Treatment of Primary CNS Lymphoma
Treatment Options for Primary CNS Lymphoma
Treatment options for primary CNS lymphoma include the following:
- Induction therapy.
- Consolidation after induction therapy.
Induction therapy
Trials using chemotherapy alone were justified because of the unsatisfactory results of using whole-brain radiation therapy (WBRT) alone [1,2] and significant neurological toxicity using high-dose methotrexate or other chemotherapeutic agents that cross the blood-brain barrier in combination with WBRT.[3,4,5]
Severe, delayed, neurological toxic effects were rarely seen in chemotherapy-only trials in the absence of subsequent radiation therapy. However, salvage radiation can be given for relapsed or refractory disease, sometimes at reduced dosage.[6,7]
Numerous phase I and phase II studies over two decades established the following active drugs for induction therapy or for treatment of relapsing disease. The following drugs have been used as single agents and in combinations:
- High-dose methotrexate.[8,9,10,11,12,13] Outside of clinical trials, high-dose methotrexate is the most frequently used standard induction therapy.[14] However, it is given to inpatients, and it is too toxic for patients with a creatinine clearance under 35 cc/min or for most patients older than 75 years.
- Lenalidomide with rituximab.[15] When high-dose chemotherapy is not feasible, this is the most frequently used combination. Lenalidomide can be initiated at low doses (e.g., 5 mg daily, 21 out of 28 days) in the setting of renal insufficiency.
- High-dose cytarabine.[12,13,16]
- Rituximab.[16,17,18]
- Thiotepa.[18,19]
- Temozolamide.[20]
- Ibrutinib.[21,22]
- Procarbazine.[23]
- Vincristine.[23]
- Pomalidomide.[24]
- Nivolumab.[25]
Evidence (chemotherapy with or without other therapy):
- The International Extranodal Lymphoma Study Group evaluated three different induction combinations in 227 patients with newly diagnosed HIV-negative primary CNS lymphoma. Patients were randomly assigned to receive high-dose methotrexate (HD MTX) + high-dose cytarabine (HDA) (group 1), HD MTX + HDA + rituximab (R) (group 2), or HD MTX + HDA + R + thiotepa (the MATRix regimen) (group 3). With a median follow-up of 88 months, the overall survival (OS) rate was:[26][Level of evidence A1]
- 21% for group 1.
- 37% for group 2.
- 56% for group 3.
The groups were compared as follows:
- Group 1 versus group 2: hazard ratio (HR), 0.64; 95% confidence interval [CI], 0.41–0.99; P = .04.
- Group 1 versus group 3: HR, 0.42; 95% CI, 0.24–0.64; P = .00005.
- Group 2 versus group 3: HR, 0.66; 95% CI, 0.44–0.98; P = .04.
The OS rate favored the complete MATRix regimen in all comparisons.[26][Level of evidence A1]
- The 113 patients who attained a complete response (CR), partial response, or stable disease were randomly assigned to 36 Gy whole-brain radiation therapy versus autologous stem cell transplant (ASCT) after thiotepa + bic-chloroethylnitrosourea + carmustine (BCNU) conditioning. No significant differences were seen in 7-year PFS or OS in regard to consolidation in this phase II trial.[26][Level of evidence B1]
- The thiotepa + BCNU conditioning regimen was well tolerated by patients aged 60 to 70 years. It had improved tolerability compared with prior reports using the more intensive thiotepa + bulsulfan regimen.[26][Level of evidence D]
- Patients who received the two-drug combination had a complete remission rate of 23% (interquartile range [IQR], 14%‒31%; HR, 0.46; 95% CI, 0.28‒0.74). Patients who received the three-drug combination had a complete remission rate of 30% (IQR, 21%‒42%; HR, 0.61; 95% CI, 0.40‒0.94). Patients who received the four-drug MATRix combination had a complete remission rate of 49% (95% CI, 38%‒60%).
- The addition of rituximab and thiotepa to high-dose methotrexate plus cytarabine resulted in a significant improvement in CR, PFS, and OS.[26][Level of evidence A1]
- In a randomized, nonblinded multicenter trial, 79 patients were assigned to receive high-dose methotrexate with or without cytarabine.[27][Level of evidence B1]
- The 3-year PFS rate was better for patients who received the two-drug regimen (HR, 0.54; 95% CI, 0.31–0.92; P = .01).
- There was no statistical difference in the 3-year OS rate (46% for the two-drug regimen vs. 32% for the one-drug regimen; HR, 0.65; 95% CI, 0.38–1.13; P = .07).
- This trial was the basis for setting the combination of high-dose methotrexate and high-dose cytarabine as the control arm in the MATRix trial.
- In a randomized, prospective, multicenter trial, 200 patients were assigned to receive intravenous high-dose methotrexate, carmustine, teniposide, and oral prednisone with or without rituximab.[28][Level of evidence B1]
- With a median follow-up of 32.9 months, there was no difference in the 1-year event-free survival (EFS) rate: 52% with rituximab (95% CI, 42%−61%) and 49% without rituximab (95% CI, 39%−58%; HR, 1.00; 95% CI, 0.70−1.43; P = .99).
- Several other combination induction regimens were created empirically and presented as phase II trials.[29][Level of evidence C3]
- Rituximab + high-dose methotrexate + procarbazine + vincristine (R-MPV) (objective response rate [ORR], 97%; CR, 66%)[23].
- High-dose methotrexate + rituximab + temozolamide (HD MTX + R + TEM) (ORR, 80%; CR, 66%).[20]
- High-dose methotrexate ± rituximab (HD MTX ± R) + other chemotherapy (retrospective analysis of 885 patients) (ORR, 59%; CR, 50%).[29]
Summary
High-dose methotrexate regimens delivered with rituximab and other chemotherapeutic agents is used for induction therapy. The MATRix regimen described above has become one such standard based on randomized OS benefit with a four-drug regimen versus a two-drug or a three-drug regimen.[26][Level of evidence 1A] The MATRix regimen has never been compared with some of the other combination therapies mentioned above. A meta-analysis of rituximab randomized trials found improved PFS with the addition of rituximab (HR, 0.65; 95% CI, 0.45–0.95) but no difference in OS.[30][Level of evidence B2]
Consolidation after induction chemotherapy
Consolidation therapy with or without WBRT
Evidence (consolidation therapy with or without WBRT):
- In a prospective, randomized, phase II trial, 87 patients (median age, 59–66 years) had induction therapy with high-dose methotrexate + high-dose cytarabine + rituximab + procarbazine + vincristine. Afterward, 37 patients had consolidation therapy with low-dose WBRT at 23.4 Gy.[31]
- With a median follow-up of 55 months, the 2-year intention-to-treat PFS was 78% with low-dose WBRT versus 54% without low-dose WBRT (HR, 0.51; P = .015).[31][Level of evidence B1]
- Investigator-assessed neurotoxicity was less than 15% in each arm and not significantly different. Another small phase II trial that examined low-dose WBRT at 23.4 Gy also found no increased problems seen on neuropsychological testing.[32,33]
- In a prospective, randomized, phase II trial of 97 newly diagnosed patients who received high-dose methotrexate combination therapy for induction, patients were randomly assigned to receive WBRT at 40 Gy versus ASCT.[34]
- With a median follow-up of 8 years, deterioration of balance was significantly greater for patients who received WBRT versus patients who received ASCT (52% vs. 10%, P ≤ .001). Worsening neurocognition was also greater for patients who received WBRT (64% vs. 13%, P < .001).
- The 8-year EFS rate was 67% for patients who received ASCT versus 39% for patients who received WBRT (HR, 0.13; P < .001). There was no significant difference in OS (69% for ASCT vs. 54% for WBRT).[34][Level of evidence B1]
- The authors concluded that 40 Gy WBRT should be avoided in first-line treatment because of its neurotoxicity and inferior efficacy.
- In a prospective, randomized trial of 551 immunocompetent patients with newly diagnosed primary CNS lymphoma, all patients received induction chemotherapy with six cycles of high-dose methotrexate (4 g/m2) with or without ifosfamide. After chemotherapy was completed, responders were randomly assigned to receive either WBRT (45 Gy) or no treatment for complete-response patients and cytarabine for partial-response patients.[35]
- There was no statistical difference in median OS at 32.4 months for patients who received WBRT versus at 37.1 months for those who did not receive WBRT (HR, 1.06; 95% CI, 0.80–1.40; P = .71).[35][Level of evidence A1]
- Treatment-related neurotoxic effects were significantly worse in the WBRT arm.
- In a prospective, randomized trial, 410 immunocompetent patients with newly diagnosed primary CNS lymphoma were scheduled to receive high-dose methotrexate. Patients were randomly assigned to receive either WBRT or no radiation therapy.[36]
- In the intent-to-treat population, WBRT was associated with longer PFS at 15.4 months versus 9.9 months (HR, 0.79; 95% CI, 0.64–0.98; P = .034). There was no difference in OS at 32.4 months versus 36.1 months (HR, 0.98; 95% CI, 0.79–1.26; P = .98).[36][Level of evidence B1]
- Long-term treatment-related neurotoxic effects were not reported, and the induction chemotherapy would now be considered substandard.
Summary
The significant neurotoxicity of standard dose WBRT [37] has reduced its role to short-duration disease control at relapse, when the expected survival is short enough that the benefit outweighs the longer-term neurological consequences. For patients unable to undergo consolidation with ASCT due to age, performance status, or comorbidities, low-dose WBRT (23.4 Gy) would be a consolidation option.
Consolidation therapy with or without ASCT
Evidence (consolidation therapy with or without ASCT):
- In a prospective, randomized trial published in abstract form, 346 patients with newly diagnosed primary CNS lymphoma (patients aged 65 years and younger and patients aged 66–70 years with a performance status of 2 or lower) underwent induction therapy with 4 cycles of rituximab, high-dose methotrexate, high-dose cytarabine, and thiotepa (IELSG43 [NCT02531841]). Eighty-six patients discontinued treatment due to toxicity or progression. Of the 260 patients who completed induction therapy, 229 patients were randomly assigned to receive either chemotherapy consolidation with rituximab, dexamethasone, etoposide, ifosfamide, and carboplatin (n = 115) or ASCT using BCNU and thiotepa (n = 114).[38][Level of evidence A1]
- With a median follow-up of 44 months, the 3-year OS rate was 86% (78%–91%) for ASCT versus 71% (61%–78%) for chemotherapy alone (HR, 0.47; P = .01).[38][Level of evidence A1]
- The 3-year PFS was 79% (71%–86%) for ASCT versus 53% (43%–62%) for chemotherapy alone.
- There was no negative effect on neurocognitive function in either arm in the absence of progression.
- This was the first randomized trial establishing a survival advantage for newly diagnosed patients receiving ASCT who are young enough and healthy enough to endure this aggressive approach.
- In a prospective, randomized, phase II trial, 97 newly diagnosed patients receiving high-dose methotrexate combination therapy for induction were randomly assigned to receive WBRT at 40 Gy or ASCT.[34]
- With a median follow-up of 8 years, deterioration of balance was significantly greater for patients who received WBRT than for patients who received ASCT (52% vs. 10%, P ≤ .001). Worsening neurocognition was also greater for patients who received WBRT (64% vs. 13%, P < .001).
- The 8-year EFS rate was 67% for patients who received ASCT versus 39% for patients who received WBRT (HR, 0.13; P < .001). There was no difference in OS (69% for ASCT vs. 65% for WBRT).[34][Level of evidence B1]
- The authors concluded that 40 Gy WBRT should be avoided in first-line treatment because of its neurotoxicity and inferior efficacy.
- A prospective, randomized, phase II trial in newly diagnosed patients aged 75 years and younger received intensive induction therapy with high-dose methotrexate at 8 g/m2 every 2 weeks, temozolamide, rituximab, and high-dose cytarabine. Patients were randomly assigned at the start of therapy to consolidation with thiotepa + BCNU conditioning with ASCT or nonmyeloablative therapy with high-dose cytarabine with a 46-hour infusion of etoposide (EA).[39]
- With a median follow-up of 3.8 years, the median PFS was 6 years (95% CI, 3.9-NR) for ASCT versus 2.4 years (95% CI, 0.6-NR) for EA (P = .02).[39][Level of evidence B1]
- PFS from time of consolidation was not statistically different (HR, 0.58; 95% CI, 0.25–1.36; P = .21).
- There was no difference in the 3-year OS rate: 83% (69%–91%) for ASCT and 72% (57%–82%) for EA.
- This trial showed the limitations of induction therapy, which affected the impact of consolidation.
- Several phase II studies evaluated consolidation with intensive chemotherapy supported by ASCT.[19,20,23,40,41,42,43] This approach is appropriate for patients aged 80 years and under with few comorbidities, good performance status, and an adequate response to induction therapy.
Summary
Consolidation therapy with ASCT results in an OS advantage for newly diagnosed patients with good performance status, few comorbidities, and an adequate response to induction therapy (in this case, the MATRix regimen: high-dose methotrexate, high-dose cytarabine, rituximab, and temozolamide).[39] For patients unable to proceed to ASCT, consolidation with low-dose WBRT (32.4 Gy) or non-myeloablative therapy might be considered.
Current Clinical Trials
Use our advanced clinical trial search to find NCI-supported cancer clinical trials that are now enrolling patients. The search can be narrowed by location of the trial, type of treatment, name of the drug, and other criteria. General information about clinical trials is also available.
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