Long-term follow-up from a phase 1/2 study of single-agent bortezomib in relapsed systemic AL amyloidosis

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116

This phase 1/2 study assessed the safety, tolerability, and preliminary efficacy of the oral proteasome inhibitor (PI) ixazomib in patients with relapsed/refractory immunoglobulin light chain (AL) amyloidosis. Ixazomib was administered to adult patients with relapsed/refractory AL amyloidosis after 1 or more prior lines of therapy (including bortezomib) on days 1, 8, and 15 of 28-day cycles, for up to 12 cycles. Patients with less than partial response after 3 cycles received oral dexamethasone (40 mg, days 1-4) from cycle 4. A 3+3 dose-escalation phase was followed by 2 expansion cohorts (PI-naive and PI-exposed patients) at the maximum tolerated dose (MTD). Twenty-seven patients were enrolled: 11 during dose escalation (6 at 4.0 mg and 5 at 5.5 mg) and 16 during dose expansion (4.0 mg). Three patients experienced dose-limiting toxicities: 1 at 4.0 mg and 2 at 5.5 mg; the MTD was determined as 4.0 mg. Most common adverse events (AEs) included nausea, skin and subcutaneous tissue disorders (SSTD), diarrhea, and fatigue; grade 3 or higher AEs included dyspnea, fatigue, and SSTD. Overall, the hematologic response rate was 52% in patients treated at the MTD (n = 21). Organ responses were seen in 56% of patients (5 cardiac, 5 renal). Median hematologic progression-free survival was 14.8 months; 1-year progression-free and overall survival rates were 60% and 85%, respectively (median follow-up, 16.9 months). Weekly oral ixazomib appears to be active in patients with relapsed/refractory AL amyloidosis, with a generally manageable safety profile. The study was registered at clinicaltrials.gov as #NCT01318902. A phase 3 study is ongoing (#NCT01659658).

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A phase 1/2 study of the oral proteasome inhibitor ixazomib in relapsed or refractory AL amyloidosis

Sanchorawala

Palladini

Kukreti

et al. 2017

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116

“…In a broader view, the intrinsic toxicity for plasma cells of immunoglobulin fragments prone to misfolding and aggregation deserves to be explored in other monoclonal immunoglobulin-related diseases including light chain (AL) amyloidosis and LCDD, in which preliminary studies suggest that bortezomib-based therapy has a strong impact on renal and patient outcomes. 44,[60][61][62] Transgenic mouse models could be of invaluable interest to explore this issue. 36 Altogether, the present transgenic mouse model of HCDD accurately recapitulates the early steps of the human pathology and represents a valuable tool to explore the mechanisms that govern toxicity of truncated HCs and the sequential events leading to glomerular injury in MIDD.…”

Section: Discussionmentioning

confidence: 99%

A mouse model recapitulating human monoclonal heavy chain deposition disease evidences the relevance of proteasome inhibitor therapy

Bonaud

Bender

Touchard

et al. 2015

Key Points• We created the first transgenic mouse model recapitulating the early pathologic features of Randall-type heavy chain deposition disease.• Production of a truncated immunoglobulin heavy chain heightens plasma cell sensitivity to bortezomib via a terminal unfolded protein response.Randall-type heavy chain deposition disease (HCDD) is a rare disorder characterized by glomerular and peritubular amorphous deposits of a truncated monoclonal immunoglobulin heavy chain (HC) bearing a deletion of the first constant domain (CH1). We created a transgenic mouse model of HCDD using targeted insertion in the immunoglobulin k locus of a human HC extracted from a HCDD patient. Our strategy allows the efficient expression of the human HC in mouse B and plasma cells, and conditional deletion of the CH1 domain reproduces the major event underlying HCDD. We show that the deletion of the CH1 domain dramatically reduced serum HC levels. Strikingly, even with very low serum level of truncated monoclonal HC, histologic studies revealed typical Randall-type renal lesions that were absent in mice expressing the complete human HC. Bortezomibbased treatment resulted in a strong decrease of renal deposits. We further demonstrated that this efficient response to proteasome inhibitors mostly relies on the presence of the isolated truncated HC that sensitizes plasma cells to bortezomib through an elevated unfolded protein response (UPR). This new transgenic model of HCDD efficiently recapitulates the pathophysiologic features of the disease and demonstrates that the renal damage in HCDD relies on the production of an isolated truncated HC, which, in the absence of a LC partner, displays a high propensity to aggregate even at very low concentration. It also brings new insights into the efficacy of proteasome inhibitor-based therapy in this pathology. (Blood. 2015;126(6):757-765) IntroductionTissue deposition of a monoclonal immunoglobulin fragment frequently complicates plasma cell disorders.1,2 Among the wide spectrum of renal diseases associated with monoclonal gammopathies, Randall-type monoclonal immunoglobulin deposition disease (MIDD) is a multisystemic disorder with prominent renal manifestations including glomerular proteinuria and renal failure. 1,[3][4][5] Kidney lesions in MIDD are characterized by nonamyloid amorphous linear deposits of a monoclonal immunoglobulin fragment along tubular, and in most cases, vascular and glomerular basement membranes (BMs). Nodular glomerulosclerosis and diffuse thickening of tubular BMs are commonly observed. 3,6 The most frequent type of MIDD is related to deposition of monoclonal light chain (LC) (LCDD), mostly of the k isotype, but deposits composed of monoclonal heavy chain (HC) only (HCDD) or of light and heavy chain (LHCDD) have been also described. 3,7 Most reported cases of HCDD were characterized by gHC deposits. 4,5,[8][9][10][11] The mechanisms involved in the deposition of monoclonal Ig fragments in MIDD remain poorly understood. Structural peculiarities of the V domains o...

“…65 Prospective trials and large retrospective series proved the efficacy and tolerability of bortezomib in AL amyloidosis. 66,67 More recently, 2 retrospective series showed unprecedented hematologic response rates (up to 90%, with 60%-65% CRs) in treatment-naive patients receiving CyBorD. 68,69 Subsequently, 2 retrospective matched case-control studies confirmed higher response rates with regimens combining bortezomib, dexamethasone, and alkylating agents (BMDex and CyBorD) compared with standard MDex or cyclophosphamide/ thalidomide/dexamethasone (CTD), but failed to demonstrate an overall survival advantage.…”

Section: What's New In Amyloidosis 163mentioning

confidence: 99%

What is new in diagnosis and management of light chain amyloidosis?

Palladini

Merlini

2016

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205

171

Light chain (AL) amyloidosis is caused by a usually small plasma cell clone producing a misfolded light chain that deposits in tissues. Survival is mostly determined by the severity of heart involvement. Recent studies are clarifying the mechanisms of cardiac damage, pointing to a toxic effect of amyloidogenic light chains and offering new potential therapeutic targets. The diagnosis requires adequate technology, available at referral centers, for amyloid typing. Late diagnosis results in approximately 30% of patients presenting with advanced, irreversible organ involvement and dying in a few months despite modern treatments. The availability of accurate biomarkers of clonal and organ disease is reshaping the approach to patients with AL amyloidosis. Screening of early organ damage based on biomarkers can help identify patients with monoclonal gammopathy of undetermined significance who are developing AL amyloidosis before they become symptomatic. Staging systems and response assessment based on biomarkers facilitate the design and conduction of clinical trials, guide the therapeutic strategy, and allow the timely identification of refractory patients to be switched to rescue therapy. Treatment should be risk-adapted. Recent studies are linking specific characteristics of the plasma cell clone to response to different types of treatment, moving toward patient-tailored therapy. In addition, novel anti-amyloid treatments are being developed that might be combined with anti-plasma cell chemotherapy.