Linda D. Beutel

Intracavitary placement of autologous lymphokine-activated killer (LAK) cells after resection of recurrent glioblastoma

This study was performed to obtain safety and survival data for patients with histologically confirmed recurrent glioblastoma multiforme (GBM) who received intralesional lymphokine-activated killer (LAK) cells following surgery. LAK cells were generated by incubating peripheral blood mononuclear cells with interleukin-2 for 3 to 5 days in vitro. Forty patients with pathologic confirmation of GBM at surgery had placement of autologous LAK cells into the tumor cavity. The 23 men and 17 women had a median age of 48 years (range 21–76). The median interval from the original diagnosis of glioma to LAK treatment was 10.9 months. Patients received an average of 2.0 ± 1.0 × 109 LAK cells, with viability of 91 ± 6.8%. Treatment was well tolerated; there was one death within 60 days. At a median follow-up of 2.3 years, median survival post-LAK was 9.0 months; 1-year survival was 34%. Gender, age, location of tumor, LAK cell lytic activity, number of cells implanted, and inclusion of interleukin-2 at cell instillation were not correlated with outcome. Median survival from the date of original diagnosis for 31 patients who had GBM at initial diagnosis was 17.5 months versus 13.6 months for a control group of 41 contemporary GBM patients (p2 = 0.012). This treatment is safe and feasible. The median survival rates are higher than reported in most published series of patients who underwent reoperation for recurrent GBM. A randomized trial would be needed to establish therapeutic benefit.

Establishing in vitro cultures of autologous tumor cells for use in active specific immunotherapy.

Summary For active specific immunotherapy, autologous tumor cells grown in vitro may be a more appropriate source of tumor antigen than allogeneic tumor cell lines, autologous tumor cell suspensions, or purified/synthetic tumor antigen. A major limitation to this approach, however, has been the ability to reliably grow tumor cells from a high percentage of fresh tumor samples. We have harvested fresh tumors and attempted to establish short-term cultures of tumor cells to obtain 108 cells which could subsequently be used in autologous tumor cell vaccine programs. Fresh tumors were mechanically processed to initiate primary cultures in RPMI-1640 containing 1 m Mglutamine, 10 mM N-(2-hydroxyethyl)piperazine-N‘-(2-ethanesulfonic acid), 15% fetal bovine serum, and antibiotics, incubated at 37°C in 5% CO2. We were successful in growing 87 of 142 [61%, (95% confidence limits [55–68%]) of all tumors] including 39 of 58 (67%) melanomas, 10 of 10 (100%) renal cell carcinomas, 14 of 14 (100%) sarcomas, and 23 of 54 (43%) various adenocarcinomas. Success rates were not significantly higher in tumors obtained locally that were processed within 4 h of surgery, 51 of 78 (65%) versus 36 of 64 (56%) of those from farther away with longer delays in processing (p = 0.276). Of the 87 tumor cell lines established, 51 have been expanded for use in autologous tumor cell vaccine programs, and 40 have been used in the treatment of patients. We conclude that autologous tumors can be grown in vitro with sufficient reliability to make an autologous tumor cell line vaccine trial feasible.

Irradiated Cells from Autologous Tumor Cell Lines as Patient-Specific Vaccine Therapy in 125 Patients with Metastatic Cancer: Induction of Delayed-Type Hypersensitivity to Autologous Tumor is Associated with Improved Survival

OBJECTIVE We established short-term cultures of pure tumor cells for use as autologous tumor cell vaccines in an effort to study the effects of patients-specific immunotherapy. PATIENTS AND METHODS Surgically resected fresh tumor was obtained from patients with metastatic cancer. Successful tumor cell lines (5 x 10(7)) were expanded to 10(8) cells, irradiated, and cryopreserved for clinical use. Following a baseline test of delayed-type hypersensitivity (DTH) to an i.d. injection of 10(6) irradiated autologous tumor cells, patients received 3 weekly s.c. injections of 10(7) cells, had a repeat DTH test at week-4, then received monthly vaccinations for 5 months. A positive DTH test was defined as > or = 10 mm induration; survival was determined from the first DTH test. RESULTS Short-term cell lines were successfully established for 299/695 patients (43%). Vaccines were prepared for 231 patients, 142 of whom were treated, and 125 had a baseline DTH test recorded. Median follow up at the time of analysis was greater than 5 years. There was no difference in survival for any of the following: gender, age > 50 years, melanoma histology, anergy to common recall antigens or baseline DTH test result. Only 17 patients had a positive DTH at baseline (14%), but DTH converted from negative to positive in 31/80 (39%) of those who were tested, and in 31/108 (29%) of all patients (intent-to-convert analysis). For the 48 patients who were DTH-positive at entry, or converted to DTH-positive, the median survival was 30.5 months and 5-year survival 41% compared to 11.4 months and 9% 5-year survival for 77 patients whose DTH was never positive (P2 = 0.003). However, survival was even better for patients whose DTH test converted to positive compared to patients who were DTH-positive at baseline (median 37.5 vs 11.9 mos, P2 = 0.066). CONCLUSION This patient-specific, cell culture-derived, autologous tumor cell vaccine induced anti-tumor immune reactivity that was associated with improved survival in patients with advanced cancer.

Characterization of human tumor-infiltrating lymphocytes expanded in hollow-fiber bioreactors for immunotherapy of cancer

We attempted to grow tumor-infiltrating lymphocytes (TIL) from 34 fresh tumors of eight different histologies using flasks for the initiation phase and hollow fiber bioreactors to expand TIL to therapeutic numbers. Overall success rate was 76% (26/34) including melanoma (9/14, 64%) and renal cell carcinoma (11/11, 100%). The mean number of days required to reach successful initiation (1 x 10(9) TIL) for all tumor types was 29 +/- 16 days (mean +/- S.D.). Therapeutic doses of TIL required an average of 88 +/- 23 days (initiation plus expansion) with an average TIL number of 3.2 x 10(10) +/- 2.8 x 10(10). TIL phenotype was predominantly CD4+ in 53% (16/30) and CD8+ in 47% (14/30), renal cell carcinoma samples accounted for 12/14 of the predominantly CD8+ TIL. Cells bearing the natural killer (NK) phenotype represented only 0-7% of TIL while LAK phenotype represented 0-68% (mean 11 +/- 15%); LAK was the predominant phenotype in one patient with kidney cancer. Cytotoxicity tests showed consistent NK and LAK activity in addition to cytolysis of autologous tumor. Autologous tumor cell restricted cytolysis was noted for three TIL cultures. The overall success rate and characteristics of TIL were similar to our results with TIL expanded in semi-permeable plastic bags. This work confirms that hollow-fiber bioreactors are a suitable alternative to semi-permeable bags and roller bottle systems for the expansion of human TIL for therapeutic use in cancer patients.

Characterization of Tumor-Infiltrating Lymphocytes Derived from Human Tumors for Use as Adoptive Immunotherapy of Cancer

Summary From 1991 to 1995, we initiated cultures of 94 fresh tumor samples of various histologies in an effort to grow tumor-infiltrating lymphocytes (TIL) using flasks and subsequent expansion in semipermeable bags. The five most prevalent tumor types from which TIL were successfully initiated were melanoma (25 successful initiates in 34 tumor samples, 74% success rate), colorectal cancer (12 of 18, 67%), renal cell carcinoma (9 of 12, 75%), breast (4 of 5, 80%), and sarcoma (5 of 7, 71%). The overall success rate for all tumors was 67 of 94 (71%). There were no instances of contamination from the time of culture initiation through harvesting of the final cell product for clinical use. The mean number of days to reach successful initiation (> 5 X 108 cells) was 35 ± 24 days (mean ± SD). TIL were then expanded from these successful initiates for either a repeated low-dose therapy (TIL reinfusion numbers of 5 X 108–5 X 109) or for a repeated high-dose therapy (> 5 X 109–5 X 1010). The mean number of days to expand a TIL culture from the time of initiation to treatment for a first low-dose TIL was 59 days (range, 27–94 days) compared with 80 days (range, 33–209 days) for high-dose TIL. For patients who received a second or third high-dose TIL treatment, the average number of days needed to expand TIL was 39 days (n = 10) if there was no intervening cryopreservation of TIL, compared with 49 days (n = 10) if the culture had to be reestablished from cryopreserved TIL. For patients who received a second or third low-dose TIL, the mean number of days needed to expand TIL was 23 days (n = 3) if there was no intervening cryopreservation compared with 42 days (n = 17) if cultures had to be reestablished after cryopreservation of TIL. Low-dose TIL displayed predominantly CD4+ phenotype in 76% of 42 cultures, whereas high-dose TIL displayed predominantly CD8+ phenotype in 84% of 44 cultures. Cells bearing the natural killer (NK) phenotype (CD3-, CD56+) and the lymphokine activated killer (LAK) phenotype (CD3+, CD56-) were present in both low- and high-dose TIL cultures, but these phenotypes were never predominant. Cytotoxicity testing consistently demonstrated the persistence of NK and LAK activity in addition to the killing of allogeneic and autologous melanoma tumor targets. This work confirms that TIL cultures from most tumor types can be successfully established and expanded for therapeutic use, and repeated expansion from continuous TIL culture or cryopreserved TIL for repeated treatments is feasible. Such cultures are predominantly T lymphocytes that are phenotypically heterogeneous, and these phenotypes do not remain constant during prolonged time in culture.

High-dose Chemotherapy and Autologous Stem Cell Rescue for Metastatic Breast Cancer: Superior Survival for Tandem Compared With Single Transplants

During 1990–1999, we treated 60 patients with breast cancer who had distant metastases with high-dose chemotherapy and autologous stem cell rescue (HDC) after they had responded to induction chemotherapy. HDC regimens were MiTepa (60 mg/m2 mitoxantrone by continuous intravenous infusion over 3 days plus 300 mg/m2 thiotepa intravenously over 2 hours daily × 3 days) and ICE (12 g/m2 ifosfamide, 1800 mg/m2 carboplatin, 2 g/m2 etoposide; all 3 by continuous intravenous over 4 days). At a median follow up >8 years, the median failure-free survival (FFS) was 13.9 months, median overall survival (OS) 29.1 months, 5-year FFS 12%s and 5-year OS 25%. Thirty-three patients underwent tandem (T) transplants; 27 underwent a single (S) HDC. Median ages for these 2 groups were 45 and 48 years; bone and liver metastases were more prevalent in the T cohort, whereas lung metastases were more prevalent in the S cohort. At a median follow up of 6.5 years for the S group and >9 years for the T group, there were 52 deaths. FFS was better for T: median 15.7 versus 7.7 months (p2 = 0.010) as was OS: median 32.7 versus 17.7 months, 2-year survival 68% versus 41%, and 5-year survival 32% versus 15% (p2 = 0.010). As a group, patients with distant metastatic breast cancer who underwent tandem transplants had a better posttransplant survival than patients who underwent a single HDC.

Treatment of Human Solid Malignancies with Autologous Activated Lymphocytes and Cimetidine: A Phase II Trial of the Cancer Biotherapy Research Group

OBJECTIVE The Cancer Biotherapy Research Group conducted a clinical trial to verify encouraging reports of antitumor activity of autolymphocyte therapy. PATIENTS AND METHODS Patients with a variety of advanced solid malignancies underwent an initial leukapheresis procedure to collect about 5 x 10(9) autologous lymphocytes that were stimulated in vitro for 3 days with anti-CD3 monoclonal antibody in the presence of indomethicin and cis-retinoic acid to obtain media that was frozen in aliquots. This media contained significant amounts of tumor necrosis factor (TNF)-alpha, interleukin (IL)-1beta, interferon-gamma, and IL6, but no IL-2. Subsequently patients underwent up to 6 monthly leukaphereses to collect 2-5 x 10(9) autologous lymphocytes that were incubated in vitro for 6 days in the cryopreserved media containing autologous lymphokines, resulting in a cell population enriched for noncytotoxic T-helper lymphocytes. These were administered intravenously monthly for up to 6 months with daily oral cimetidine at a dose of 600 mg po qid, which was given throughout the treatment period. Tumor response was assessed every 2 months. RESULTS There were 47 patients (25 women and 22 men) with a median age of 55 years (range 31-79). One hundred seventy four treatments were delivered and were well tolerated. A mean of 2.05 +/- 1.46 (range 0.82-12.8 x 10(9)) cells were infused. Eighty-five percent received two or more doses; 19% received six doses. Objective tumor responses were observed in 1/15 renal cell, 1/13 colorectal, 0/6 breast, 0/5 lung, 0/2 gastric, 0/2 sarcoma, 0/1 pancreas, 0/1 prostate, 0/1 melanoma, and 0/1 eccrine. Forty-three patients have died. Median survival was 8.8 months, 1-year survival 35%, and 2-year survival 15%. CONCLUSION This complex treatment program was feasible. Infusion of these cells was well tolerated. Some antitumor activity was seen in patients with renal cell cancer and colorectal cancer.

Short-Term Tumor Cell Lines from Breast Cancer for Use as Autologous Tumor Cell Vaccines in the Treatment of Breast Cancer

OBJECTIVE We tried to establish short-term cultures of autologous tumors from patients with breast carcinoma for potential use as active specific immunotherapy (i.e., autologous vaccine) after resection of primary breast cancer, and/or for the treatment of metastases. METHODS Between 10/90 and 12/99 the cell biology laboratory of the Hoag Cancer Center attempted to establish short-term tumor cell lines from 115 breast cancer specimens from 56 primary breast lesions, 17 axillary nodes, 14 other lymph node/soft tissue sites, 10 chest wall recurrences, and 6 thoracentesis of malignant pleural effusions. Success was defined by growth of 5 x 10(7) viable cells whose malignant nature and breast cancer origin was confirmed by histology of the submitted tissue, cell morphology and antigenic phenotyping. Variables associated with successful growth of short-term cell lines were examined. RESULTS Expansion to 5 x 10(7) cells was achieved for only 8/115 samples [7%] including two from chest wall recurrences, and one each from a supraclavicular node, an umbilical node, liver, omentum, and pleural fluid. Two of the successful cell lines were established from tissue that originally had been cryopreserved; the others were initiated from fresh tumor. The success rate was better from regional/distant metastases 7/55 (13%) compared to primary tumors 1/56 (1.8%) (p = 0.063). The success rate for tumors harvested at Hoag Hospital was 4/97 (4%) compared to 4/14 from (31%) distant sites, but all but one of the tumors from a distant geographic site was a metastatic lesion. Tumor cell lines were successfully established from metastatic lesions ranging in size from < 1.0 g to 19 g. Four patients were treated with their autologous vaccine in the setting of chemotherapy-refractory metastatic disease without any significant toxicity. CONCLUSIONS We were unable to establish short-term cell lines for most patients with primary or metastatic breast cancer using this methodology. However, two long-term cell lines have been established and characterized. Treatment with the autologous irradiated cell product was not associated with acute toxicity.

Tissue Banking in Community Cancer Centers

Oncology Issues November/December 2008 A s the technologies for phenotypic and genotypic analyses become simplified and standardized, community cancer centers have increased interest in preserving tumor tissue for testing. Submission of tumor tissue is increasingly a component of clinical trials in order to correlate phenotypic and genomic features with therapeutic response and survival in a defined clinical setting. Although formalin-fixed, paraffin-embedded tissues are sufficient for many types of analysis, snap-frozen tumor tissue and even cryopreserved tumor cell suspensions may be needed for certain tests. The good news: technology related to long-term tissue storage is evolving rapidly. The bad news: early diagnosis of microscopic cancer (prostate, breast, melanoma) and pathology assessment can make long-term tissue storage unfeasible in certain clinical situations. To date, commercial efforts to establish tissue banks for individual patients have enjoyed limited success, in part because of lack of reimbursement for tumor preservation services. Hoag Cancer Center has maintained a cell biology laboratory with tissue banking capabilities for 20 years. Maintaining a tissue bank in a community hospital requires an ongoing financial commitment to support personnel, facilities, equipment, operating procedures, and data systems. Close working relationships with operating room personnel and pathologists are crucial. In addition, long-term tissue banking involves long-term contractual and legal responsibilities. Prior to establishing a tissue bank, community cancer centers should first evaluate whether operating a tissue bank is consistent with the center’s local patient care mission. Second, cancer center and hospital management must look at the tissue bank with a cost-to-benefit perspective.