Treatment of mantle cell lymphoma in Asia: a consensus paper from the Asian Lymphoma Study Group

Mantle cell lymphoma (MCL) is a rare B cell malignancy subtype and is typically clinically aggressive with a poor prognosis [1, 2]. The clinical course of MCL is heterogeneous, with some cases characterized by splenomegaly, peripheral blood lymphocytosis, and with little or no nodal disease, and thereby presenting with indolent features [3‐7]. Patients with MCL may present with generalized lymphadenopathy; however, extra-nodal involvement is common in the peripheral blood, bone marrow, and gastrointestinal tract [8].

The diagnosis of MCL is based on lymph node biopsy, with histological review showing typical patterns including nodular, diffuse, pleomorphic, and blastoid—the latter two associated with particularly aggressive disease [9]. Typically, immunophenotyping shows CD19, CD20, CD22, CD43, CD79a, CD5, and FMC7 positivity and CD23, CD10, CD200, and BCL6 negativity. Evidence of t(11;14)(q13;q32) or cyclin D1 expression is required to diagnose MCL; however, approximately 5% of cases otherwise consistent with MCL may be cyclin D1-negative and may present with cyclin D2-positive disease instead [8]. Additional tests including SOX-11 should be considered in MCL to be distinguished from other diseases or to determine clinically indolent diseases [10]. Diagnostic workup also includes physical examination, viral serology (if rituximab treatment is contemplated), computed tomography (CT), positron emission tomography (PET)-CT or magnetic resonance imaging, and bone marrow aspiration and biopsy to enable the accurate staging of disease [11]. Cerebrospinal fluid evaluation with or without central nervous system prophylaxis should be performed in some cases [10]. Staging follows the Lugano classification (Table 1).

The reported survival rates of patients with MCL, at least in East Asia, were similar to those of Western countries. Five-year overall survival (OS) and progression-free survival (PFS) rates reported in China in 2017 were 35.5% and 8.8%, respectively [16]. Taiwan has recorded a relatively better prognosis, with 5-year survival rates of 78% in 2006 though a small number of patients were included in these analyses [19, 25, 26]. A Korean retrospective review of the medical records of 131 patients with MCL showed a similar pattern of presentation and prognosis as seen in mainland China, Hong Kong, and Taiwan, with 2-year OS and PFS of 64.7% and 39.7%, respectively [27].

Treatment guidelines have been developed internationally, in particular, by the National Comprehensive Cancer Network (NCCN), the European Society of Medical Oncology (ESMO), and the British Society of Hematology (BSH) [7, 10, 11]. However, published data or guidance on the clinical characteristics and management of MCL are generally lacking for patient populations from Asia. Importantly, the level of healthcare resources and available treatments in Asia vary from one country/region to another. While some areas may have only basic access to oncology care, some highly urbanized areas may have world-class expertise and more novel agents at their disposal [28, 29]. Moreover, Asian patients may have different comorbidities, such as hepatitis B virus infection. Infection with hepatitis B virus is a common comorbidity in patients with lymphoma in Asia, with a 2- to 5-fold higher prevalence among patients with NHL compared with the general population [29]. In these patients who have inactive hepatitis B virus infection, chemotherapy may lead to hepatitis B virus reactivation, and thus, this should be an important consideration for the management of patients with MCL in Asia.

In this context, guidelines from Western regions may not be appropriate in Asia, and tailored treatment guidance may be needed.

This paper aims to review the available treatment options and, where clinical gaps exist, to provide expert consensus from the ALSG on the appropriate management of MCL in Asian patients.

Various therapeutics are used in the management of MCL, with different mechanisms of action and targets that allow the use of a wide variety of combination regimens. Traditional chemotherapeutic agents used include cyclophosphamide, doxorubicin, vincristine, cytarabine (Ara-C), cisplatin, and bendamustine. These are often combined in chemotherapeutic regimens with a steroid. Recently, the monoclonal antibody, rituximab; the immunomodulatory agent, lenalidomide; and the proteasome inhibitor, bortezomib, have been incorporated into treatment regimens, followed by the introduction of newer, small-molecule inhibitors (i.e., ibrutinib and acalabrutinib). Finally, a role remains for autologous hematopoietic stem cell transplant (auto-HSCT) and allogeneic hematopoietic stem cell transplant (allo-HSCT) in MCL. While conventional chemotherapy plays a vital role in the treatment of MCL, there is still limited robust evidence to support its use. A summary of available therapies is shown in Table 2.

Guidelines agree that the choice of salvage therapy is influenced by the prior lines of therapy used and duration of response to prior therapy. Non-cross-resistant regimens are preferential, specifically the use of newer targeted approaches for patients with early relapse, with the BTK inhibitor ibrutinib showing the highest response rates [11, 62‐64]. If ibrutinib is contraindicated, lenalidomide with or without rituximab may offer some clinical benefit [11, 65‐67].

Ibrutinib monotherapy demonstrated an ORR of 68%, a CR rate of 21%, and a median PFS of 13.9 months, with an additional benefit demonstrated with the addition of rituximab (ORR 87%; CR 38%; 15-month PFS 69%) [63, 64]. In the 3-year follow-up of the RAY study, ibrutinib showed a favorable OS trend versus temsirolimus (median OS 30.3 versus 23.5 months; hazard ratio [HR] 0.74 [95% CI 0.54–1.02], P = 0.0621), with the most benefit seen in patients receiving only one prior line of therapy [68]. In addition, in a pooled analysis after an extended 3.5-year follow-up of phase II and III clinical trials of patients with relapsed/refractory MCL, those who received second-line therapy and those achieving a CR derived the greatest benefit from ibrutinib treatment; median PFS and OS were 12.5 and 26.7 months, respectively [69].

The use of bortezomib-based chemotherapy showed an ORR of 33%, a CR rate of 8%, and a median PFS of 6.5 months; responses were improved with the addition of rituximab (ORR 58%; CR 16%) [70, 71]. Lenalidomide demonstrated limited clinical benefit with an ORR of 28%, a CR rate of 8%, and a median PFS of 4 months. These rates increased with the addition of rituximab to an ORR of 57%, a CR rate of 36%, and a median PFS of 11.1 months [66, 72]. Follow-on BTK inhibitors include acalabrutinib, which has demonstrated an ORR of 81%, a CR rate of 40%, and a 67% PFS at 12 months, and zanubrutinib, which has demonstrated an ORR of 86.5%, a CR rate of 29.7%, and a median PFS of 15.4 months [73, 74]. These findings should be confirmed in further studies with larger sample sizes.

Rituximab monotherapy in a small phase II study in Japanese patients with relapsed MCL demonstrated an ORR of 46% (6/13 patients) [75]. A subsequent analysis of factors affecting response in this study suggested that the ORR is higher in rituximab-treated patients receiving one versus two or more prior lines of chemotherapy, and PFS was shorter in patients with extra-nodal disease and those receiving two or more prior lines of chemotherapy [76]. Phase I/II clinical trial data demonstrated consistency in results seen for ibrutinib in Japanese patients, with a durable response over a median of 22.5 months [77, 78]. ORR was 93.8%, with CR seen in 31.3% of patients by the end of the phase II follow-up [78]. Real-world data of ibrutinib monotherapy in a salvage setting in Korea showed a favorable ORR and duration of response; however, higher MIPI and/or prior bendamustine exposure was associated with ibrutinib treatment failure and poorer outcomes [79]. Additional data from a Korean retrospective analysis of 75 patients with advanced MCL treated with ibrutinib reported a 70% ORR; at a median follow-up of 30.5 months, the median PFS was 18.6 months; and among elderly patients, better outcomes from ibrutinib were achieved in second-line versus later lines of therapy (median PFS 24.4 versus 5.8 months; P = 0.015) [80].