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DARZALEX® (daratumumab)

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DARZALEX + DARZALEX FASPRO - Interaction with Serological Testing for Oncologists

Last Updated: 07/23/2024

Summary

  • Daratumumab binds to CD38 found at low levels on red blood cells (RBCs) and may result in a positive indirect Coombs test (indirect antiglobulin test; IAT). Daratumumab-mediated positive indirect Coombs test may persist for up to 6 months after the last daratumumab infusion. It should be recognized that daratumumab bound to RBCs may mask detection of antibodies to minor antigens in the patient’s serum. The determination of a patient’s ABO and Rh blood type are not impacted.1
    • Type and screen patients prior to starting daratumumab.1
    • In the event of a planned transfusion notify blood transfusion centers of this interference with IATs. If an emergency transfusion is required, non-cross-matched ABO/RhD-compatible RBCs can be given per local blood bank practices.1
  • Positive IATs in fresh-frozen plasma (FFP) samples and samples from multiple myeloma patients in which daratumumab has been introduced or administered, respectively, have been reported in the literature.1-3
  • Chapuy et al (2015)2 and Oostendorp et al (2015)3 reported daratumumab anti-idiotype antibodies and recombinant soluble CD38 (sCD38) blocked all daratumumab interference in the IAT of FFP + daratumumab samples and in plasma samples from multiple myeloma patients.
  • Chari et al (2017)4 conducted an analysis of RBC transfusions and transfusion-related adverse events (AEs) in the SIRIUS study. Seven patients at the authors’ institutions who had antibody screening after receiving DARZALEX demonstrated agglutination of all RBCs on panel testing.
  • Chapuy et al (2015)2 published findings that treating RBCs with dithiothreitol (DTT) effectively eliminates daratumumab interference in serologic testing. Treating RBCs with trypsin demonstrated less efficient elimination of interference by daratumumab.
  • Chapuy et al (2016)5 conducted a multicenter international study to validate the DTT method for use by blood banks worldwide. Using DTT-treated RBCs, 100% of blood bank laboratories sampled worldwide were able to identify a clinically significant antibody initially masked by the presence of daratumumab.
  • Additional citations are included in the References section for your information.6-22

PRODUCT LABELING

BACKGROUND

  • Daratumumab binds to CD38 found at low levels on RBCs and may result in a positive indirect Coombs test. Daratumumab-mediated positive indirect Coombs test may persist for up to 6 months after the last daratumumab infusion. It should be recognized that daratumumab bound to RBCs may mask detection of antibodies to minor antigens in the patient’s serum. The determination of a patient’s ABO and Rh blood type are not impacted.1

Typical Positive Indirect Coombs Test4

Typical Negative Indirect Coombs Test4

Typical Indirect Coombs Test from a Patient Treated with Daratumumab4

CLINICAL STUDIES

Daratumumab Interference with Blood Compatibility Testing

Chapuy et al (2015)2 published similar findings from the same phase 1 and 2 studies at their single center (Dana Farber Cancer Institute). In total, investigators observed positive antibody screens in 5 of 5 patients who received daratumumab after routine serological testing. Results from treating RBCs with DTT as a method for blocking daratumumab IAT interference are summarized.

Study Design/Methods

  • Normal plasma samples were supplemented with daratumumab 0.01, 0.1, 1.0, and 10.0 µg/mL.
  • The effectiveness of treating RBCs with DTT to eliminate daratumumab IAT interference was assessed.
  • Blocking daratumumab interference with daratumumab anti-idiotype antibody and soluble CD38 were also assessed.

Results

Observed Irregular Antibody Screening in the Phase 1 and 2 Study
  • Positive antibody screens were observed in 5 of 5 patients treated with daratumumab who underwent routine screening in the blood bank. In total 18 samples were collected, and all demonstrated positive results.
Failure of Adsorption to Eliminate Interference
  • Panreactivity was observed at all daratumumab concentrations and could not be removed even after 6 cycles of heterologous adsorption.
Blocking Daratumumab Interference with DTT-Treated RBCs
  • Following incubation of HL60 cells transduced with human CD38 (HL60-CD38) with 10 mmol/L DTT, daratumumab binding on the cell surface was reduced by 92% (P<0.001). Treating HL60-CD38 cells with 2% trypsin reduced daratumumab binding by 40% (P<0.001).
  • In plasma samples with daratumumab 1.0 µg/mL, treating reagent RBCs with DTT and trypsin each resulted in elimination of panreactivity.

False-Positive Indirect Antiglobulin Tests Post DARZALEX Treatment

Oostendorp et al (2015)3 published findings from a phase 1 and 2 safety and dose-escalation study in which 11 multiple myeloma patients at their single center received DARZALEX 8 to 16 mg/kg intravenous infusions on weeks 1, 4, and then weekly until week 8. Peak daratumumab serum concentrations exceeded 100 µg/mL for all patients (range 110-438 µg/mL). The investigators observed that all patients who received DARZALEX demonstrated false-positive IATs for 2 to 6 months after the last DARZALEX infusions.

In-Vitro Study Design/Methods

  • The ability of daratumumab to produce red blood cell agglutination was assessed using FFP samples supplemented with daratumumab 0.01, 0.1, 1.0, and 10.0 µg/mL.
  • Analyses were conducted with FPP + daratumumab 10.0 µg/mL samples in which daratumumab anti-idiotype antibody or sCD38 were introduced to assess these approaches as potential solutions for blocking daratumumab interference.

Results

Observed Irregular Antibody Screening in the Phase 1 and 2 Study
  • Plasma from all patients demonstrated negative IATs and direct antiglobulin tests (DATs) prior to DARZALEX administration.
  • After DARZALEX administration, positive IAT results were observed for 11 patient samples tested and the IAT autocontrol was negative for all patients.
  • The positive IAT results persisted for 2-6 months after the last DARZALEX treatment in 8 patients.
  • DAT results were negative (indicating a lack of immunoglobulin G [IgGs] bound to the RBCs) for all patients tested.
Irregular Antibody Screening In-vitro
  • Daratumumab induced RBC agglutination in a dose-dependent manner in a 3-cell RBC panel and in RBCs from untreated multiple myeloma patients.
Blocking daratumumab interference with daratumumab Anti-Idiotype Antibodies
  • Daratumumab anti-idiotype antibodies at 5- and 10-fold excess concentrations blocked all daratumumab interference in the IAT of FFP + daratumumab samples and in plasma samples from multiple myeloma patients.
  • Addition of sCD38 also blocked daratumumab interference in the IAT.

Analysis of RBC Transfusions and Transfusion-Related Adverse Events in the SIRIUS Study

Chari et al (2017)4 conducted an analysis of RBC transfusions and transfusion-related AEs in the SIRIUS study.

Study Design/Methods

  • SIRIUS was a phase 2, open-label, international, multicenter study.
  • Patients in the study had multiple myeloma and received ≥3 prior lines of therapy, including a proteasome inhibitor and an immunomodulatory drug, or had disease which was refractory to both a proteasome inhibitor and an immunomodulatory drug.
  • In part 1 of the study, patients were randomized 1:1 to receive:
    • DARZALEX 16 mg/kg every week for 8 weeks, DARZALEX 16 mg/kg every 2 weeks for 16 weeks, then DARZALEX 16 mg/kg every 4 weeks thereafter (n=16), or,
    • DARZALEX 8 mg/kg every 4 weeks (n=18)
  • Response was evaluated and the DARZALEX 16 mg/kg dose was established as the recommended dose for further evaluation in part 2 of the study. An additional 90 patients were enrolled in the DARZALEX 16 mg/kg group.
  • Patients were RBC phenotyped by tube methodology prior to receiving their first dose of DARZALEX.
  • If the patient’s antibody screen was positive, antibody identification was performed using a panel of reagent RBCs.
  • Antibody screens and RBC panels were performed using gel cards.
  • If panagglutination reactions were detected on gel cards, additional testing was conducted using LISS.

Results

Transfusions in the Overall Study Population
  • As of a clinical cut-off date of January 9, 2015, 49 of 124 (39.5%) patients received 236 transfusions.
    • A total of 47 (37.9%) patients received 147 packed red blood cell transfusions.
    • A total of 17 (13.7%) patients received 89 platelet transfusions.
    • No patient received a whole blood or fresh frozen plasma transfusion.
  • Hemolysis was not reported.
  • One transfusion-related reaction was observed following platelet transfusion.
Transfusion Experience at Clinical Study Sites
  • The experience of 15 patients was described (n=8 from Mount Sinai, n=7 from the Levine Cancer Institute).
    • At Mount Sinai, no transfusion AEs were observed, no new unexpected RBC alloantibodies were identified, and transfusions increased hemoglobin values (median, 1.2 g/dL).
    • At the Levine Cancer Institute, 6 of 7 patients responded to transfusions, with a median hemoglobin change of 1.7 g/dL.
  • Blood typing of patients from Mount Sinai is described in Table: Blood Typing of Mount Sinai Patients.
  • Patient blood transfusions from both Mount Sinai and the Levine Cancer Institute are described in Table: Blood Transfusions.

Blood Typing of Mount Sinai Patients4
Patient No.
DARA Dose, mg/kg
RBC Antigen Antibody Before DARA
Strength of Panhemagglutinin After DARA
Comments
1
16
-
2+ (gel), 1+ (LISS)
AC negative, not enhanced by ficin
2
16
-
2+ (gel), 1+ (LISS)
AC 1+ (gel), AC- (LISS), DAT IgG 1+, eluate- (gel)
3
16
Anti-D and anti-E
1-2+ (gel), no reaction (LISS)
AC negative
4
16
-
1+ (gel), 0-1 (LISS)
AC negative
5
16
Anti-E, anti-K, anti-Jkb, anti-Fya, anti-Fyb, anti-S, and anti-Knops
2+ (gel), 1+ (LISS)
AC negative
6
16
N/A
N/A
N/A
7
16
-
2-3+ (gel), 1+ (LISS)
AC negative, negative at immediate spin and 37 degrees
8
16
-
1+ (gel)
AC negative
Abbreviations: AC, autocontrol; DARA, DARZALEX; DAT, direct antiglobulin test; IgG, immunoglobulin G; LISS, low ionic strength saline; N/A, not available; No., number; RBC, red blood cell.

Blood Transfusions4
Patient No.
DARA Dose, mg/kg
Pretransfusion Hb, g/dL
Posttransfusion Hb, g/dL
Mount Sinai
1
16
8.5
9.8
2
16
7.2
8.4
6.9
8.1
7.1
8.3
4
16
8.0
9.8
5
16
7.4
7.9
7.1
7.9
7
16
6.2
9.2
Levine Cancer Institute
9
8
8.0
7.7
8.0
7.7
7.7
8.4
10
16
7.9
10.9
8.9
10.6
9.8
11.5
8.7
11.3
11
8
8.5
11.1
8.1
9.8
8.4
10.7
12
16
7.0
9.2
8.3
8.9
13
16
8.4
10.8
8.2
9.5
14
16
8.4
9.4
7.9
10.3
8.5
9.6
8.5
9.6
7.7
10.2
15
16
7.9
9.7
Abbreviations: DARA, DARZALEX; Hb, hemoglobin; No., number.

Dithiothreitol-Based Method to Resolve the Daratumumab Interference with Blood Compatibility Testing

Chapuy et al (2016)5 conducted a multicenter international study to validate the DTT method for use by blood banks worldwide.

Study Design/Methods

  • Blood banks received 2 unknown plasma samples:
    • Sample 1 was spiked with daratumumab alone (10 mcg/mL).
    • Sample 2 was spiked with daratumumab plus a clinically significant antibody (anti-D, anti-Fya, or anti-s).
  • Sites were instructed to perform an antibody screen using their usual method (tube, gel, or solid phase), then to repeat the antibody screen using DTT-treated RBCs (gel or tube).
    • If the antibody screen remained positive with DTT-treated RBCs (sample 2), sites were asked to identify the unknown antibody using a DTT-treated RBC panel (gel or tube).
  • The primary outcome was the proportion of study sites able to identify the unknown antibody in the presence of daratumumab.

Results

  • Paired plasma sample unknowns were shipped to 25 study sites in North America, South America, Europe, Asia, and Australia/New Zealand.
  • For the initial antibody screen (sample 1), 10 sites used tube testing, 9 sites used gel, and 6 sites used solid phase.
  • All sites observed daratumumab interference with the antibody screen and at 24 of 25 sites (96%), DTT treatment of screening cells eliminated the positive reactions seen with sample 1.
  • All sites were able to correctly identify the unknown antibody using the DTT method: anti-Fya (9 sites), anti-s (10 sites), and anti-D (6 sites).
  • Ninety percent of sites (17/19) reported that they planned to use the DTT method to manage clinical samples from daratumumab-treated patients in the future.

LITERATURE SEARCH

A literature search of MEDLINE®, Embase®, BIOSIS Previews®, and Derwent Drug File databases (and/or other resources, including internal/external databases) was conducted on 22 July 2024.

 

References

Show
1 Data on File. Daratumumab Intravenous Formulation CCDS. Janssen Research & Development, LLC. EDMS-ERI-78724630; 2024.  
2 Chapuy CI, Nicholson RT, Aguad MD, et al. Resolving the daratumumab interference with blood compatibility testing. Transfusion. 2015;55(6pt2):1545-1554.  
3 Oostendorp M, Bueren JL van, Doshi P, et al. When blood transfusion medicine becomes complicated due to interference by monoclonal antibody therapy. Transfusion. 2015;55:1555-1562.  
4 Chari A, Arinsburg S, Jagannath S, et al. Blood transfusion management and transfusion-related outcomes in daratumumab-treated patients with relapsed or refractory multiple myeloma. Clin Lymphoma Myeloma Leuk. 2018;18:44-51.  
5 Chapuy C, Aguad M, Nicholson R, et al. International validation of a dithiothreitol (DTT)-based method to resolve the daratumumab interference with blood compatibility testing. Transfusion. 2016;56:2964-2972.  
6 Lintel N, Brown D, Schafer D, et al. Use of standard laboratory methods to obviate routine dithiothreitol treatment of blood samples with daratumumab interference. Immunohematology. 2017;33:22-26.  
7 Deneys V, Thiry C, Frelik A, et al. Daratumumab: therapeutic asset, biological trap! Transfus Clin Biol. 2018;25:2-7.  
8 Bub C, Reis I, Aravechia M, et al. Transfusion management for patients taking an anti-CD38 monoclonal antibody. Hematol Transfus Cell Ther. 2018;40:25-29.  
9 E Werle, J Ziebart, E Wasmund, et al. Daratumumab interference in pretransfusion testing is overcome by addition of daratumumab fab fragments to patients’ plasma. Transfus Med Hemotherapy. 2019;46(6):423-430.  
10 EC Izaguirre, M Del Mar Luis-Hidalgo, LL González, et al. New method for overcoming the interference produced by anti-CD38 monoclonal antibodies in compatibility testing [in eng]. Blood transfusion = Trasfusione del sangue. 2020;18(4):290-294.  
11 Zhou Y, Chen L, Jiang T, et al. 2-Mercaptoethanol (2-ME)-based IATs or Polybrene method mitigates the interference of daratumumab on blood compatibility tests. Hematol. 2021;26:365-370.  
12 Perram J, Blayney B, Ackerman L, et al. Solid phase antibody screening in the presence of anti-CD38 monoclonal antibodies: a potential alternative to avoid interference. Pathology. 2020;52:492-494.  
13 Tremblay T, Branch D, Loubaki L. Daudi cell stroma: An alternative to dithiothreitol to resolve daratumumab interference in pretransfusion testing. Transfusion. 2020;60:2090-2096.  
14 Aung F, Spencer J, Potter D. Efficient neutralization of daratumumab in pretransfusion samples using a novel recombinant monoclonal anti-idiotype antibody. Transfusion. 2022;62:1511-1518.  
15 Ibeh N, Baine I, Rudon L. Use of an in-house trypsin-based method to resolve the interference of daratumumab. Transfusion. 2021;61:3000-3007.  
16 Feng CC, Chang CW, Lien ZY, et al. Better resolving of anti-CD38 antibody interference with blood compatibility testing by using manual polybrene method compared with dithiothreitol-pretreatment indirect antiglobulin test. Journal of Clinical Laboratory Analysis. 2023;37:e24891.  
17 Habicht C, Ridders M, Grueger D, et al. Mitigation of therapeutic anti-CD38 antibody interference with fab fragments: How well does it perform? Transfusion. 2023;63:808-816.  
18 Habicht C, Adolph S, Schneeweiss B. Antigen masking indirect antiglobulin test: a new reagent with improved protocols. Abstract presented at: Jahrestagung der Deutschen Gesellschaft fur Transfusionsmedizin und Immunhamatologie e V (DGTI); September 21-23, 2022; Mannheim, Germany.  
19 Wottge A, Bartolmas T, Mayer B. Comparison of different methods to optimize immunohematological diagnostics in case of interference due to monoclonal antibodies against CD38. Abstract presented at: Jahrestagung der Deutschen Gesellschaft fur Transfusionsmedizin und Immunhamatologie e V (DGTI); September 21-23, 2022; Mannheim, Germany.  
20 Feldman A, Duek A, Mandel-Benado M, et al. Effective neutralization of daratumumab effects on pre-transfusion testing: a method modification. Clin Lab. 2022;68:1977-1981.  
21 Lockhart A, Easterbrook J, Wilson I, et al. Daratumumab interference with blood-compatibility testing after autologous stem cell transplantation. Transfus Med. 2023;no pagination.  
22 Zemaite E, Urbonaitė D, Urbonienė D, et al. Treating red blood cells with dithiothreitol can help eliminate daratumumab interference in blood compatibility tests (pretransfusion testing). Clin Chim Acta. 2024;558(Supplement 1):no pagination.