Clinical observation of lymphopenia in patients with newly diagnosed glioblastoma

Patients with high-grade gliomas (HGG) routinely receive radiation, temozolomide, and glucocorticoids. As each of these is immunosuppressive, we conducted a prospective, multicenter study to follow CD4 counts over time and determine whether low CD4 counts were associated with adverse outcomes. Patients with newly diagnosed HGG had CD4 counts drawn before initiating standard therapy and monthly thereafter for 1 year. Information on hospitalizations, infections, glucocorticoid use, survival, and cause of death were also collected. Ninety-six evaluable patients were accrued [85% glioblastoma, median age of 57, median Karnofsky performance status (KPS) = 90]. The median CD4 count before radiation and temozolomide treatment was 664 cells/mm(3). The CD4 count nadir occurred 2 months after initiating therapy when 73% of patients had CD4 counts less than 300 cells/mm(3) and 40% had less than 200 cells/mm(3). CD4 counts remained low throughout the year of follow-up. Patients with CD4 counts less than 200 cells/mm(3)at 2 months had shorter survival than those with higher counts (median: 13.1 vs. 19.7 months, P = 0.002). Median survival was related to CD4 toxicity grades (I = 23.8 months, II = 19.7 months, III-IV = 13.1 months, P = 0.009). The adjusted HR for death attributable to 2-month CD4 count below 200 was 1.66 (P = 0.03). Eighty-eight percent of deaths resulted from disease progression, whereas only 2.5% were due to infection. Severe reductions in CD4 counts in patients with newly diagnosed HGG treated with radiation and temozolomide treatment are common, treatment-related, long-lasting, and associated with early death from tumor progression. ©2011 AACR.

Severe treatment-related lymphopenia (TRL) occurs in 40% of patients with high grade gliomas (HGG) receiving glucocorticoids, temozolomide, and radiation. This occurs following radiation, persists for months, and is associated with reduced survival. As all three treatment modalities are lymphotoxic, this study was conducted to estimate the radiation dose that lymphocytes receive passing through the radiation field and if this could explain the observed TRL. A typical glioblastoma plan (8-cm tumor, 60 Gy/30 fractions) was constructed using the Pinnacle™ radiation planning system. Radiation doses to circulating cells (DCC) were analyzed using MatLab™. The primary endpoints were mean DCC and percent of circulating cells receiving ≥0.5 Gy. The model was also used to study how changes in target volumes (PTV), dose rates, and delivery techniques affect DCC. The modeling determined that while a single radiation fraction delivered 0.5 Gy to 5% of circulating cells, after 30 fractions 99% of circulating blood had received ≥0.5 Gy. The mean DCC was 2.2 Gy and was similar for IMRT, 3D-conformal techniques, and different dose rates. Major changes in PTV size affected mean DCC and percent of circulating cells receiving ≥0.5 Gy. Standard treatment plans for brain tumors deliver potentially lymphotoxic radiation doses to the entire circulating blood pool. Altering dose rates or delivery techniques are unlikely to significantly affect DCC by the end of treatment. Novel approaches are needed to limit radiation to circulating lymphocytes given the association of lymphopenia with poorer survival in patients with HGG.