Karen Quillen

High-Dose Melphalan and Autologous Stem-Cell Transplantation in Patients with AL Amyloidosis: An 8-Year Study

Context AL amyloidosis responds poorly to oral chemotherapy and rarely leads to elimination of plasma cell dyscrasia. Amyloid cardiomyopathy is a particularly fatal complication of the disease. Contribution Analysis of consecutive patients with AL amyloidosis from 6 separate trials over 8 years shows that high-dose intravenous melphalan therapy combined with autologous stem-cell transplantation greatly improves duration of survival and ameliorates organ dysfunction. Implications Intravenous melphalan therapy combined with stem-cell transplantation represents a clinically significant improvement in treating AL amyloidosis and shows promise in reversing amyloid cardiomyopathy. The Editors The most common form of systemic amyloidosis in the United States is AL (or primary) amyloidosis. In this disease, amyloid fibrils are derived from monoclonal immunoglobulin light chains that are produced by an underlying clonal plasma cell dyscrasia. Although the burden of plasma cells is generally low, accumulation of amyloid deposits in vital organs leads to progressive disability and death. The median survival of untreated patients after diagnosis is 12 months and less than 5 months for those with cardiomyopathy (1-5). AL amyloidosis is reported to occur in 5 to 12 persons per million per year in the United States; however, death records and autopsy results suggest that the incidence may be higher (6, 7). Treatment with oral melphalan results in a modest increase in median survival but rarely eliminates the plasma cell dyscrasia and is not effective for rapidly progressive disease (8-10). Alternative chemotherapy regimens have not improved survival further (11-15). Promising treatment outcomes observed with high-dose intravenous melphalan and autologous stem-cell transplantation in multiple myeloma (16-19) provided a rationale for testing the hypothesis that this treatment would improve survival for patients with AL amyloidosis. Favorable responses to high-dose melphalan and stem-cell transplantation in patients with AL amyloidosis have been reported in case reports and in small series; however, treatment-related mortality was high in multicenter trials (20-28). Our initial experience with treatment in AL amyloidosis indicated that selected patients can tolerate treatment and that hematologic responses and reversal of amyloid-related organ dysfunction can be achieved (29-32). Since 1994, we have evaluated 701 patients with AL amyloidosis, 312 of whom initiated high-dose melphalan treatment and stem-cell transplantation. This longitudinal study examines survival, hematologic response, and improvement of amyloid-related organ disease in patients who were treated with high-dose melphalan and stem-cell transplantation. We contrast these data with features and survival of a simultaneous cohort of patients who were not eligible for treatment. Methods Patients Between July 1994 and June 2002, 701 consecutive patients with AL amyloidosis were evaluated and clinical data were collected with the approval of the Institutional Review Board of Boston University Medical Center. All patients had biopsy-proven amyloid disease and a documented plasma cell dyscrasia, which was diagnosed by the presence of clonal plasma cells in the bone marrow or a monoclonal gammopathy detected by immunofixation electrophoresis of serum or urine proteins (Figure 1). To exclude another type of systemic amyloidosis and a monoclonal gammopathy of unknown significance, all patients with findings compatible with familial or secondary (AA) amyloidosis were tested by DNA analysis for gene mutations in transthyretin, apolipoprotein A1, fibrinogen, and lysozyme known to be associated with amyloidosis and by immunohistochemistry of the biopsy tissue for AA amyloid fibril deposits (33). Patients with multiple myeloma (bone marrow plasmacytosis 30% or lytic bone lesions) were excluded. In patients older than 70 years of age with cardiomyopathy only, a diagnosis of senile cardiac amyloidosis (caused by wild-type transthyretin) was excluded by immunohistochemical examination of a tissue biopsy specimen using antiserum to transthyretin. All patients were evaluated for degree of organ involvement by physical examination, standardized blood tests, electrocardiography, echocardiography, chest radiography, pulmonary function tests, and a 24-hour urine collection. All patients were evaluated by a hematologist and cardiologist and, when appropriate, by nephrology, pulmonology, gastroenterology, and neurology specialists. Figure 1. Algorithm for patient selection and treatment with high-dose melphalan and stem-cell transplantation. High-Dose Melphalan and Stem-Cell Transplantation Eligibility and Protocols Patients were enrolled in several sequential institutional review boardapproved protocols during the 8-year study period. Eligibility criteria for all protocols required biopsy-proven amyloid disease; evidence of a plasma cell dyscrasia; at least 1 major organ affected by amyloid disease; and minimum measures of cardiac, pulmonary, and performance status (Figure 1). Functional measures included cardiac ejection fraction 0.4 or greater, absence of symptomatic pleural effusions, absence of heart failure or arrhythmia resistant to medical management, oxygen saturation of 95% or greater on room air, lung diffusing capacity of 50% or more of predicted, supine systolic blood pressure of 90 mm Hg or greater, and Southwest Oncology Group performance status score of 2 or less unless limited by neuropathy (on a scale of 0 to 4, reflecting percentage of the day [0%, 25%, 50%, 75%, or 100%] spent in bed or in a chair). Minor variations in eligibility requirements for age, renal function, amount of previous chemotherapy, and time from diagnosis while on some protocols are noted in the following discussion; the number of patients affected is also given. The first protocol (July 1994 to December 1995) enrolled 13 patients 60 years of age or younger with serum creatinine values of 176.8 mol/L (2.0 mg/dL) or less; these patients were treated with melphalan, 200 mg/m2 (29). Subsequent protocols had no restriction for impaired renal function. A second protocol (April 1995 to October 1996) enrolled 28 patients 70 years of age or younger and used a lower dose of melphalan, 100 mg/m2 (31). Two protocols (January 1996 to June 1998) evaluated the use of CD34+-selected stem cells in 16 patients (34). The fifth protocol (October 1996 to September 2000) randomly assigned 100 previously untreated patients to treatment with high-dose melphalan and stem-cell transplantation immediately or after 2 cycles of oral melphalan and prednisone. There was no age limit for this protocol; however, melphalan, 140 mg/m2, was given to patients who were older than 65 years of age or had a cardiac ejection fraction between 0.40 and 0.44. The sixth protocol (November 2000 to the present) has enrolled 29 patients 65 years of age or younger. On this protocol, enough stem cells are collected initially to give a second cycle of chemotherapy within the first year if a complete response has not been achieved after an initial course of melphalan at a dose of 200 mg/m2. Other patients who met eligibility criteria (August 1996 to the present) but were excluded from an active protocol because of previous treatment or time from diagnosis were treated by using the established dosing guidelines. Patients who did not meet eligibility for treatment with high-dose melphalan and stem-cell transplantation were grouped according to reasons for ineligibility and were analyzed for survival. Organ system involvement was defined by physical examination; postural blood pressure determinations; standardized serologic laboratory measurements of kidney, liver, and endocrine function; coagulation studies, including factor X levels; electrocardiography; echocardiography; chest radiography; pulmonary function tests with walking oximetry; and a 24-hour urine collection for protein excretion. Cardiac involvement was defined by septal or posterior wall thickening of 13 mm or greater on echocardiography or a clinical syndrome of congestive heart failure or cardiac arrhythmia in the absence of preexisting cardiac disease. Renal involvement was diagnosed by proteinuria of 500 mg/24 h or greater or an elevated serum creatinine concentration in the absence of other causes of renal disease. Gastrointestinal involvement was diagnosed by involuntary loss of 10% of body weight, unexplained diarrhea, hepatomegaly of 4 cm or more below the right costal margin on physical examination, or alkaline phosphatase level 2 or more times the upper limit of normal values. Peripheral neuropathy was diagnosed by symptoms and physical examination or nerve conduction studies, and autonomic neuropathy was defined by orthostatic hypotensiona decrease in systolic blood pressure of 20 mm Hg or greater with upright posture in euvolemic patients. Soft tissue involvement was diagnosed by clinical evidence of macroglossia, soft tissue or subcutaneous deposits, amyloid arthropathy, lymphadenopathy, or nail dystrophy. Coagulation factor X level was considered deficient if it was 50% or less of normal. Stem-Cell Collection and High-Dose Chemotherapy Peripheral blood stem cells were collected by leukapheresis after mobilization using granulocyte colony-stimulating factor. A minimum yield of 2.0 106 CD34+cells/kg of body weight was required to support high-dose chemotherapy. The patients age and cardiac status and the number of stem cells collected determined the melphalan dose (Figure 1). A dose of 200 mg/m2 was administered to patients who were 65 years of age or younger and who had a cardiac ejection fraction of 0.45 or greater and a stem-cell collection of at least 2.5 106 CD34+cells/kg. A dose of 140 mg/m2 was administered to patients who were older than 65 years of age, who had a cardiac ejection fraction of 0.4 to 0.44, or who had a stem-cell collection of 2.0 to 2.5 106 CD34+cells/k

Plasma exchange and glucocorticoid dosing in the treatment of anti-neutrophil cytoplasm antibody associated vasculitis (PEXIVAS): protocol for a randomized controlled trial

BackgroundGranulomatosis with polyangiitis (GPA, Wegener’s) and microscopic polyangiitis (MPA) are small vessel vasculitides collectively referred to as anti-neutrophil cytoplasm antibody-associated vasculitis (AAV). AAV is associated with high rates of morbidity and mortality due to uncontrolled disease and treatment toxicity. Small randomized trials suggest adjunctive plasma exchange may improve disease control, while observational evidence suggests that current oral glucocorticoid doses are associated with severe infections in patients with AAV. A randomized study of both plasma exchange and glucocorticoids is required to evaluate plasma exchange and oral glucocorticoid dosing in patients with AAV.Methods/designPEXIVAS is a two-by-two factorial randomized trial evaluating adjunctive plasma exchange and two oral glucocorticoid regimens in severe AAV. Five hundred patients are being randomized at centers across Europe, North America, Asia, and Australasia to receive plasma exchange or no plasma exchange, and to receive standard or reduced oral glucocorticoid dosing. All patients receive immunosuppression with either cyclophosphamide or rituximab. The primary outcome is the time to the composite of all-cause mortality and end-stage renal disease.PEXIVAS is funded by the National Institute of Health Research (UK), the Food and Drug Administration (USA), the National Institutes of Health (USA), the Canadian Institute of Health Research (Canada), the National Health and Medical Research Council (Australia), and Assistance Publique (France). Additional in-kind supplies for plasma exchange are provided by industry partners (TerumoBCT, Gambro Australia, and Fresenius Australia).DiscussionThis is the largest trial in AAV undertaken to date. PEXIVAS will inform the future standard of care for patients with severe AAV. The cooperation between investigators, funding agencies, and industry provides a model for conducting studies in rare diseases.Trial registrationCurrent Controlled Trials:(ISRCTN07757494) and clinicaltrials.gov:(NCT00987389)

Granulocyte transfusions in severe aplastic anemia: an eleven-year experience

Although they have been used for over 40 years, the value of granulocyte transfusions is controversial. This paper reviews outcomes in patients with severe aplastic anemia given such transfusions at the NIH. See related perspective article on page 1644. Background Infections, particularly those caused by invasive fungi, are a major cause of death in patients with severe aplastic anemia. The purpose of this study was to analyze our experience with granulocyte transfusions in such patients. Design and Methods A retrospective analysis was performed on all patients with severe aplastic anemia who had received granulocyte transfusions between 1997 and 2007 in our institute. Survival to hospital discharge was the primary outcome. Secondary outcomes included microbiological, radiographic and clinical responses of the infection at 7 and 30 days after initiating granulocyte therapy, and post-transfusion absolute neutrophil count, stratified by HLA alloimmunization status. Results Thirty-two patients with severe aplastic anemia underwent granulocyte transfusions; the majority had received horse antithymocyte globulin and cyclosporine A. One quarter of patients had demonstrable HLA alloimmunization prior to the initiation of granulocyte therapy. Infections were evenly divided between invasive bacterial and fungal infections unresponsive to maximal antibiotic and/or antifungal therapy. The median number of granulocyte components transfused was nine (range, 2–43). The overall survival to hospital discharge was 58%. Survival was strongly correlated with hematopoietic recovery. Among the 18 patients who had invasive fungal infections, 44% survived to hospital discharge. Response at 7 and 30 days correlated with survival. The mean post-transfusion absolute neutrophil count did not differ significantly between response groups (i.e. patients grouped according to whether they had complete or partial resolution of infection, stable disease or progressive infection). There was also no difference in mean post-transfusion absolute neutrophil count between the patients divided according to HLA alloimmunization status. Conclusions Granulocyte transfusions may have an adjunctive role in severe infections in patients with severe aplastic anemia. HLA alloimmunization is not an absolute contraindication to granulocyte therapy.

Probiotic-associated high-titer anti-b in a group a platelet donor as a cause of severe hemolytic transfusion reactions

BACKGROUND: Hemolytic transfusion reactions (HTRs) can occur with transfusion of platelets (PLTs) containing ABO‐incompatible plasma. Reported cases have involved group O donors. Two cases of PLT‐mediated HTRs associated with the same group A plateletpheresis component, collected from a donor taking high doses of probiotics are reported.

Tandem cycles of high-dose melphalan and autologous stem cell transplantation increases the response rate in AL amyloidosis

Clinical outcomes of patients with AL amyloidosis treated with high-dose melphalan and stem cell transplantation (HDM/SCT) are tightly linked to the achievement of a hematologic complete response (HCR). We conducted a prospective trial to determine whether a second cycle of HDM/SCT could induce HCR in patients in whom the plasma cell dyscrasia persisted following initial treatment with HDM/SCT. Sixty-two patients were enrolled. Nine patients (15%) were removed from the protocol. Of the 53 patients continuing in this study, four died within 100 days of treatment (8%), and 27 (55%) achieved an HCR at 6 months after the first cycle of HDM/SCT. Of the 22 patients who did not achieve an HCR after initial treatment, 17 received a second HDM/SCT, 1 died within 100 days of treatment (6%), while 5 (31%) achieved an HCR. Thus, the HCR rate was 67% (32/48) for surviving patients on study, 60% (32/53) for all patients who received initial cycle of HDM/SCT, and 56% (35/62) by intention-to-treat. The median survival for all patients enrolled on the trial has not yet been reached. Thus, tandem cycles of HDM/SCT can increase the proportion of patients who achieve an HCR.

Quality improvement to decrease specimen mislabeling in transfusion medicine.

CONTEXT Proper specimen identification and labeling is a critical preanalytic step in pretransfusion compatibility testing. OBJECTIVE To gather baseline data for specimen mislabeling, specifically targeting major mislabeling events, and to design and implement a plan of corrective action. DESIGN All mislabeled specimens received by the transfusion service for a type and screen were recorded and classified into minor and major mislabeling categories. Major mislabeling events were tracked by origin of the specimen. Locations with a high proportion of major mislabeling were given timely feedback (within 1 week) of the events as they arose. SETTING A university hospital. MAIN OUTCOME MEASURES The incidence of major mislabeling. RESULTS The incidence of mislabeling in the transfusion service was 0.5% (243/49 955) during 21 months of data collection. Of these mislabeling events, 47% were classified as major events (unlabeled, mismatched specimen/ requisition, ABO/Rh result on current specimen not matching historical record on file). The emergency department accounted for a high proportion of these major mislabeling events. After the intervention of providing weekly feedback to emergency department staff, their contribution to major mislabeling fell from 47% in 1 year (23/49) to 14% (4/29) in the subsequent 3 quarters. CONCLUSIONS Collecting and trending data on mislabeled samples with timely feedback to patient care areas can change phlebotomy practice and reduce specimen mislabeling.

Bortezomib and high dose melphalan conditioning for stem cell transplantation for AL amyloidosis: a pilot study

Treatment with high-dose intravenous melphalan followed by autologous stem cell transplantation (HDM/SCT) can induce hematologic responses, organ responses and lead to improvement in survival in selected patients with AL (immunoglobulin light chain) amyloidosis.[1][1] The depth of hematologic

Induction Therapy with Bortezomib Followed by Bortezomib-High Dose Melphalan and Stem Cell Transplantation for Light Chain Amyloidosis: Results of a Prospective Clinical Trial

The depth of hematologic response has been shown to correlate with survival and organ responses for patients with light chain (AL) amyloidosis. We conducted a prospective trial of 2 cycles of induction with bortezomib and dexamethasone on a twice a week schedule followed by conditioning with bortezomib and high-dose melphalan (HDM) and autologous stem cell transplantation (SCT). The objectives were hematologic responses, tolerability, and survival. Thirty-five patients were enrolled from 2010 to 2013. Of these, 30 proceeded with SCT, whereas 5 did not because of clinical deterioration during induction (n = 3) or complications after stem cell collection (n = 2). Two patients developed features of an autologous graft-versus-host disease-like syndrome post-SCT, which responded to steroids; no other unusual complications were seen. Treatment-related mortality occurred in 8.5% (3/35). Hematologic responses were achieved by 100% of the 27 assessable patients (63% complete response, 37% very good partial response [VGPR]) who completed the planned treatment. By intention-to-treat, hematologic responses occurred in 77% of patients (49% complete response, 29% VGPR). With a median follow-up of 36 months, the median overall survival and progression-free survival were not reached. In conclusion, incorporating bortezomib into induction and conditioning yielded a high rate of hematologic responses after HDM/SCT in patients with AL amyloidosis.

Long-term outcome of patients with AL amyloidosis treated with high-dose melphalan and stem cell transplantation: 20-year experience.

To the editor: In immunoglobulin light chain (AL) amyloidosis, amyloid fibril deposits, derived from immunoglobulin light chains produced by a clonal plasma cell dyscrasia, accumulate in extracellular tissues and damage vital organs.[1][1] High-dose melphalan and autologous stem cell

Predictive factors for hematopoietic engraftment after autologous peripheral blood stem cell transplantation for AL amyloidosis

Summary:Treatment of patients with AL amyloidosis with high-dose melphalan and autologous peripheral blood stem cells (PBSC) produces hematologic remissions in approximately 40% of evaluable patients, accompanied by improvements in organ disease and quality of life. These patients, who frequently have amyloid deposits in bone marrow blood vessels and interstitium and impaired function of kidneys, liver, spleen, and heart, represent an unusual population for stem cell transplantation, with unique problems. To identify factors influencing engraftment rates after chemotherapy and autologous granulocyte colony-stimulating factor (G-CSF)-mobilized PBSC reinfusion, we studied a group of 225 patients. The median time to neutrophil engraftment was 10 days (range, 8–17 days). In a multivariate analysis, the factors positively affecting the rate of neutrophil engraftment were CD34+ stem cell dose, female gender, and minimal prior alkylator therapy. The median time to platelet engraftment was 13 days (range, 7–52 days). Factors positively affecting platelet engraftment, in addition to CD34+ cell dose, included preserved renal function and the absence of neutropenic fever. The conditioning dose of intravenous melphalan was not found to be an independent predictive factor for hematopoietic recovery. Thus, in this patient population, organ function and host and hematopoietic factors influence engraftment after PBSC rescue.