Global ETD Search

1	Die Bedeutung von Pneumolysin für die Entstehung des akuten Lungenversagens bei Pneumokokkenpneumonie eine experimentelle Untersuchung Gutbier, Birgitt January 2008 (has links) Zugl.: Berlin ; Freie Univ., Diss., 2008
2	Molecular analysis of adenylyl cyclase : bacillus anthracis edema factor exotoxin Mohammed, Hesham Hamada Taha January 2009 (has links) Regensburg, Univ., Diss., 2009.
3	Die Bedeutung von Pneumolysin für die Entstehung des akuten Lungenversagens bei Pneumokokkenpneumonie : eine experimentelle Untersuchung / Gutbier, Birgitt. January 2009 (has links) Zugl.: Berlin ; Freie Universiẗat, Diss., 2008.
4	The Round Window Membrane - Gateway to the Cochlea : A Morphological and Electrophysiological study Nordang, Leif January 2002 (has links) <p>Topical treatment of several inner ear diseases through the round window membrane (RWM) might be feasible in the near future. Bacteria toxins, ototoxic drugs and noise trauma seem to harm the inner ear by a common pathway which involves, excessive outflow of the afferent neurotransmitter glutamate and formation of nitric oxide (NO), which can severely damage cells/nerve endings and lead to cell death.</p><p>In this study we used 98 Sprague-Dawley rats and seven human temporal bones. Various substances were instilled into the middle ear of the rat, such as Pseudomonas Aeruginosa Exotoxin (PaExoA), gentamicin, NO-inhibitor N-Omega-Nitro-L-Arginine Methyl Ester (L-NAME), and glucocorticoids. The effects of the substances were studied by morphological analysis of RWM and the endolymphatic sac (ES) by light and electron microscopic. Hearing level was measured in the rats by ABR technique. The human temporal bones were studied immunomorphologically to search for glutamate.</p><p>In the human inner ear, glutamate receptors and glutamine synthetase, were identified. In the rat, we found, following PaExoA exposure, reversible and permanent hearing loss and morphological changes in the RWM. The ES showed increased numbers of macrophages and thickening of the epithelia. When L-NAME was used as an otoprotector from gentamicin ototoxicity a therapeutic effect in the high frequency area was found. Hydrocortisone (but not dexamethasone) exposure of the RWM resulted in membrane thickening, and adjacent to the membrane, inflammatory cells.</p><p>The importance of the RWM as a portal for toxic substances and topical treatment of inner ear diseases was highlighted in this study. The difficulties of applying drugs in the round window niche were exposed. The results of this study add important knowledge concerning certain mechanisms of inner ear injury and help us to understand possibilities and problems of local treatment of inner ear diseases in patients.</p> Otorhinolaryngology round window membrane pseudomonas exotoxin auditory brainstem response hearing loss endolymphatic sac inner ear immunology glutamate nitric oxide inhibitor glucocorticoid. Otorhinolaryngologi Otorhinolaryngology Otorhinolaryngologi
5	Antibiotic-induced Bacterial Toxin Release – Inhibition by Protein Synthesis Inhibitors Hjerdt-Goscinski, Gunilla January 2004 (has links) <p>Toxic products, such as endotoxin from the gram-negative and exotoxin from the gram-positive bacteria, are the most important initiators of the inflammatory host response in sepsis. In addition to antibacterial treatment, numerous attempts have been made to interfere with the exaggerated proinflammatory cascade initiated by the toxins. As most antitoxic and anti-inflammatory agents have shown no clear efficacy, an attractive alternative has been to prevent or minimise their release. Therefore, it was of interest to further study the antibiotic-induced release of toxins after exposure to antibiotics used for the treatment of the most severe infections, especially if protein synthesis inhibitors could reduce the release induced by PBP 3-specific β-lactam antibiotics.</p><p>There were significant reductions in endotoxin release from gram-negative bacteria when the combination of the PBP 3-specific β-lactam antibiotic, cefuroxime, and the protein synthesis inhibitor, tobramycin, was compared with cefuroxime alone. Increasing doses of tobramycin reduced endotoxin release and increased the killing rate. In a kinetic <i>in vitro</i> model the endotoxin release from <i>E.coli</i> was higher after the second dose of cefuroxime. Nevertheless, it was reduced after addition of tobramycin.</p><p>No binding of tobramycin to endotoxin was observed, either <i>in vivo</i> or <i>in vitro</i>. In a porcine sepsis model, a possible anti-inflammatory effect of ceftazidime and tobramycin, expressed as late cytokine inhibition, was seen.</p><p>The protein synthesis inhibitor, clindamycin, released less streptococcal pyrogenic exotoxin A (SpeA) from a group A streptococcus strain than penicillin, and addition of clindamycin to penicillin resulted in less toxin production than penicillin alone. The SpeA production was dependent on the bacterial number at the start of treatment. Higher doses of penicillin also led to less SpeA. </p><p>The choice of antibiotic class and dose may be important in the severely ill septic patient in whom an additional toxin release could be deleterious. A combination of a β-lactam antibiotic and a protein synthesis inhibitor seems beneficial but further investigations are needed.</p> Communicable diseases Endotoxin LPS exotoxin SpeA penicillin-binding protein aminoglycosides clindamycin β-lactam antibiotics severe sepsis septic shock Infektionssjukdomar Infectious diseases Infektionssjukdomar
6	The Round Window Membrane - Gateway to the Cochlea : A Morphological and Electrophysiological study Nordang, Leif January 2002 (has links) Topical treatment of several inner ear diseases through the round window membrane (RWM) might be feasible in the near future. Bacteria toxins, ototoxic drugs and noise trauma seem to harm the inner ear by a common pathway which involves, excessive outflow of the afferent neurotransmitter glutamate and formation of nitric oxide (NO), which can severely damage cells/nerve endings and lead to cell death. In this study we used 98 Sprague-Dawley rats and seven human temporal bones. Various substances were instilled into the middle ear of the rat, such as Pseudomonas Aeruginosa Exotoxin (PaExoA), gentamicin, NO-inhibitor N-Omega-Nitro-L-Arginine Methyl Ester (L-NAME), and glucocorticoids. The effects of the substances were studied by morphological analysis of RWM and the endolymphatic sac (ES) by light and electron microscopic. Hearing level was measured in the rats by ABR technique. The human temporal bones were studied immunomorphologically to search for glutamate. In the human inner ear, glutamate receptors and glutamine synthetase, were identified. In the rat, we found, following PaExoA exposure, reversible and permanent hearing loss and morphological changes in the RWM. The ES showed increased numbers of macrophages and thickening of the epithelia. When L-NAME was used as an otoprotector from gentamicin ototoxicity a therapeutic effect in the high frequency area was found. Hydrocortisone (but not dexamethasone) exposure of the RWM resulted in membrane thickening, and adjacent to the membrane, inflammatory cells. The importance of the RWM as a portal for toxic substances and topical treatment of inner ear diseases was highlighted in this study. The difficulties of applying drugs in the round window niche were exposed. The results of this study add important knowledge concerning certain mechanisms of inner ear injury and help us to understand possibilities and problems of local treatment of inner ear diseases in patients. Otorhinolaryngology round window membrane pseudomonas exotoxin auditory brainstem response hearing loss endolymphatic sac inner ear immunology glutamate nitric oxide inhibitor glucocorticoid. Otorhinolaryngologi Otorhinolaryngology Otorhinolaryngologi
7	Antibiotic-induced Bacterial Toxin Release – Inhibition by Protein Synthesis Inhibitors Hjerdt-Goscinski, Gunilla January 2004 (has links) Toxic products, such as endotoxin from the gram-negative and exotoxin from the gram-positive bacteria, are the most important initiators of the inflammatory host response in sepsis. In addition to antibacterial treatment, numerous attempts have been made to interfere with the exaggerated proinflammatory cascade initiated by the toxins. As most antitoxic and anti-inflammatory agents have shown no clear efficacy, an attractive alternative has been to prevent or minimise their release. Therefore, it was of interest to further study the antibiotic-induced release of toxins after exposure to antibiotics used for the treatment of the most severe infections, especially if protein synthesis inhibitors could reduce the release induced by PBP 3-specific β-lactam antibiotics. There were significant reductions in endotoxin release from gram-negative bacteria when the combination of the PBP 3-specific β-lactam antibiotic, cefuroxime, and the protein synthesis inhibitor, tobramycin, was compared with cefuroxime alone. Increasing doses of tobramycin reduced endotoxin release and increased the killing rate. In a kinetic in vitro model the endotoxin release from E.coli was higher after the second dose of cefuroxime. Nevertheless, it was reduced after addition of tobramycin. No binding of tobramycin to endotoxin was observed, either in vivo or in vitro. In a porcine sepsis model, a possible anti-inflammatory effect of ceftazidime and tobramycin, expressed as late cytokine inhibition, was seen. The protein synthesis inhibitor, clindamycin, released less streptococcal pyrogenic exotoxin A (SpeA) from a group A streptococcus strain than penicillin, and addition of clindamycin to penicillin resulted in less toxin production than penicillin alone. The SpeA production was dependent on the bacterial number at the start of treatment. Higher doses of penicillin also led to less SpeA. The choice of antibiotic class and dose may be important in the severely ill septic patient in whom an additional toxin release could be deleterious. A combination of a β-lactam antibiotic and a protein synthesis inhibitor seems beneficial but further investigations are needed. Communicable diseases Endotoxin LPS exotoxin SpeA penicillin-binding protein aminoglycosides clindamycin β-lactam antibiotics severe sepsis septic shock Infektionssjukdomar Infectious diseases Infektionssjukdomar
8	Time-related Aspects of Otoprotection : Experimental Studies in Rat Lidian, Adnan January 2013 (has links) Intratympanic injection of various otoprotectants through the round window membrane (RWM) might become available in the near future as an alternative to the currently available medical and surgical methods used to treat several inner ear diseases. The most common outcome of such diseases is sensorineural hearing loss (SNHL). Two examples of these otoprotectants are Edaravone and Brain-Derived Neurotrophic Factor (BDNF), both of which have already proved effective against noise-induced hair cell loss, barotrauma and ototoxicity caused by cisplatin. In four different studies we used two electrophysiological methods, auditory brainstem response (ABR) and distortion product otoacoustic emission (DPOAE), to study the effects of tobramycin and Pseudomonas aeruginosa exotoxin A (PaExoA) on the inner ears of 129 male Sprague-Dawley rats. In two investigations, not only the otoprotective effects of Edaravone on tobramycin-induced ABR threshold shifts and PaExoA-induced DPOAE threshold changes, were studied but even different application times, in order to establish in which interval it was still possible to achieve effective otoprotection.We found that Edaravone gave otoprotection from tobramycin when injected simultaneously or within 7 days, but it had only a limited effect on the changes in DPOAE thresholds caused by PaExoA when injected 1, 2, or 4 hours after the exotoxin. The effect of BDNF on PaExoA-induced ABR threshold shifts was investigated in two studies, where different doses of intratympanically injected PaExoA were used and where BDNF was applied simultaneously, 12 or 72 hours efter exotoxin instillation. We found that BDNF had an otoprotective effect on SNHL induced by different doses PaExoA when injected simultaneously or with no more than 12 hours delay. sensorineural hearing loss Edaravone brain-derived neurotrophic factor auditory brainstem response Sprague-Dawley rat distortion product otoacoustic emission Pseudomonas aeruginosa exotoxin A.
9	The Anti-toxin Properties of Grape Seed Phenolic Compounds Cherubin, Patrick 01 January 2014 (has links) Corynebacterium diphtheriae, Pseudomonas aeruginosa, Ricinus communis, Shigella dysentariae, and Vibrio cholerae produce AB toxins which share the same basic structural characteristics: a catalytic A subunit attached to a cell-binding B subunit. All AB toxins have cytosolic targets despite an initial extracellular location. AB toxins use different methods to reach the cytosol and have different effects on the target cell. Broad-spectrum inhibitors against these toxins are therefore hard to develop because they use different surface receptors, entry mechanisms, enzyme activities, and cytosolic targets. We have found that grape seed extract provides resistance to five different AB toxins: diphtheria toxin (DT), P. aeruginosa exotoxin A (ETA), ricin, Shiga toxin, and cholera toxin (CT). To identify individual compounds in grape seed extract that are capable of inhibiting the activities of these AB toxins, we screened twenty common phenolic compounds of grape seed extract for anti-toxin properties. Three compounds inhibited DT, four inhibited ETA, one inhibited ricin, and twelve inhibited CT. Additional studies were performed to determine the mechanism of inhibition against CT. Two compounds inhibited CT binding to the cell surface and even stripped bound CT off the plasma membrane of a target cell. Two other compounds inhibited the enzymatic activity of CT. We have thus identified individual toxin inhibitors from grape seed extract and some of their mechanisms of inhibition against CT. This work will help to formulate a defined mixture of phenolic compounds that could potentially be used as a therapeutic against a broad range of AB toxins. Diphtheria toxin (dt) p. aeruginosa exotoxin a (eta) ricin shiga toxin cholera toxin (ct) grape seed extract phenolic compounds polyphenolic compounds corynebacterium diphtheriae pseudomonas aeruginosa ricinus communis shigella dysentariae vibrio cholerae Biotechnology Molecular Biology

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