METHODS: We applied an experimental approach employing two recombinant adenoviral vectors (Ad) that express interleukin-12 (IL-12) and angiostatin-like molecule (K1-3) respectively to a subcutaneous hepatoma model in mice. RESULTS: Injection of AdK1-3 into tumour nodules established by subcutaneous (s.c.) implantation of Hepa129 hepatoma cells in C3H mice resulted in a significant dose-dependent reduction in tumour growth by 57% in the high dosage group (5x10(9) plaque-forming units [pfu], n=8) 10 days after treatment initiation. Similar antitumoural effects were found for the intratumoural mono-therapy with IL-12 (2.5x10(9) pfu, n=8) resulting in 60% tumour inhibition at the same time point. The survival rate was significantly (p=0.009) improved in the IL-12 but not in the K1-3 treatment group. A combination therapy of AdK1-3 and AdIL-12 was also effective, but did not further improve antitumour efficacy compared with the monotherapy. CONCLUSION: In conclusion, both mono- and combination therapy of K1-3 and IL-12 significantly inhibited tumour progression in this experimental tumour model. The co-administration of both compounds did not result in additive antitumour effects. We hypothesise that the lack of additive antitumour effects of the combination treatment might be attributed to partially counteracting antitumour effects and further studies are needed to illustrate the interference of tumour angiogenesis and tumour inflammation in this tumour model.
METHODS: We applied an experimental approach employing two recombinant adenoviral vectors (Ad) that express interleukin-12 (IL-12) and angiostatin-like molecule (K1-3) respectively to a subcutaneous hepatoma model in mice. RESULTS: Injection of AdK1-3 into tumour nodules established by subcutaneous (s.c.) implantation of Hepa129 hepatoma cells in C3H mice resulted in a significant dose-dependent reduction in tumour growth by 57% in the high dosage group (5x10(9) plaque-forming units [pfu], n=8) 10 days after treatment initiation. Similar antitumoural effects were found for the intratumoural mono-therapy with IL-12 (2.5x10(9) pfu, n=8) resulting in 60% tumour inhibition at the same time point. The survival rate was significantly (p=0.009) improved in the IL-12 but not in the K1-3 treatment group. A combination therapy of AdK1-3 and AdIL-12 was also effective, but did not further improve antitumour efficacy compared with the monotherapy. CONCLUSION: In conclusion, both mono- and combination therapy of K1-3 and IL-12 significantly inhibited tumour progression in this experimental tumour model. The co-administration of both compounds did not result in additive antitumour effects. We hypothesise that the lack of additive antitumour effects of the combination treatment might be attributed to partially counteracting antitumour effects and further studies are needed to illustrate the interference of tumour angiogenesis and tumour inflammation in this tumour model.
Authors: I Narvaiza; G Mazzolini; M Barajas; M Duarte; M Zaratiegui; C Qian; I Melero; J Prieto Journal: J Immunol Date: 2000-03-15 Impact factor: 5.422
Authors: M Barajas; G Mazzolini; G Genové; R Bilbao; I Narvaiza; V Schmitz; B Sangro; I Melero; C Qian; J Prieto Journal: Hepatology Date: 2001-01 Impact factor: 17.425
Authors: Volker Schmitz; Esther Raskopf; Maria Angeles Gonzalez-Carmona; Annabelle Vogt; Christian Rabe; Ludger Leifeld; Miroslaw Kornek; Tilman Sauerbruch; Wolfgang H Caselmann Journal: Gut Date: 2006-06-29 Impact factor: 23.059