TO THE EDITOR:

Chimeric antigen receptor (CAR) T-cell therapy has been approved for the treatment of relapsed/refractory hematologic malignancies.1-5 For relapsed/refractory mantle cell lymphoma (MCL), a single infusion of brexucabtagene autoleucel (brex-cel, KTE-X19), an anti-CD19 CAR T-cell therapy, was associated with an overall response rate of 93% and complete response (CR) rate of 67%. Importantly, remissions were durable with 57% of patients remaining in remission after 12 months.1,6 Brex-cel-related toxicities were manageable; cytokine release syndrome (CRS) and immune effector cell-associated neurotoxicity syndrome (ICANS) occurred at grade ≥ 3 in 15% and 31% of patients, respectively. Notably, this study excluded patients with active or history of central nervous system (CNS) lymphoma. There is an unmet need for patients with CNS MCL. They have poor outcomes, and there are no consensus treatment guidelines for these patients.7,8 Studies show CAR T-cell therapy is safe and effective in primary and secondary CNS diffuse large B-cell lymphoma (DLBCL).9-12 Here, we report a case of relapsed MCL with active secondary CNS involvement successfully treated with brex-cel.

A 74-year-old woman with hyperlipidemia and hypothyroidism presented with fatigue and 20-pound weight loss over 2 months. Laboratory results showed a white blood cell count (WBC) 17.9 × 103/μL, hemoglobin level 9.9 g/d, and platelet count 146 × 103/μL. Flow cytometry (FC) on peripheral blood demonstrated a CD5-positive, κ-restricted B-cell population comprising 30% of nucleated white blood cells. Fluorescence in situ hybridization tests detected a t(11;14)(q13;q32) translocation consistent with MCL. Deletion of 11q22.3 (Ataxia-Telangiesctasia Mutated) and trisomy 12 were found and a 17p deletion was not. A staging positron emission tomography (PET)/computed tomography (CT) scan revealed diffuse lymphadenopathy and splenomegaly (Figure 1A). Bone marrow biopsy confirmed 70% cellular involvement by classical MCL with Ki-67 of ∼30%. There was no evidence of blastoid or pleomorphic morphology. The modified MCL International Prognostic Index score was high-risk. The correlative sciences reported in this manuscript are approved by an institutional review board. It was conducted according to the Declaration of Helsinki.

Figure 1.

Initial and subsequent imaging of a patient with CNS MCL who achieved remission after brex-cel infusion. (A) Initial PET/CT scan demonstrating MCL within the bilateral cervical, supraclavicular, axillary, mediastinal, iliac, and inguinal regions; mild splenomegaly with diffuse hypermetabolism; bilaterally enlarged kidneys with hypermetabolic cortical thickening; nodular hypermetabolic foci along the large bowel; and diffuse bone marrow space hypermetabolism. (B) Magnetic resonance imaging of the spine at the time of first relapse. The red arrow indicates the presence of enhancing soft tissue posterior to the sacral spine nerve levels 2 and 3. (C) PET/CT scan prior to CAR T therapy and Day +28 after therapy. The red arrows highlight the presence of enlarged hypermetabolic left inguinofemoral and right axillary lymph nodes prior to treatment. These lesions resolved after CAR T therapy. (D) Upper plot shows CD8+ versus CD19 anti-idiotype–positive cells (CD19 anti-idiotype antibody is described in Jena et al24) on peripheral blood monocytes gated on live CD45+ CD3+ CD14 cells via a gating strategy as described previously.25 CD4+ and CD8+ CAR T-cells are shown on the left and right, respectively. On a log scale, the absolute number of circulating CD4+ (blue), CD8+ (red), and total CD19 CAR T-cells (green) after infusion as measured by flow cytometry over time.

Figure 1.

Initial and subsequent imaging of a patient with CNS MCL who achieved remission after brex-cel infusion. (A) Initial PET/CT scan demonstrating MCL within the bilateral cervical, supraclavicular, axillary, mediastinal, iliac, and inguinal regions; mild splenomegaly with diffuse hypermetabolism; bilaterally enlarged kidneys with hypermetabolic cortical thickening; nodular hypermetabolic foci along the large bowel; and diffuse bone marrow space hypermetabolism. (B) Magnetic resonance imaging of the spine at the time of first relapse. The red arrow indicates the presence of enhancing soft tissue posterior to the sacral spine nerve levels 2 and 3. (C) PET/CT scan prior to CAR T therapy and Day +28 after therapy. The red arrows highlight the presence of enlarged hypermetabolic left inguinofemoral and right axillary lymph nodes prior to treatment. These lesions resolved after CAR T therapy. (D) Upper plot shows CD8+ versus CD19 anti-idiotype–positive cells (CD19 anti-idiotype antibody is described in Jena et al24) on peripheral blood monocytes gated on live CD45+ CD3+ CD14 cells via a gating strategy as described previously.25 CD4+ and CD8+ CAR T-cells are shown on the left and right, respectively. On a log scale, the absolute number of circulating CD4+ (blue), CD8+ (red), and total CD19 CAR T-cells (green) after infusion as measured by flow cytometry over time.

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She achieved a CR after 6 cycles of rituximab–bendamustine. Six months later, lower extremity weakness and pain occurred. Cerebrospinal fluid (CSF) analysis showed WBC 91/μL, protein 259 mg/dL, and glucose < 10 mg/dL. FC of the CSF demonstrated a CD5-positive, κ-restricted B-cell population comprising 33% of all cells, consistent with CNS relapse. Magnetic resonance imaging (MRI) of the brain and spine demonstrated enhancement of the lower lumbar nerve roots within the neural foramen and along the nerve roots of the cauda equina in addition to enhancing soft tissue posterior to the sacral spinal nerves at levels 2 and 3 (Figure 1B). A contemporaneous CT scan did not show systemic disease. The patient, now with an Eastern Cooperative Oncology Group performance status 2, underwent palliative radiation (4 Gy) to the sacral region and started ibrutinib 560 mg daily since more aggressive chemotherapy. Six weeks later, repeat CSF analysis showed persistent disease with 96 WBC/μL and FC showed a malignant B-cell population comprising 60% of all cells. Ibrutinib was stopped; high-dose methotrexate (MTX) 3 g/m2 plus rituximab 375 mg/m2 given every 2 weeks was initiated. After 2 cycles, repeat CSF analysis demonstrated 135 WBC/μL with FC showing persistent malignant cells comprising 33% of total events. MTX was halted and after starting weekly intrathecal (IT) cytarabine 50 mg, the CSF WBC rapidly declined. Five weeks later, CSF studies showed no detectable malignant cells. A PET/CT showed no systemic disease. She continued maintenance IT cytarabine 50 mg every 2 weeks.

Seven weeks later, her CSF studies demonstrated CNS relapse with 23 WBC/μL despite. PET/CT also showed systemic relapse with enlarged left inguinofemoral and right axillary lymph nodes (Figure 1C). She started twice weekly IT triple therapy with methotrexate 12 mg, cytarabine 50 mg, and hydrocortisone 50 mg. One week later, she underwent leukapheresis for standard-of-care brex-cel. After standard fludarabine/cyclophosphamide lymphodepletion, brex-cel was infused 19 days postapheresis. The CSF studies just prior to CAR T-cell infusion showed persistent disease. On day +13, she developed a fever of 38°C consistent with grade-1 CRS. Infectious workup was negative, and she defervesced without interventions. These symptoms were associated with CD19 CAR T-cell expansion as measured by FC (Figure 1D). On day +14, she developed slurred speech, lethargy, visual hallucinations, and intermittent headaches, without abnormalities seen on CT and MRI brain imaging; an electroencephalogram was not performed. For grade-2 ICANS and concurrent grade-1 CRS, tocilizumab 450 mg IV, dexamethasone 10 mg every 6 hours for 5 days (followed by a 5-day taper), and anakinra 100 mg every 6 hours (between days +17 to +21 after persistent grade-2 ICANS) were given. Her neurologic symptoms resolved in 8 days on day +22, associated with a reduction in CD19 CAR T-cells (Figure 1D). Day +28 and day +90 PET/CT scans and CSF analysis were consistent with a CR; day +90 minimal residual disease analysis via clonoSEQ showed no detectable tumor clones.

MCL comprises ∼3% of adult non-Hodgkin lymphoma cases,13,14 and CNS involvement is rare with a crude incidence of 4%. When present, prognosis is poor with a median overall survival of 3 to 6 months.7,8 Interestingly, CNS relapse in MCL is typically leptomeningeal rather than parenchymal, unlike DLBCL in which parenchymal involvement is more frequent.7 Risk factors for CNS relapse include blastoid histology, high Ki-67 expression, high lactate dehydrogenase, and high-risk International Prognostic Index score.8,15,16 However, via multivariable analysis, Ki-67 ≥ 30% was the only significant risk factor predicting CNS relapse with a 2-year cumulative incidence of 25.4%.16 CNS prophylaxis for MCL is not the standard of care since there is no convincing evidence that high-dose antimetabolites (eg, cytarabine, methotrexate) or rituximab reduces risk of CNS relapse.16 

The treatment for CNS relapse remains challenging. Historical treatment strategies included MTX, high-dose cytarabine, IT chemotherapy, and radiotherapy. Ibrutinib and lenalidomide can induce durable response in MCL,17,18 and each has demonstrated efficacy in relapsed/refractory CNS lymphoma.19-21 Ibrutinib has demonstrated CNS activity in CNS-relapsed MCL.22,23 In a retrospective multicenter analysis (n = 84), ibrutinib was associated with superior CR rates (42% vs 22%, P = .02) and 1-year overall survival (59% vs 25%, P = .011) compared with alternative therapies (eg, MTX or cytarabine, ifosfamide) in patients with CNS-relapsed MCL.23 

Recent studies have shown the safety and efficacy of CAR T-cell therapy in primary and secondary CNS DLBCL.9-12 In a single-center retrospective analysis of 5 patients with primary CNS DLBCL treated with anti-CD19 CAR T-cell therapy, 3 achieved a CR, and 2 had stable disease.10 This study demonstrated that CAR T cells can traffic to the CNS space. In a single-center retrospective analysis of 7 patients with secondary CNS lymphoma, 6 patients (85.7%) achieved a CR at day 28 with median progression-free survival of 83 days (range, 28-219 days).11 ICANS occurred in 3 patients. In summary, these studies show that CNS involvement should not preclude patients from receiving CAR T-cell therapy.

In our patient’s case, she developed leptomeningeal CNS relapse that did not initially respond to ibrutinib and MTX. Her CNS disease was initially sensitive to IT cytarabine but relapsed quickly with CNS and systemic disease. After brex-cel infusion, this patient achieved a CR in both CNS and extra-CNS compartments. To our knowledge, this is the first reported case of brex-cel used in an older patient with CNS-relapsed MCL. This case provides further support to the growing literature reporting the safety and efficacy of CAR T-cell therapy in CNS lymphoma, including MCL.

Contribution: K.V. and M.J.F. jointly analyzed the data and wrote the paper.

Conflict-of-interest disclosure: The authors declare no competing financial interests.

Correspondence: Matthew J. Frank, 300 Pasteur Dr, Room H0145, Stanford, CA 94305-5623; e-mail: [email protected].

1.
Wang
M
,
Munoz
J
,
Goy
A
, et al
.
KTE-X19 CAR T-cell therapy in relapsed or refractory mantle-cell lymphoma
.
N Eng J Med
.
2020
;
382
(
14
):
1331
-
1342
.
2.
Shah
BD
,
Ghobadi
A
,
Oluwole
OO
, et al
.
KTE-X19 for relapsed or refractory adult B-cell acute lymphoblastic leukaemia: phase 2 results of the single-arm, open-label, multicentre ZUMA-3 study
.
Lancet
.
2021
;
398
(
10299
):
491
-
502
.
3.
Berdeja
JG
,
Madduri
D
,
Usmani
SZ
, et al
.
Ciltacabtagene autoleucel, a B-cell maturation antigen-directed chimeric antigen receptor T-cell therapy in patients with relapsed or refractory multiple myeloma (CARTITUDE-1): a phase 1b/2 open-label study
.
Lancet
.
2021
;
398
(
10297
):
314
-
324
.
4.
Jacobson
CA
,
Chavez
JC
,
Sehgal
AR
, et al
.
Axicabtagene ciloleucel in relapsed or refractory indolent non-Hodgkin lymphoma (ZUMA-5): a single-arm, multicentre, phase 2 trial
.
Lancet Oncol
.
2022
;
23
(
1
):
91
-
103
.
5.
Locke
FL
,
Miklos
DB
,
Jacobson
CA
, et al;
All ZUMA-7 Investigators and Contributing Kite Members
.
Axicabtagene ciloleucel as second-line therapy for large B-cell lymphoma
.
N Engl J Med
.
2022
;
386
(
7
):
640
-
654
.
6.
Jain
P
,
Wang
Y
,
Locke
FL
, et al
.
Brexucabtagene autoleucel for relapsed/refractory mantle cell lymphoma: real-world experience from the United States lymphoma CAR T consortium
.
J Clin Oncol
.
2022
;
40
(
16_suppl
):
e19583
.
7.
Cheah
CY
,
George
A
,
Giné
E
, et al;
European Mantle Cell Lymphoma Network
.
Central nervous system involvement in mantle cell lymphoma: clinical features, prognostic factors and outcomes from the European Mantle Cell Lymphoma Network
.
Ann Oncol
.
2013
;
24
(
8
):
2119
-
2123
.
8.
Ferrer
A
,
Bosch
F
,
Villamor
N
, et al
.
Central nervous system involvement in mantle cell lymphoma
.
Ann Oncol
.
2008
;
19
(
1
):
135
-
141
.
9.
Frigault
MJ
,
Dietrich
J
,
Martinez-Lage
M
, et al
.
Tisagenlecleucel CAR T-cell therapy in secondary CNS lymphoma
.
Blood
.
2019
;
134
(
11
):
860
-
866
.
10.
Siddiqi
T
,
Wang
X
,
Blanchard
MS
, et al
.
CD19-directed CAR T-cell therapy for treatment of primary CNS lymphoma
.
Blood Adv
.
2021
;
5
(
20
):
4059
-
4063
.
11.
Ahmed
G
,
Hamadani
M
,
Shah
NN
.
CAR T-cell therapy for secondary CNS DLBCL
.
Blood Adv
.
2021
;
5
(
24
):
5626
-
5630
.
12.
Alcantara
M
,
Houillier
C
,
Blonski
M
, et al
.
CAR T-cell therapy in primary central nervous system lymphoma: the clinical experience of the French LOC network
.
Blood
.
2022
;
139
(
5
):
792
-
796
.
13.
National Comprehensive Cancer Network
.
B-Cell Lymphomas (Version 4) 2022
. Accessed 28 June 2022https://www.nccn.org/professionals/physician_gls/pdf/b-cell.pdf.
14.
Cheah
CY
,
Seymour
JF
,
Wang
ML
.
Mantle cell lymphoma
.
J Clin Oncol
.
2016
;
34
(
11
):
1256
-
1269
.
15.
Conconi
A
,
Franceschetti
S
,
Lobetti-Bodoni
C
, et al
.
Risk factors of central nervous system relapse in mantle cell lymphoma
.
Leuk Lymphoma
.
2013
;
54
(
9
):
1908
-
1914
.
16.
Chihara
D
,
Asano
N
,
Ohmachi
K
, et al
.
Ki-67 is a strong predictor of central nervous system relapse in patients with mantle cell lymphoma (MCL)
.
Ann Oncol
.
2015
;
26
(
5
):
966
-
973
.
17.
Wang
ML
,
Rule
S
,
Martin
P
, et al
.
Targeting BTK with ibrutinib in relapsed or refractory mantle-cell lymphoma
.
N Engl J Med
.
2013
;
369
(
6
):
507
-
516
.
18.
Trněný
M
,
Lamy
T
,
Walewski
J
, et al;
SPRINT trial investigators and in collaboration with the European Mantle Cell Lymphoma Network
.
Lenalidomide versus investigator’s choice in relapsed or refractory mantle cell lymphoma (MCL-002; SPRINT): a phase 2, randomised, multicentre trial
.
Lancet Oncol
.
2016
;
17
(
3
):
319
-
331
.
19.
Soussain
C
,
Choquet
S
,
Blonski
M
, et al
.
Ibrutinib monotherapy for relapse or refractory primary CNS lymphoma and primary vitreoretinal lymphoma: final analysis of the phase II ‘proof-of-concept’ iLOC study by the Lymphoma study association (LYSA) and the French oculo-cerebral lymphoma (LOC) network
.
Eur J Cancer
.
2019
;
117
:
121
-
130
.
20.
Rubenstein
JL
,
Geng
H
,
Fraser
EJ
, et al
.
Phase 1 investigation of lenalidomide/rituximab plus outcomes of lenalidomide maintenance in relapsed CNS lymphoma
.
Blood Adv
.
2018
;
2
(
13
):
1595
-
1607
.
21.
Ghesquieres
H
,
Chevrier
M
,
Laadhari
M
, et al
.
Lenalidomide in combination with intravenous rituximab (REVRI) in relapsed/refractory primary CNS lymphoma or primary intraocular lymphoma: a multicenter prospective ‘proof of concept’ phase II study of the French Oculo-Cerebral lymphoma (LOC) Network and the Lymphoma Study Association (LYSA)
.
Ann Oncol
.
2019
;
30
(
4
):
621
-
628
.
22.
Bernard
S
,
Goldwirt
L
,
Amorim
S
, et al
.
Activity of ibrutinib in mantle cell lymphoma patients with central nervous system relapse
.
Blood
.
2015
;
126
(
14
):
1695
-
1698
.
23.
Rusconi
C
,
Cheah
C
,
Tucker
D
, et al
.
Ibrutinib compared to immuno-chemotherapy for central nervous system relapse of mantle cell lymphoma: a report from Fondazione Italiana Linfomi (FIL) and European Mantle Cell Lymphoma Network (EMCLN). [Abstract.]. Eur Hematol Assoc
. Accessed 22 February 2022. Published online 2020https://library.ehaweb.org/eha/2020/eha25th/295049/chiara.rusconi.ibrutinib.compared.to.immuno-chemotherapy.for.central.nervous.html?f=menu=6.
24.
Jena
B
,
Maiti
S
,
Huls
H
, et al
.
Chimeric antigen receptor (CAR)-specific monoclonal antibody to detect CD19-specific T cells in clinical trials
.
PLoS One
.
2013
;
8
(
3
):
e57838
.
25.
Spiegel
JY
,
Patel
S
,
Muffly
L
, et al
.
CAR T cells with dual targeting of CD19 and CD22 in adult patients with recurrent or refractory B cell malignancies: a phase 1 trial
.
Nat Med
.
2021
;
27
(
8
):
1419
-
1431
.

Author notes

Data sharing requests should be sent to the corresponding author, Matthew J. Frank ([email protected]).