PURPOSE: Radiofrequency ablation (RFA) is a common treatment modality for surgically unresectable tumors. However, there is a high rate of both local and systemic recurrence. EXPERIMENTAL DESIGN: In this preclinical study, we sought to enhance the antitumor effect of RFA by combining it with huKS-IL2 immunocytokine [tumor-specific monoclonal antibody fused to interleukin-2 (IL2)] in mice bearing CT26-KS colon adenocarcinoma. Mice were treated with RFA, huKS-IL2 via intratumoral injection, or combination therapy. RESULTS: Treatment of mice bearing s.c. tumors with RFA and huKS-IL2 resulted in significantly greater tumor growth suppression and enhanced survival compared with mice treated with RFA or huKS-IL2 alone. When subtherapeutic regimens of RFA or huKS-IL2 were used, tumors progressed in all treated mice. In contrast, the combination of RFA and immunocytokine resulted in complete tumor resolution in 50% of mice. Treatment of a tumor with RFA and intratumoral huKS-IL2 also showed antitumor effects against a distant untreated tumor. Tumor-free mice after treatment with RFA and huKS-IL2 showed immunologic memory based on their ability to reject subsequent challenges of CT26-KS and the more aggressive parental CT26 tumors. Flow cytometry analysis of tumor-reactive T cells from mice with complete tumor resolution showed that treatment with RFA and huKS-IL2 resulted in a greater proportion of cytokine-producing CD4 T cells and CD8 T cells compared with mice treated with RFA or huKS-IL2 alone. CONCLUSIONS: These results show that the addition of huKS-IL2 to RFA significantly enhances the antitumor response in this murine model, resulting in complete tumor resolution and induction of immunologic memory.
PURPOSE: Radiofrequency ablation (RFA) is a common treatment modality for surgically unresectable tumors. However, there is a high rate of both local and systemic recurrence. EXPERIMENTAL DESIGN: In this preclinical study, we sought to enhance the antitumor effect of RFA by combining it with huKS-IL2 immunocytokine [tumor-specific monoclonal antibody fused to interleukin-2 (IL2)] in mice bearing CT26-KS colon adenocarcinoma. Mice were treated with RFA, huKS-IL2 via intratumoral injection, or combination therapy. RESULTS: Treatment of mice bearing s.c. tumors with RFA and huKS-IL2 resulted in significantly greater tumor growth suppression and enhanced survival compared with mice treated with RFA or huKS-IL2 alone. When subtherapeutic regimens of RFA or huKS-IL2 were used, tumors progressed in all treated mice. In contrast, the combination of RFA and immunocytokine resulted in complete tumor resolution in 50% of mice. Treatment of a tumor with RFA and intratumoral huKS-IL2 also showed antitumor effects against a distant untreated tumor. Tumor-free mice after treatment with RFA and huKS-IL2 showed immunologic memory based on their ability to reject subsequent challenges of CT26-KS and the more aggressive parental CT26tumors. Flow cytometry analysis of tumor-reactive T cells from mice with complete tumor resolution showed that treatment with RFA and huKS-IL2 resulted in a greater proportion of cytokine-producing CD4 T cells and CD8 T cells compared with mice treated with RFA or huKS-IL2 alone. CONCLUSIONS: These results show that the addition of huKS-IL2 to RFA significantly enhances the antitumor response in this murine model, resulting in complete tumor resolution and induction of immunologic memory.
Authors: M Imboden; K R Murphy; A L Rakhmilevich; Z C Neal; R Xiang; R A Reisfeld; S D Gillies; P M Sondel Journal: Cancer Res Date: 2001-02-15 Impact factor: 12.701
Authors: S Giacchetti; B Perpoint; R Zidani; N Le Bail; R Faggiuolo; C Focan; P Chollet; J F Llory; Y Letourneau; B Coudert; F Bertheaut-Cvitkovic; D Larregain-Fournier; A Le Rol; S Walter; R Adam; J L Misset; F Lévi Journal: J Clin Oncol Date: 2000-01 Impact factor: 44.544
Authors: H J Haisma; H M Pinedo; A Rijswijk; I der Meulen-Muileman; B A Sosnowski; W Ying; V W Beusechem; B W Tillman; W R Gerritsen; D T Curiel Journal: Gene Ther Date: 1999-08 Impact factor: 5.250
Authors: Erik E Johnson; Hillary D Lum; Alexander L Rakhmilevich; Brian E Schmidt; Meghan Furlong; Ilia N Buhtoiarov; Jacquelyn A Hank; Andrew Raubitschek; David Colcher; Ralph A Reisfeld; Stephen D Gillies; Paul M Sondel Journal: Cancer Immunol Immunother Date: 2008-04-26 Impact factor: 6.968
Authors: Zulmarie Perez Horta; Swetha Saseedhar; Alexander L Rakhmilevich; Lakeesha Carmichael; Jacquelyn A Hank; Margaret Boyden; Stephen D Gillies; Paul M Sondel Journal: Oncoimmunology Date: 2018-05-07 Impact factor: 8.110
Authors: Austin G Duffy; Susanna V Ulahannan; Oxana Makorova-Rusher; Osama Rahma; Heiner Wedemeyer; Drew Pratt; Jeremy L Davis; Marybeth S Hughes; Theo Heller; Mei ElGindi; Ashish Uppala; Firouzeh Korangy; David E Kleiner; William D Figg; David Venzon; Seth M Steinberg; Aradhana M Venkatesan; Venkatesh Krishnasamy; Nadine Abi-Jaoudeh; Elliot Levy; Brad J Wood; Tim F Greten Journal: J Hepatol Date: 2016-11-02 Impact factor: 25.083
Authors: Zachary S Morris; Emily I Guy; David M Francis; Monica M Gressett; Lauryn R Werner; Lakeesha L Carmichael; Richard K Yang; Eric A Armstrong; Shyhmin Huang; Fariba Navid; Stephen D Gillies; Alan Korman; Jacquelyn A Hank; Alexander L Rakhmilevich; Paul M Harari; Paul M Sondel Journal: Cancer Res Date: 2016-05-06 Impact factor: 12.701
Authors: Georgios P Skandalakis; Daniel R Rivera; Caroline D Rizea; Alexandros Bouras; Joe Gerald Jesu Raj; Dominique Bozec; Constantinos G Hadjipanayis Journal: Int J Hyperthermia Date: 2020-07 Impact factor: 3.914
Authors: Fumito Ito; Trupti D Vardam; Michelle M Appenheimer; Kevin H Eng; Sandra O Gollnick; Jason B Muhitch; Sharon S Evans Journal: Int J Hyperthermia Date: 2019-11 Impact factor: 3.914