative was converted to the corresponding alpha,beta-unsaturated lactam via a syn-elimination reaction. The formation of the C-3-substituted ortho ester compounds (R=methyl,ethyl,butyl,allyl,phenyl,4-chlorophenyl,biphenyl,naphthyl) was performed via a copper-mediated conjugate addition to the alpha,beta-enone system of the N-Cbz-alpha,beta-unsaturated lactam. The OBO functionality hence was envisaged to support perfect trans selectivity in this cuprate addition to the Michael system of the N-Cbz-alpha,beta-unsaturated lactam. Spectroscopic NMR-data, on the basis of 1H-, 13C- and DEPT spectra, proved the assumption that the C-3-substituted ortho ester derivatives exclusively are trans-configurated, i.e. the alkyl derivatives (R=methyl,ethyl,butyl,allyl) are (2S,3S)-configurated and the aryl derivatives (R=phenyl,4-chlorophenyl,biphenyl,naphthyl) are (2S,3R)-configurated). The C-3-substituted ortho ester derivatives were completely deprotected to yield the C-3-substituted pyroglutamates (R=ethyl,phenyl,4-chlorophenyl,naphthyl). Finally, ring opening reaction via route A-2 lead to the desired enantiopure C-3-substituted glutamates. Alternatively, latter preferably were reacted via route A-1 to yield the C-3-substituted glutamates (R=methyl,ethyl,butyl,phenyl,4-chlorophenyl,naphthyl). Their (2S,3R)-configuration (R=aryl) and (2S,3S)-configuration (R=alky), respectively, unambiguously was proved on the basis of available spectroscopic NMR-data. To ensure this assumption, diastereomeric (2S,3R)-3-methyl glutamic acid (i.e. cis-configurated) examplarily was synthesized via route A-3 and spectroscopic NMR-data was compared to that of (2S,3S)-3-methyl glutamic acid (i.e. trans-configurated). Conclusively, there can be recorded the fact that the serious drawback of the bad atom-economy in the reaction sequence previously used can be circumvented by the introduction of the OBO functionality, so the concept of an improved atom-economy is achieved. Additionally, in comparison to the silyl-ether-mediated synthesis, the OBO functionality provided crystalline ortho ester derivatives, which facilitated their purification as well as characterization.},
  subject      = {Glutamate},
  language  = {en}
}