Spelling suggestions: "subject:"anti tumortherapie"" "subject:"anti tumortherapien""
1 |
Der Einfluss muriner mesenchymaler Stammzellen auf murine zytokin induzierte Killerzellen in der KokulturBach, Martin 30 July 2014 (has links) (PDF)
Stimulating lymphocytes with Ifn-γ, anti-CD3, and interleukin-2 promotes the proliferation of a cell population coexpressing T-lymphocyte surface antigens such as CD3, CD8a, and CD25 as well as natural killer cell markers such as NK1.1, CD49, and CD69. These cells, referred to as cytokine-induced killer cells (CIKs), display cytotoxic activity against tumour cells, even without prior antigen presentation, and offer a new cell-based approach to the treatment of malignant diseases. Because CIKs are limited in vivo, strategies to optimize in vitro culture yield are required.
In the last 10 years, mesenchymal stem cells (MSCs) have gathered considerable attention. Aside from their uses in tissue engineering and as support in haematopoietic stem cell transplantations, MSCs show notable immunomodulatory characteristics, providing further possibilities for therapeutic applications. In this study, we investigated the influence of murine MSCs on proliferation, phenotype, vitality, and cytotoxicity of murine CIKs in a coculture system. We found that CIKs in coculture proliferated within 7 days, with an average growth factor of 18.84, whereas controls grew with an average factor of 3.7 in the same period. Furthermore, higher vitality was noted in cocultured CIKs than in controls. Cell phenotype was unaffected by coculture with MSCs and, notably, coculture did not impact cytotoxicity against the tumour cells analysed. The findings suggest that cell–cell contact is primarily responsible for these effects. Humoral interactions play only a minor role. Furthermore, no phenotypical MSCs were detected after coculture for 4 h, suggesting the occurrence of immune reactions between CIKs and MSCs. Further investigations with DiD-labelled MSCs revealed that the observed disappearance of MSCs appears not to be due to differentiation processes.
|
2 |
Der Einfluss muriner mesenchymaler Stammzellen auf murine zytokin induzierte Killerzellen in der KokulturBach, Martin 19 June 2014 (has links)
Stimulating lymphocytes with Ifn-γ, anti-CD3, and interleukin-2 promotes the proliferation of a cell population coexpressing T-lymphocyte surface antigens such as CD3, CD8a, and CD25 as well as natural killer cell markers such as NK1.1, CD49, and CD69. These cells, referred to as cytokine-induced killer cells (CIKs), display cytotoxic activity against tumour cells, even without prior antigen presentation, and offer a new cell-based approach to the treatment of malignant diseases. Because CIKs are limited in vivo, strategies to optimize in vitro culture yield are required.
In the last 10 years, mesenchymal stem cells (MSCs) have gathered considerable attention. Aside from their uses in tissue engineering and as support in haematopoietic stem cell transplantations, MSCs show notable immunomodulatory characteristics, providing further possibilities for therapeutic applications. In this study, we investigated the influence of murine MSCs on proliferation, phenotype, vitality, and cytotoxicity of murine CIKs in a coculture system. We found that CIKs in coculture proliferated within 7 days, with an average growth factor of 18.84, whereas controls grew with an average factor of 3.7 in the same period. Furthermore, higher vitality was noted in cocultured CIKs than in controls. Cell phenotype was unaffected by coculture with MSCs and, notably, coculture did not impact cytotoxicity against the tumour cells analysed. The findings suggest that cell–cell contact is primarily responsible for these effects. Humoral interactions play only a minor role. Furthermore, no phenotypical MSCs were detected after coculture for 4 h, suggesting the occurrence of immune reactions between CIKs and MSCs. Further investigations with DiD-labelled MSCs revealed that the observed disappearance of MSCs appears not to be due to differentiation processes.:Inhaltsverzeichnis I
Abbildungsverzeichnis III
Tabellenverzeichnis IV
Bibliographische Beschreibung V
Abkürzungsverzeichnis VII
1 Einleitung 1
1.1 CIK-Zellen (CIK) 3
1.1.1 Merkmale von CIK-Zellen 3
1.1.2 Wirkungsmechanismen von CIK-Zellen 3
1.1.3 Studienlage 4
1.1.4 Bisherige Ansätze zur Verbesserung der Kultivierungsbedingungen 6
1.2 Mesenchymale Stammzellen (MSC) 7
1.2.1 Allgemein 7
1.2.2 Differenzierung von MSC 7
1.2.3 Heterogenität und Einflussfaktoren der MSC - Identitätsproblematik 8
1.2.4 Charakterisierung von MSC 9
1.2.5 Therapeutische Einsatzmöglichkeiten von MSC 11
2 Zielformulierung 15
3 Material und Methoden 16
3.1 Tiere 16
3.2 Materialien 17
3.2.1 Materialien für Zellkultur 17
3.2.2 Materialien für FACS-Analyse 18
3.2.3 Materialien für Zytotoxizitätsassay 19
3.2.4 Materialien für CFU-F-Assay 20
3.3 Methoden 21
3.3.1 Statistische Auswertung 21
3.3.2 Zellkultur 22
3.3.3 FACS (Fluorescence Activated Cell Sorting) 26
3.3.4 Markierung der MSC mit DiD 28
3.3.5 Zytotoxizitätsassay (LDH-Freisetzungsassay) 29
3.3.6 CFU-F-Assay 32
4 Ergebnisse 34
4.1 Beeinflussung der Wachstumskurve 34
4.1.1 Der Wachstumskurvenverlauf von CIK-Zellen (Kontrollen) 34
4.1.2 Der Wachstumskurvenverlauf von CIK-Zellen in der Kokultur mit MSC 35
4.1.3 Der Wachstumskurvenverlauf in MSC-konditioniertem Medium 37
4.1.4 Der Wachstumskurvenverlauf bei Restimulierung an Tag 14 38
4.2 Beeinflussung des Oberflächenphänotyps 40
4.2.1 Der Oberflächenphänotyp von CIK-Zellen 40
4.2.2 Vergleich Oberflächenphänotyp Kontrollen mit kokultivierten CIK 43
4.3 Beeinflussung der Vitalität 46
4.4 Beeinflussung der Zytotoxizität 48
4.5 Identifizierung der MSC 49
4.5.1 Adhärenz an Plastikoberflächen 50
4.5.2 Fibroblastenähnliche Wachstumsmorphologie 50
4.5.3 Wachstum in Colony-Forming-Units 51
4.5.4 Der Oberflächenphänotyp von MSC 53
4.6 Schicksal der MSC in der Kokultur 54
4.6.1 Der Oberflächenphänotyp der adhärenten Zellen nach Kokultur 54
4.6.2 Kokultur mit DiD gelabelten MSC 57
5 Diskussion 59
5.1 Beeinflussung der Wachstumskurve 60
5.1.1 Mechanismen der Beeinflussung des Wachstumskurvenverlaufs 60
5.1.2 Fehlerbetrachtung 68
5.2 Identifizierung der CIK sowie Beeinflussung von Phänotyp und Vitalität 69
5.3 Beeinflussung der Zytotoxizität 70
5.3.1 Vergleich Zytotoxizität Kontrollen mit Kokulturen 70
5.3.2 Fehlerbetrachtung 71
5.4 Identifizierung der MSC 72
6 Schlussfolgerung 75
7 Ausblick 77
8 Zusammenfassung 79
Literaturverzeichnis 83
Danksagung I
|
Page generated in 0.2331 seconds