PURPOSE/ OBJECTIVE: The nucleoside analogue gemcitabine inhibits cellular repair and repopulation, induces apoptosis, causes tumor growth delay, and enhances radiation-induced growth delay. After single doses of drug and radiation, maximum enhancement of tumor response was obtained when gemcitabine preceded radiation by at least 24 h. Conversely, the cellular radioresponse of the normal gastrointestinal epithelium was slightly protected when gemcitabine and radiation were separated by 24 h. This differential response created a time frame within which therapeutic gain could be maximized. In our present investigation, we sought to define the most therapeutically beneficial scheme of gemcitabine administration when combined with fractionated radiotherapy. METHODS AND MATERIALS: C3Hf/Kam mice were given identical drug and radiation schedules of administration, and both normal tissue (jejunal mucosa) and tumor (Sa-NH) responses were measured. Irradiation was given once per day for 5 days in normal tissue and tumor growth delay studies and twice per day for the tumor cure endpoint. A total dose of 25 mg/kg gemcitabine was given i.p. in 1 of 3 schedules: a single dose of 25 mg/kg 24 h before the start of fractionated irradiation, 12.5 mg/kg 24 h before the first and third radiation doses, or 24 h before each of 5 radiation doses. Groups of mice bearing 7- or 8-mm diameter tumors were treated with gemcitabine alone or in combination with fractionated irradiation under ambient or hypoxic conditions. The survival response of the jejunal mucosa was quantified by the microcolony assay and histologically by quantifying apoptosis, mitosis, S-phase fraction, and crypt cellularity. RESULTS: For tumor growth delay, dose-modifying factors (DMFs) were similar (1.34-1.46) for all 3 schedules of drug administration. In contrast, the response of the jejunum was strongly dependent on the schedule of gemcitabine administration. A single dose of gemcitabine before the start of fractionated radiotherapy resulted in slight radioprotection (DMF 0.96). Two doses and 5 daily doses of gemcitabine enhanced radiation response by factors of 1.09 and 1.23, respectively. Major factors affecting the response of the jejunal mucosa were apoptotic death of S-phase cells exposed to gemcitabine and cell cycle synchrony of surviving cells. Tumor reoxygenation was found to be a major mechanism for tumor radioenhancement, in addition to those reported earlier. CONCLUSION: All 3 schedules of drug administration produced therapeutic gain; however, when gemcitabine was given more than once in a 5-fraction radiation treatment schedule, normal tissue toxicity increased. The highest therapeutic gain (1.4) was achieved by giving a single dose of gemcitabine (25 mg/kg) 24 h before the start of fractionated radiotherapy.
PURPOSE/ OBJECTIVE: The nucleoside analogue gemcitabine inhibits cellular repair and repopulation, induces apoptosis, causes tumor growth delay, and enhances radiation-induced growth delay. After single doses of drug and radiation, maximum enhancement of tumor response was obtained when gemcitabine preceded radiation by at least 24 h. Conversely, the cellular radioresponse of the normal gastrointestinal epithelium was slightly protected when gemcitabine and radiation were separated by 24 h. This differential response created a time frame within which therapeutic gain could be maximized. In our present investigation, we sought to define the most therapeutically beneficial scheme of gemcitabine administration when combined with fractionated radiotherapy. METHODS AND MATERIALS: C3Hf/Kam mice were given identical drug and radiation schedules of administration, and both normal tissue (jejunal mucosa) and tumor (Sa-NH) responses were measured. Irradiation was given once per day for 5 days in normal tissue and tumor growth delay studies and twice per day for the tumor cure endpoint. A total dose of 25 mg/kg gemcitabine was given i.p. in 1 of 3 schedules: a single dose of 25 mg/kg 24 h before the start of fractionated irradiation, 12.5 mg/kg 24 h before the first and third radiation doses, or 24 h before each of 5 radiation doses. Groups of mice bearing 7- or 8-mm diameter tumors were treated with gemcitabine alone or in combination with fractionated irradiation under ambient or hypoxic conditions. The survival response of the jejunal mucosa was quantified by the microcolony assay and histologically by quantifying apoptosis, mitosis, S-phase fraction, and crypt cellularity. RESULTS: For tumor growth delay, dose-modifying factors (DMFs) were similar (1.34-1.46) for all 3 schedules of drug administration. In contrast, the response of the jejunum was strongly dependent on the schedule of gemcitabine administration. A single dose of gemcitabine before the start of fractionated radiotherapy resulted in slight radioprotection (DMF 0.96). Two doses and 5 daily doses of gemcitabine enhanced radiation response by factors of 1.09 and 1.23, respectively. Major factors affecting the response of the jejunal mucosa were apoptotic death of S-phase cells exposed to gemcitabine and cell cycle synchrony of surviving cells. Tumor reoxygenation was found to be a major mechanism for tumor radioenhancement, in addition to those reported earlier. CONCLUSION: All 3 schedules of drug administration produced therapeutic gain; however, when gemcitabine was given more than once in a 5-fraction radiation treatment schedule, normal tissue toxicity increased. The highest therapeutic gain (1.4) was achieved by giving a single dose of gemcitabine (25 mg/kg) 24 h before the start of fractionated radiotherapy.
Authors: Jean-Luc Van Laethem; Pascal Hammel; Françoise Mornex; David Azria; Geertjan Van Tienhoven; Philippe Vergauwe; Marc Peeters; Marc Polus; Michel Praet; Murielle Mauer; Laurence Collette; Volker Budach; Manfred Lutz; Eric Van Cutsem; Karin Haustermans Journal: J Clin Oncol Date: 2010-09-13 Impact factor: 44.544
Authors: C H Crane; N A Janjan; D B Evans; R A Wolff; M T Ballo; L Milas; K Mason; C Charnsangavej; P W Pisters; J E Lee; R Lenzi; J N Vauthey; A Wong; T Phan; Q Nguyen; J L Abbruzzese Journal: Int J Pancreatol Date: 2001
Authors: C H Crane; J A Antolak; I I Rosen; K M Forster; D B Evans; N A Janjan; C Charnsangavej; P W Pisters; R Lenzi; M A Papagikos; R A Wolff Journal: Int J Gastrointest Cancer Date: 2001
Authors: A William Blackstock; Joel E Tepper; Donna Niedwiecki; Donna R Hollis; Robert J Mayer; Margaret A Tempero Journal: Int J Gastrointest Cancer Date: 2003
Authors: Brock J Sishc; Lianghao Ding; Taek-Keun Nam; Collin D Heer; Samuel N Rodman; Joshua D Schoenfeld; Melissa A Fath; Debabrata Saha; Casey F Pulliam; Britta Langen; Robert A Beardsley; Dennis P Riley; Jeffery L Keene; Douglas R Spitz; Michael D Story Journal: Sci Transl Med Date: 2021-05-12 Impact factor: 17.956
Authors: Tom Budiharto; Karin Haustermans; Eric Van Cutsem; Werner Van Steenbergen; Baki Topal; Raymond Aerts; Nadine Ectors; Didier Bielen; Dirk Vanbeckevoort; Laurence Goethals; Chris Verslype Journal: Radiat Oncol Date: 2008-09-22 Impact factor: 3.481
Authors: Fares Al-Ejeh; Jocelyn M Darby; Chris Tsopelas; Douglas Smyth; Jim Manavis; Michael P Brown Journal: PLoS One Date: 2009-02-27 Impact factor: 3.240