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1	A study of the complexing behavior of sarcosine anhydride Poole, John W. January 1959 (has links) Thesis (Ph. D.)--University of Wisconsin--Madison, 1959. / Typescript. Abstracted in Dissertation abstracts, v. 20 (1959) no. 3, p. 895. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 101-104). Sarcosine anhydride.
2	Biochemical genetics of sarcosine and phasphate transport in human kidney. Glorieux, Francis H. January 1972 (has links) No description available. Kidneys. Biochemical genetics. Biological transport. Phosphates. Sarcosine X-linked hypophosphatemis
3	Preparation and Characterization of Kaolinite-based Nanocomposite Materials Czarnecka, Anna 06 August 2013 (has links) A kaolinite-nylon 6 composite was prepared by a polycondensation reaction from 6-aminohexanoic acid (AHA) intercalated in the kaolinite interlayer space. The basal spacing of kaolinite-AHA was 1.47 nm and the basal spacing of the heated products decreased to 1.16 nm. The signals attributed to nylon 6 were detected in the 13C CP/MAS NMR spectra of the heated products. Formation of nylon 6 in kaolinite was confirmed by appearance of IR band due to amide I and amide II. Sarcosine was intercalated in kaolinite for the first time by guest displacement with methanol from the kaolinite-methanol precursor. The basal spacing of kaolinite-sarcosine was 1.27 nm. This intercalation compound was characterized by NMR, TGA, XRD, and IR. The physical and chemical properties of natural clay sample from Mirandela formation (Portugal) were determined in terms of external skin treatment. The low CEC 4,45meq/100g is consistent with high content of kaolinite in the sample clay kaolinite nanocomposite nylon 6 sarcosine 6-aminohexanoic acid (AHA)
4	Preparation and Characterization of Kaolinite-based Nanocomposite Materials Czarnecka, Anna January 2013 (has links) A kaolinite-nylon 6 composite was prepared by a polycondensation reaction from 6-aminohexanoic acid (AHA) intercalated in the kaolinite interlayer space. The basal spacing of kaolinite-AHA was 1.47 nm and the basal spacing of the heated products decreased to 1.16 nm. The signals attributed to nylon 6 were detected in the 13C CP/MAS NMR spectra of the heated products. Formation of nylon 6 in kaolinite was confirmed by appearance of IR band due to amide I and amide II. Sarcosine was intercalated in kaolinite for the first time by guest displacement with methanol from the kaolinite-methanol precursor. The basal spacing of kaolinite-sarcosine was 1.27 nm. This intercalation compound was characterized by NMR, TGA, XRD, and IR. The physical and chemical properties of natural clay sample from Mirandela formation (Portugal) were determined in terms of external skin treatment. The low CEC 4,45meq/100g is consistent with high content of kaolinite in the sample clay kaolinite nanocomposite nylon 6 sarcosine 6-aminohexanoic acid (AHA)
5	Biochemical genetics of sarcosine and phasphate transport in human kidney. Glorieux, Francis H. January 1972 (has links) No description available. Biological transport. Phosphates. X-linked hypophosphatemis Sarcosine Kidneys. Biochemical genetics.
6	Novel Angiotensin II Binding Sites in the Mesopontine Area of the Rat Brain Rowe, Brian P., Saylor, David L., Speth, Robert C. 26 November 1990 (has links) Angiotensin II (AII) immunoreactivity in the mesopontine area of the rat brain is distributed through several areas where co-localization of AII receptors has not been established. The current in vitro receptor autoradiography study re-examined the distribution of AII binding using 125I-Sar1, Ile8-AII ([125I]SIAII). When incubations were conducted without sulfhydryl reducing agents, [125I]SIAII binding was observed in the locus coeruleus, inferior colliculus, superior colliculus and the central gray in agreement with previous reports. Novel [125I]SIAII binding sites were detected in the parabrachial nucleus, pedunculopontine tegmental nucleus and the caudal linear raphe nucleus, corresponding with previously reported localization of AII immunoreactivity in these nuclei. [125I]SIAII binding was also found in the paragenual nucleus where the peptide has not been detected. Thus, the observation of novel AII receptors which are sensitive to sulfhydryl reducing agents, resolves several AII-AII receptor mismatches. angiotensin autoradiography brain mesencephalon pons rat receptor Biomedical Sciences
7	Coordination Chemistry of Monocarboxylate and Aminocarboxylate Complexes at the Water/Goethite Interface Norén, Katarina January 2007 (has links) <p>This thesis is a summary of five papers with focus on adsorption processes of various monocarboxylates and aminocarboxylates at the water/goethite interface. Interaction of organic acids at the water/mineral interfaces are of importance in biogeochemical processes, since such processes have potential to alter mobility and bioavailability of the acids and metal ions.</p><p>In order to determine the coordination chemistry of acetate, benzoate, cyclohexanecarboxylate, sarcosine, MIDA (methyliminediacetic acid), EDDA (ethylenediamine-N,N’-diacetic acid) and EDTA (ethylenediamine-N,N’-tetraacetic acid) upon adsorption to the goethite (alpha-FeOOH) surface, a combination of quantitative measurements with attenuated total reflectance Fourier transform infrared spectroscopy (ATR-FTIR) was utilized.</p><p>Over the pH range studied here (pH 3- 9) all ligands, except for sarcosine, have been found to form surface complexes with goethite. In general, theses were characterized as outer sphere surface complexes i.e. with no direct interaction with surface Fe(III) metal ions. Furthermore, two types of different outer-sphere complexes were identified, the solvent-surface hydration-separated ion pair, and hydration-shared ion pair. For the monocarboxylate surface complexes distinction between these two could be made. At high pH values the solvent-surface hydration-separated ion pair was the predominating complex, while at low pH the surface complex is stabilized through the formation of strong hydrogen bonds with the goethite surface. However, it was not possible to clearly separate between the two outer-sphere complexes for coordination of the aminocarboxylates with the surface of goethite. Additionally, EDDA also formed an inner-sphere surface complex at high pH values. The EDDA molecule was suggested to coordinate to the surface by forming a five membered ring with an iron at the goethite surface, through the amine and carboxylate groups.</p><p>Contrary to the other ligands studied, EDTA significantly induced dissolution of goethite. Some of the dissolved iron, in the form of the highly stable FeEDTA- solution complex, was indicated to re-adsorb to the mineral surface as a ternary complex. Similar ternary surface complexes were also found in the Ga(III)EDTA/goethite system, and quantitative and spectroscopic studies on adsorption of Ga(III) in presence and absence of EDTA showed that EDTA considerably effects speciation of gallium at goethite surface.</p><p>The collective results in this thesis show that the affinity of these ligands for the surface of goethite is primarily governed by their chemical composition and structure, and especially important are the types, numbers and relative position of functional groups within the molecular structure.</p> Acetate benzoate adsorption surface complex ternary surface complexes ATR-FTIR spectroscopy EXAFS spectroscopy. cyclohexanecarboxylate sarcosine MIDA EDDA EDTA gallium(III) goethite mineral surface Chemistry Kemi
8	Transdermal Drug Delivery Enhanced by Magainin Peptide Kim, Yeu Chun 06 November 2007 (has links) The world-wide transdermal drug delivery market is quite large, but only a small number of agents have FDA approval. The primary reason for such limited development is the difficulty in permeating the stratum corneum layer of human skin. In our study, we developed a novel percutaneous delivery enhancing approach. Magainin peptide was previously shown to disrupt vesicles from stratum corneum lipid components and this ability of magainin allows us to propose that magainin can increase skin permeability. Therefore, we tested the hypothesis that magainin, a pore-forming peptide, can increase skin permeability by disrupting stratum corneum lipid structure and that magainin¡¯s enhancement requires co-administration of a surfactant chemical enhancer to increase magainin penetration into the skin. In support of these hypotheses, synergistic enhancement of transdermal permeation can be observed with magainin peptide in combination of N-lauroyl sarcosine (NLS) in 50% ethanol-PBS solution. The exposure to NLS in 50% ethanol solution increased in vitro skin permeability to fluorescein 15 fold and the addition of magainin synergistically increased skin permeability 47 fold. In contrast, skin permeability was unaffected by exposure to magainin without co-enhancement by NLS-ethanol. To elucidate the mechanism of this synergistic effect, several characterization methods such as differential scanning calorimetry, Fourier transform infrared spectroscopy, and X-ray diffraction were applied. These analyses showed that NLS-ethanol disrupted stratum corneum lipid structure and that the combination of magainin and NLS-ethanol disrupted stratum corneum lipids even further. Furthermore, confocal microscopy showed that magainin in the presence of NLS-ethanol penetrated deeply and extensively into stratum corneum, whereas magainin alone penetrated poorly into the skin. Together, these data suggest that NLS-ethanol increased magainin penetration into stratum corneum, which further increased stratum corneum lipid disruption and skin permeability. Finally, skin permeability was enhanced by changing the charge of magainin peptide via pH change. We modulated pH from 5 to 11 to change the magainin charge from positive to neutral, which decreased skin permeability to a negatively charged fluorescein and increased skin permeability to a positively charged granisetron. This suggests that an attractive interaction between the drug and magainin peptide improves transdermal flux. pH Ethanol N-lauroyl sarcosine Magainin Antimicrobial peptide Stratum corneum Chemical enhancer Transdermal drug delivery Drug delivery systems Transdermal medication Peptide drugs Skin Permeability
9	Sulfhydryl Reducing Agents Distinguish Two Subtypes of Angiotensin II Receptors in the Rat Brain Speth, Robert C., Rowe, Brian P., Grove, Kevin L., Carter, Michelle R., Saylor, David 10 May 1991 (has links) Two angiotensin II receptor subtypes were distinguished in the rat brain using in vitro receptor autoradiography based on the differential effects of sulfhydryl reducing agents on 125I-sarcosine1, isoleucine8 angiotensin II binding in various brain nuclei. At several nuclei, e.g. the hypothalamus, circumventricular organs and the dorsal medulla, 125I-sarcosine1, isoleucine8 angiotensin II binding was strongly inhibited by 30 mM β-mercaptoethanol or 5 mM dithiothreitol, whereas at other nuclei, e.g. the lateral septum, colliculi, locus coeruleus and medial amygdala, sulfhydryl reducing agents had either little effect on radioligand binding or enhanced the binding. The distribution of the sulfhydryl reducing agent inactivated subtype corresponds exactly with the distribution of DuP 753 sensitive (designated as AIIα) 125I-sarcosine1, isoleucine8 angiotensin II binding sites25. The subtype not inhibited by sulfhydryl reducing agents corresponds with the DuP 753 insensitive (designated as AIIβ) sites in the brain25. The sulfhydryl reducing agent effect on brain angiotensin II receptor subtypes is similar to that seen in angiotensin II receptor subtypes in peripheral tissues. These observations indicate that many previous studies of brain angiotensin II receptor binding that included 5 mM dithiothreitol in the assay medium overlooked the sulfhydryl reducing agent inactivated (AIIα) receptor subtype. 125 1 8 I-Sarcosine isoleucine angiotensin II angiotensin II receptor dithiothreitol in vitro receptor autoradiography rat receptor subtype sulfhydryl reducing agent β-Mercaptoethanol Biomedical Sciences
10	Coordination Chemistry of Monocarboxylate and Aminocarboxylate Complexes at the Water/Goethite Interface Norén, Katarina January 2007 (has links) This thesis is a summary of five papers with focus on adsorption processes of various monocarboxylates and aminocarboxylates at the water/goethite interface. Interaction of organic acids at the water/mineral interfaces are of importance in biogeochemical processes, since such processes have potential to alter mobility and bioavailability of the acids and metal ions. In order to determine the coordination chemistry of acetate, benzoate, cyclohexanecarboxylate, sarcosine, MIDA (methyliminediacetic acid), EDDA (ethylenediamine-N,N’-diacetic acid) and EDTA (ethylenediamine-N,N’-tetraacetic acid) upon adsorption to the goethite (alpha-FeOOH) surface, a combination of quantitative measurements with attenuated total reflectance Fourier transform infrared spectroscopy (ATR-FTIR) was utilized. Over the pH range studied here (pH 3- 9) all ligands, except for sarcosine, have been found to form surface complexes with goethite. In general, theses were characterized as outer sphere surface complexes i.e. with no direct interaction with surface Fe(III) metal ions. Furthermore, two types of different outer-sphere complexes were identified, the solvent-surface hydration-separated ion pair, and hydration-shared ion pair. For the monocarboxylate surface complexes distinction between these two could be made. At high pH values the solvent-surface hydration-separated ion pair was the predominating complex, while at low pH the surface complex is stabilized through the formation of strong hydrogen bonds with the goethite surface. However, it was not possible to clearly separate between the two outer-sphere complexes for coordination of the aminocarboxylates with the surface of goethite. Additionally, EDDA also formed an inner-sphere surface complex at high pH values. The EDDA molecule was suggested to coordinate to the surface by forming a five membered ring with an iron at the goethite surface, through the amine and carboxylate groups. Contrary to the other ligands studied, EDTA significantly induced dissolution of goethite. Some of the dissolved iron, in the form of the highly stable FeEDTA- solution complex, was indicated to re-adsorb to the mineral surface as a ternary complex. Similar ternary surface complexes were also found in the Ga(III)EDTA/goethite system, and quantitative and spectroscopic studies on adsorption of Ga(III) in presence and absence of EDTA showed that EDTA considerably effects speciation of gallium at goethite surface. The collective results in this thesis show that the affinity of these ligands for the surface of goethite is primarily governed by their chemical composition and structure, and especially important are the types, numbers and relative position of functional groups within the molecular structure. Acetate benzoate adsorption surface complex ternary surface complexes ATR-FTIR spectroscopy EXAFS spectroscopy. cyclohexanecarboxylate sarcosine MIDA EDDA EDTA gallium(III) goethite mineral surface Other Basic Medicine Annan medicinsk grundvetenskap

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