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In phase 1 of CC-92480- MM- 001 (NCT03374085), the recommended phase 2 dose (RP2D) of mezigdomide plus dexamethasone (MEZI-d) was selected at 1 mg once daily for 21/28 days. Here we report preliminary results from the MEZI-d dose-expansion cohort in patients with heavily pretreated RRMM. Key eligibility criteria were: RRMM;>=3 prior lines of therapy;disease progression <=60 days of last myeloma therapy;refractoriness to lenalidomide/pomalidomide, a proteasome inhibitor, a glucocorticoid, and an anti-CD38 monoclonal antibody. Oral mezigdomide 1 mg was given on days 1-21 of each 28-day cycle, plus weekly dexamethasone (40 mg;20 mg if >75 years of age). Primary objective was to evaluate efficacy (overall response rate [ORR]);secondary objectives included safety/tolerability and additional efficacy assessments. Pharmacodynamics was an exploratory objective. As of 16/Sep/2022, 101 patients had received MEZI-d at the RP2D. Median age was 67 (range 42-85) years, median time since initial diagnosis was 7.4 (1.1-37.0) years;39.6% of patients had plasmacytomas and 37/101 patients had high-risk cytogenetics (56/101 not evaluable). Median number of prior regimens was 6 (3-15);prior therapies included stem cell transplantation (77.2%) and anti-BCMA therapy (29.7%). All patients were refractory to last myeloma regimen and triple-class refractory. Median follow-up was 7.5 (0.5-21.9) months, with a median of 4 (1-20) cycles;10.0% of patients continued treatment;progressive disease was the main reason for discontinuation (60.4%). ORR was 40.6% for all patients. Whilst data are not mature yet, median PFS was 4.4 (95% CI 3.0-5.5) months and median duration of response was 7.6 (95% CI 5.4-9.5) months. ORR was 30.0% in patients with plasmacytomas (N = 40) and 50.0% in patients with prior anti-BCMA therapy (N = 30). Ninety-one (91.1%) patients experienced a grade 3/4 treatment-emergent adverse event (TEAE). Most frequent hematologic grade 3/4 TEAEs were neutropenia (75.2%), anaemia (35.6%), and thrombocytopenia (27.7%);34.7% of patients had grade 3/4 infections, including grade 3/4 pneumonia (15.8%) and COVID-19 (7.0%). Occurrence of other grade 3/4 non-hematologic TEAEs was generally low. Due to TEAEs, 76.2% and 29.7% of patients had mezigdomide dose interruptions and reductions, respectively;90.1% of patients discontinued mezigdomide. Mezigdomide induced substrate degradation and increases in activated and proliferating T cells in patients, including those directly refractory to pomalidomide-based therapies. MEZI-d had a manageable safety profile with encouraging efficacy in patients with triple-class refractory RRMM, including patients with prior BCMA-targeted therapies. These results strongly support the continued development of mezigdomide in MM, and especially in combination.
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Background: B-cell lymphoma-2 (Bcl-2) proteins play an important role in multiple myeloma (MM) cell survival and represent an attractive therapeutic target. In prior trials, a subgroup analysis of patients with t(11;14)-positive relapsed/refractory (R/R) MM showed the combination of a Bcl-2 inhibitor, a proteasome inhibitor, and dexamethasone improved progression-free survival with no increased mortality. BGB-11417, a Bcl-2 inhibitor, is more potent and selective than venetoclax. BGB-11417- 105 (NCT04973605) is a phase 1b/2 study assessing the safety and efficacy of BGB-11417 monotherapy, in combination with dexamethasone, or with dexamethasone+carfilzomib in patients with t(11;14)-positive R/R MM. Preliminary safety results for the combination of BGB-11417 + dexamethasone are presented. Method(s): Eligible patients had t(11;14)-positive R/R MM and had been exposed to a proteasome inhibitor, immunomodulatory agent, and anti-CD38 therapy. Patients received 80-, 160-, 320-, or 640-mg BGB-11417 daily with 40-mg dexamethasone weekly until death, intolerability, or disease progression. Dose escalation was guided by a mTPI-2 design and overall review by a safety monitoring committee. Pharmacokinetics (PK) were also assessed. Result(s): As of 1 July 2022, 10 patients were enrolled in the 80-, 160-, and 320-mg (3 patients each) and 640-mg (1 patient) dose-escalation cohorts of BGB-11417 + dexamethasone. The median age was 69 years (range, 52-81) and median prior lines of therapy was 3 (range, 1-5). The median treatment duration was 3.2 months (range, 0.5-6.5). No patients experienced dose-limiting toxicity at any dose level. Three patients died whilst on study: 1 due to COVID-19 complications 157 days after treatment discontinuation (day 208), 1 due to progressive disease 50 days after treatment discontinuation (day 89), and 1 due to COVID-19 whilst on study treatment (day 78). No deaths were associated with study treatment. Two patients experienced Grade >= 3 treatment-emergent adverse events (TEAEs). One patient in the 160-mg cohort experienced Grade 3 increase in liver enzymes and lymphopenia. One patient in the 320-mg cohort experienced Grade 3 lymphopenia. The most common TEAEs were insomnia (50%), fatigue (30%), arthralgia (20%), back pain (20%), lymphopenia (20%), and nausea (20%). BGB-11417 exposure increased dose-dependently from 80 mg to 320 mg with high interpatient PK variability. BGB-11417 exposures after single and multiple doses appeared similar, indicating limited accumulation. Conclusion(s): BGB-11417 plus dexamethasone was generally well-tolerated in patients with R/R MM harbouring t(11;14) at doses <=640 mg. Efficacy data are forthcoming. Recruitment is ongoing in the US, Australia, and New Zealand;the BGB-11417, dexamethasone, and carfilzomib combination arm will open in the future.
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It is known that viral infections induce DNA damage by different mechanisms and cause genomic instability. DNA damage that is not properly repaired contributes to pathological mechanisms associated with various diseases such as cancer, type 2 diabetes (T2D), neurodegenerative disorders as well aging. There are findings supporting that coronaviruses cause DNA damage, genomic instability, and cell cycle dysregulation in the host cells while replicating their genomes. Increased DNA damage and aberrant DNA repair are shown in cancer, diabetes, neurodegenerative disorders, and cardiovascular diseases. As for coronavirus infection, if DNA damage cannot be repaired, it contributes to the amplification of viral infection-induced pathologies. The adaptive immune system is very important in fighting against SARS-COV-2, and clinical studies have shown that adaptive immunity is weakened and delayed in individuals with severe Coronavirus Disease 19 (COVID-19). In vitro studies revealed that the SARS-COV-2 spike protein, which is effective in adaptive immunity, significantly inhibits DNA damage repair. Prolonged COVID-19 is associated with colorectal cancer that is characterized by defects in DNA mismatch repair mechanisms. PARP1 is an enzyme that regulates cellular processes such as DNA repair, and gene transcription. PARP1 inhibitors are used effectively to treat acute lung injury in patients with COVID-19. In light of such preliminary data, it is concluded that a close interaction between DNA repair and the severity of Covid-19 may be available. Deficient DNA repair may contribute to life-threatening conditions in severe Covid -19, and may be one of the underlying mechanisms of long-term consequences of SARS-CoV-2 infection. In this chapter, the role of DNA repair in the acute and long-term pathological effects of COVID-19 was evaluated. © 2023 Nova Science Publishers, Inc. All rights reseverd.
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Introduction: CARTITUDE-2 (NCT04133636) is a phase 2, multicohort study evaluating cilta-cel, an anti-BCMA CAR-T therapy, in several multiple myeloma (MM) patient (pt) populations. Objective(s): To report updated results with longer follow-up on cohort C pts with previous exposure to a non-cellular anti- BCMA immunotherapy. Method(s): Cohort C pts had progressive MM after treatment (tx) with a proteasome inhibitor, immunomodulatory drug, anti-CD38 antibody, and non-cellular BCMA-targeting agent. A single cilta-cel infusion (target dose 0.75x106 CAR+ viable T cells/kg) was administered 5-7 days post lymphodepletion. Primary endpoint was minimal residual disease (MRD) negativity at 10-5. Secondary endpoints included overall response rate (ORR), duration of response (DOR), and adverse events (AEs). Result(s): As of June 1, 2022, 20 pts (13 ADC exposed;7 BsAb exposed) were treated with cilta-cel;4 pts did not receive cilta-cel due to either low cellular yield (n=2, 1 in each group) or death due to progressive disease (PD) prior to dosing (n=2, 1 in each group) and 6 pts received anti-BCMA tx as their last line of therapy (n=4 ADC, n=2 BsAb). During prior anti-BCMA tx, best responses included VGPR (ADC: 2 pts;BsAb: 1 pt), sCR (ADC: 1 pt), and CR (BsAb: 1 pt);the rest had best response of stable disease or PD (1 pt not evaluable). Baseline characteristics are presented in Figure 1A. Median time from last anti- BCMA agent to cilta-cel infusion was 195 d;median administered dose of cilta-cel was 0.65x106 CAR+ viable T cells/kg. At a median follow-up of 18.0 mo, 7/10 evaluable pts (70%) were MRD negative at 10-5 (ADC: 5/7 [71.4%], BsAb: 2/3 [66.7%]). ORR: full cohort, 60%;ADC, 61.5%;BsAb, 57.1% (Figure 1B). Median DOR: full cohort, 12.8 mo;ADC, 12.8 mo;BsAb, 8.2 mo. Median PFS: full cohort, 9.1 mo;ADC, 9.5 mo;BsAb, 5.3 mo. Cilta-cel responders had a shorter median duration of last anti- BCMA agent exposure (29.5 d) compared with non-responders (63.5 d). Responders also had a longer median time from last anti-BCMA tx exposure to apheresis (161.0 d) than non-responders (56.5 d). Most common AEs were hematologic. CRS: n=12 (60%;all Gr1/2), median time to onset 7.5 d, median duration 6.0 d. ICANS: n=4 (20%, 2 Gr3/4), median time to onset 9.0 d, median duration 7.0 d. No patient had movement or neurocognitive tx emergent AE/parkinsonism. There were 12 deaths (PD: 8;COVID-19 pneumonia: 2 [not tx related];subarachnoid hemorrhage: 1 [not tx related];C. difficile colitis: 1 [tx related]). (Figure Presented)(Figure Presented)Conclusions: Pts with heavily pretreated MM and previous exposure to a non-cellular anti-BCMA therapy had favorable responses to cilta-cel. However, depth and DOR appear lower than that seen in anti-BCMA-naive pts treated with cilta-cel (at 27.7 mo, median DOR was not reached in heavily pre-treated but anti-BCMA naive CARTITUDE-1 pts). These data may inform tx plans, including sequencing and washout period between BCMA-targeting agentsCopyright © 2023 American Society for Transplantation and Cellular Therapy
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Background: Secondary lymphoid organs provide the adequate microenvironment for the development of antigen (Ag)-specific immune responses. The tight collaboration between CD4+ T cells and B cells in germinal centers is crucial to shape B cell fate and optimize antibody maturation. Dissecting these immune interactions remains challenging in humans, and animal models do not always recapitulate human physiology. To address this issue, we developed an in vitro 3D model of a human lymphoid organ. The model relies on a microfluidic device, enabling primary human cells to self-organize in an extracellular matrix (ECM) under continuous fluid perfusion. We applied this Lymphoid Organ-Chip (LO chip) system to the analysis of B cell recall responses to SARS-CoV-2 antigens. Method(s): We used a two-channel microfluidic Chip S1 from Emulate, where the top channel is perfused with antigen (spike protein or SARS-CoV-2 mRNA vaccine), while the bottom channel contains PBMC (n = 14 independent donors) seeded at high-density in a collagen-based ECM. Immune cell division and cluster formation were monitored by confocal imaging, plasmablast differentiation and spike-specific B cell amplification by flow cytometry, antibody secretion by a cell-based binding assay (S-flow). Result(s): Chip perfusion with the SARS-CoV-2 spike protein for 6 days resulted in the induction CD38hiCD27hi plasmablast maturation compared to an irrelevant BSA protein (P< 0.0001). Using fluorescent spike as a probe, we observed a strong amplification of spike-specific B cell (from 3.7 to 140-fold increase). In line with this rapid memory B cell response, spike-specific antibodies production could be detected as early as day 6 of culture. Spike perfusion also induced CD4+ T cell activation (CD38+ ICOS+), which correlated with the level of B cell maturation. The magnitude of specific B cell amplification in the LO chip was higher than in 2D and 3D static cultures at day 6, showing the added value of 3D perfused culture for the induction of recall responses. Interestingly, the perfusion of mRNA-based SARS-CoV-2 vaccines also led to strong B cell maturation and specific B cell amplification, indicating that mRNA-derived spike could be expressed and efficiently presented in the LO chip. Conclusion(s): We developed a versatile Lymphoid Organ-Chip model suitable for the rapid evaluation of B cell recall responses. The model is responsive to protein and mRNA-encoded antigens, highlighting its potential in the evaluation of SARS-CoV-2 vaccine boosting strategies.
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Acute lung injury (ALI) is a clinically severe lung illness with high incidence rate and mortality. Especially, coronavirus disease 2019 (COVID-19) poses a serious threat to world wide governmental fitness. It has distributed to almost from corner to corner of the universe, and the situation in the prevention and control of COVID-19 remains grave. Traditional Chinese medicine plays a vital role in the precaution and therapy of sicknesses. At present, there is a lack of drugs for treating these diseases, so it is necessary to develop drugs for treating COVID-19 related ALI. Fagopyrum dibotrys (D. Don) Hara is an annual plant of the Polygonaceae family and one of the long-history used traditional medicine in China. In recent years, its rhizomes (medicinal parts) have attracted the attention of scholars at home and abroad due to their significant anti-inflammatory, antibacterial and anticancer activities. It can work on SARS-COV-2 with numerous components, targets, and pathways, and has a certain effect on coronavirus disease 2019 (COVID-19) related acute lung injury (ALI). However, there are few systematic studies on its aerial parts (including stems and leaves) and its potential therapeutic mechanism has not been studied. The phytochemical constituents of rhizome of F. dibotrys were collected using TCMSP database. And metabolites of F. dibotrys' s aerial parts were detected by metabonomics. The phytochemical targets of F. dibotrys were predicted by the PharmMapper website tool. COVID-19 and ALI-related genes were retrieved from GeneCards. Cross targets and active phytochemicals of COVID-19 and ALI related genes in F. dibotrys were enriched by gene ontology (GO) and KEGG by metscape bioinformatics tools. The interplay network entre active phytochemicals and anti COVID-19 and ALI targets was established and broke down using Cytoscape software. Discovery Studio (version 2019) was used to perform molecular docking of crux active plant chemicals with anti COVID-19 and ALI targets. We identified 1136 chemicals from the aerial parts of F. dibotrys, among which 47 were active flavonoids and phenolic chemicals. A total of 61 chemicals were searched from the rhizome of F. dibotrys, and 15 of them were active chemicals. So there are 6 commonly key active chemicals at the aerial parts and the rhizome of F. dibotrys, 89 these phytochemicals's potential targets, and 211 COVID-19 and ALI related genes. GO enrichment bespoken that F. dibotrys might be involved in influencing gene targets contained numerous biological processes, for instance, negative regulation of megakaryocyte differentiation, regulation of DNA metabolic process, which could be put down to its anti COVID-19 associated ALI effects. KEGG pathway indicated that viral carcinogenesis, spliceosome, salmonella infection, coronavirus disease - COVID-19, legionellosis and human immunodeficiency virus 1 infection pathway are the primary pathways obsessed in the anti COVID-19 associated ALI effects of F. dibotrys. Molecular docking confirmed that the 6 critical active phytochemicals of F. dibotrys, such as luteolin, (+) -epicatechin, quercetin, isorhamnetin, (+) -catechin, and (-) -catechin gallate, can combine with kernel therapeutic targets NEDD8, SRPK1, DCUN1D1, and PARP1. In vitro activity experiments showed that the total antioxidant capacity of the aerial parts and rhizomes of F. dibotrys increased with the increase of concentration in a certain range. In addition, as a whole, the antioxidant capacity of the aerial part of F. dibotrys was stronger than that of the rhizome. Our research afford cues for farther exploration of the anti COVID-19 associated ALI chemical compositions and mechanisms of F. dibotrys and afford scientific foundation for progressing modern anti COVID-19 associated ALI drugs based on phytochemicals in F. dibotrys. We also fully developed the medicinal value of F. dibotrys' s aerial parts, which can effectively avoid the waste of resources. Meanwhile, our work provides a new strategy for integrating metabonomics, network pharmacology, and molecular docking techniques which was an efficient way for recognizing effective constituents and mechanisms valid to the pharmacologic actions of traditional Chinese medicine.
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Objetivo: Descrever um caso com duas neoplasias concomitantes infiltrando medula ossea (MO), sendo uma delas hematologica e outra, TS. Material e metodos: Relato de caso por meio de coleta de dados de prontuario de paciente acompanhado no HAC. Resultados: Paciente 67 anos, masculino, tabagista (100 anos/maco), ex-etilista, historia de inalacao de tintas com benzeno (pintor de carros por 30 anos), com astenia e anemia ha 4 meses, associado a perda de 25kg. Procurou atendimento em marco/22 com diagnostico de COVID-19 e necessidade de internacao hospitalar. Evoluiu com bicitopenia sendo transferido ao HAC para investigacao. Ao exame fisico: ECOG 3. Hemograma: bicitopenia (Hb 5.8 mg/dL;plaquetas 40000/mm3;leucocitos 13000/mm3;69% blastos). TC: derrame pleural a direita;raros micronodulos pulmonares;enfisema pulmonar difuso acentuado com areas de fibrose associadas;linfonodomegalias mediastinais e hilares, lesoes osteoliticas esparsas. Mielograma: dispoese das tres linhagens, com 24% de celulas blasticas, alem de grumos de celulas nao-hematologicas (TS). Em Citometria de Fluxo (Euroflow): 16% de mieloblastos patologicos, expressando CD7, CD13, CD33, CD34, CD38, CD44, CD71, CD97, CD123. Citogenetica: 47,XY,+8. Nao foi realizada avaliacao molecular. Biopsia de MO: infiltracao macica da medula ossea por tumor solido. Imunohistoquimica com positividade para: CK7 e TTF-1 e negatividade para: CK20, PSA, PAX-8, CD10, CDX-2, GATA-3. Diagnostico final: infiltracao da MO por adenocarcinoma, favorecido sitio pulmonar, e em area residual, infiltracao por Leucemia mieloide aguda, com alteracao citogenetica associada a mielodisplasia (ELN 2022). Como tratava-se de idoso fragil, sem possibilidade de tratamento intensivo das doencas leucemica e oncologica, proposto tratamento paliativo exclusivo, com medidas de suporte. Paciente faleceu apos 2 meses do diagnostico. Discussao: A associacao de LMA com TS nao e rara. O risco de um paciente previamente tratado para TS desenvolver LMA pode ser ate 10 vezes maior que a populacao normal. Relatos de casos de TS recidivados em MO e LMA concomitantes foram descritos, com desfechos sombrios. Contudo, nao ha na literatura a descricao de LMA de novo com TS infiltrando MO concomitantes ao diagnostico. Estudo chines de 2020, analisou 12 casos de LMA associada a TS primario sincronicos, sendo: 3 etiologia pulmonar, 1 mama, 1 mola, e 7 com neoplasia de TGI. O intervalo de tempo mediano para o diagnostico das duas neoplasias foi de 4 meses. O tratamento da LMA foi realizado com quimioterapia (QT) de alta intensidade ou agente hipometilante. A sobrevida global mediana foi de 12.5 meses (porem somente 4/12 tinham TS avancado). Um estudo americano em 2009 analisou 5 pacientes com LMA e tumor de pulmao (2 com doenca avancada) sincronicos. Todos foram tratados com QT de alta intensidade, e a sobrevida media foi de 5 meses (3-21). Conclusao: Este e o primeiro relato de caso de LMA e TS metastatico infiltrando MO concomitantemente ao diagnostico. A LMA deve ser tratada prioritariamente por ser doenca altamente agressiva, levando-se em conta as condicoes clinicas do paciente, com avaliacao individual. E mesmo com tratamento intensivo, o prognostico e reservado. Copyright © 2022
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Coronavirus Disease-2019 (COVID-19) is a highly contagious disease caused by Severe Acute Respiratory Syndrome-Coronavirus-2 (SARS-CoV-2). The World Health Organization (WHO) classified the disease a as global public health hazard on 11 March 2020. Currently, there are no adequate measures to combat viral infections, including COVID-19, and the medication guidelines for the management of COVID-19 are dependent on previous findings from SARS-CoV and MERS-CoV research. Natural products have achieved widespread acceptance around the world as a means of enhancing healthcare and disease prevention. Plants are a potential source of antiviral factors such as flavonoids, phenolic acids, terpenoids, and others. Some of these agents exhibit a broad spectrum of antiviral activity. This study aimed to screen herbal leads for possible inhibitors of the SARS-CoV-2 ADP Ribose Phosphatase enzyme (ARP). Guggulsterone was found to be highly stabilized within the active site of the viral ARP enzyme by molecular dynamic simulation with very little fluctuation throughout the simulation timeframe of 100 ns. Thus, guggulsterone can be further used to develop a safe and competent medication for evolving therapy against SARS-CoV-2 in post-preclinical and clinical trials.
Subject(s)
COVID-19 , Middle East Respiratory Syndrome Coronavirus , Humans , SARS-CoV-2 , Adenosine Diphosphate Ribose , Phosphoric Monoester Hydrolases , Antiviral Agents/chemistryABSTRACT
Background: 30-50% of pediatric acute liver failure (PALF) is of unknown cause, or indeterminate PALF (iPALF), which frequently results in transplantation. A subset of iPALF is characterized by T-cell activation. Some children with acute severe hepatitis of unknown etiology (SH-u) can evolve to iPALF. Hemophagocytic Lymphohistiocytosis (HLH) is a well-defined hyper-inflammatory condition characterized by marked T-cell activation and frequent severe liver involvement. We postulated SH-u evolving to iPALF has hyper-inflammatory immune signatures that are identifiable before fulfilling PALF criteria, and might overlap with those seen in HLH. We compared the immune dysregulation signatures of children with HLH to children with SH-u, PALF cases with known etiologies, and healthy pediatric controls (HC). Method(s): Between 2019-2021, we prospectively enrolled 14 patients hospitalized with SH-u and 7 patients with PALF of known etiologies. Age dependent standard of care diagnostic studies were performed. SH-u was defined as ALT> 500, INR < 2, and no hepatic encephalopathy. HLH enrollees fulfilled the 2004 diagnostic criteria. High dimension T-cell immunophenotyping, cytokine and chemokine profiling (71-plex) was done for SH-u, HLH (n=5), and HC (n= 16) peripheral blood samples. T cell activation was prospectively identified by co-expression of surface activation markers HLA-DR and CD38. Based on immune studies in HC, CD8 effector memory (EM) activation of >9% distinguished patients with significant T cell activation from HC. This cutoff of >9% was therefore used to identify SH-u patients with T cell activation. Normally distributed data were compared by either a two-tailed t-test or an ordinary One-Way Anova test with Turkey's multiple comparison test. Non-normally distributed data were compared by either the Mann-Whitney test or Kruskal-Wallis test with Dunn's multiple comparisons test. P Values < 0.05 were deemed significant. Result(s): Subjects ranged in age from 4 days to 19 years old. There were no age or sex differences between the groups. One SH-u patient had prior COVID infection, but no subject met MIS-c criteria. Two SH-u patients ultimately evolved to PALF criteria with INR> 2. All patients with SH-u had higher CD8 EM T-cell activation (mean +/- SEM = 43.7+/-6.3%;range 9.2 to 81.3;p<0.0001), which was significantly higher than HC (2.9+/-0.5%) and PALF of known etiology (4.0+/-0.9%) . However, the amplitude of T-cell activation was lower in the SH-u group relative to the HLH group (90.3+/-2.7%;p<0.0001), as shown in Figure 1. A similar trend in T cell activation was noted in the CD4 compartment. Overall, the activation in the CD8 compartment was much greater than in CD4. SH-u patients had a decreased CD4/CD8 ratio compared to the PALF group. Despite higher T cell activation in patients with SH-u compared to PALF, ferritin, often used to screen for hyper-inflammation, was lower in the SH-u group when compared to PALF group (1240+/-609 vs. 39517+/-32149;p<0.05) and very significantly lower than HLH (32415 +/- 14845;p =0.002). 50% of patients with SH-u etiology had ferritin < 500 mg/L. Cytopenia (hemoglobin < 9 g/dL, ANC < 1000/mL, platelets < 100,000/mL) is characteristic of patients with HLH. Despite overlapping T cell activation with HLH, the SH-u cohort had only 2 patients with this feature: one with thrombocytopenia and one with neutropenia. Supportive of this higher T cell activation, we noted chemokines driven by IFN-gamma, CXCL9 and CXCL10, to be elevated in SH-u compared to HCs and comparable to HLH patients. As a proof of concept, 1 patient with SH-u and thrombocytopenia underwent treatment with Emapalumab (an IFN-gamma blocking antibody) along with other immune modulators both with complete liver, immune, and platelet count recovery. Conclusion(s): Our cohort of SH-u was associated with significant T-cell activation. In addition, our patients with HLH and SH-u with T cell activation had similar increased IFN-gamma activity. Despite this T cell activation, ferritin values were significantly lower in SH-u compared to PALF without T cell activation. Ferritin may not be a reliable screening test to identify SH-u patients with significant T cell activation. If validated in a larger well-defined population of SH-u, the results may suggest a role for IFN-gamma blocking agents in a subgroup of SH-u prior to PALF or before bone marrow failure development.
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Background: Infectious complications are a major cause of morbidity and mortality in Chronic Lymphocytic Leukaemia (CLL). Therapeutic approaches that deplete CLL cells also affect normal B-cells. Optimal treatment would result in eradication of CLL cells and recovery of normal immune function. FLAIR (ISRCTN01844152) is a phase III trial for previously untreated CLL comparing ibrutinib plus rituximab (IR) with fludarabine, cyclophosphamide and rituximab (FCR) and subsequently amended to also compare ibrutinib plus venetoclax (I+V) and ibrutinib alone (I) with FCR. Measurable residual disease (MRD) and normal B-cell levels were assessed at multiple timepoints. Aims: To assess the depletion of normal B-cells during treatment and recovery after end of treatment. Methods: Participants aged under 75 years with <20% TP53-deleted cells were initially randomised to FCR or IR and subsequently to FCR, IR, I+V or I with the IR arm closed after randomisation of 771 participants to FCR/IR. FCR was given for 6 cycles, while treatment in the IR, I and I+V arms continued for up to 6 years except in participants attaining <0.01% MRD who continued treatment for the time taken to achieved MRD <0.01% and then stopped if MRD remained <0.01%. Month (M) 24 was earliest permitted stopping point. MRD flow cytometry was performed according to ERIC guidelines (panel: CD19/5/20/43/79/81+ROR1, acquisition of 0.5-2.2 million cells, BD Biosciences Lyric). Additional analysis of normal B-cell subsets was performed in a cohort of >500 patients (panel: CD19 to identify B-cells, CD20/5/79b+ROR1 and CD3 to exclude CLL & contaminating cells, with CD27/ 38/IgD/IgM to characterise normal B-cell subsets using a Coulter Cytoflex LX). Results: Normal B-cells were undetectable during FCR treatment and only rarely detectable until 12 months after last FCR cycle. Circulating normal B-cells were reduced in number or undetectable in participants receiving ibrutinibcontaining regimens with greater depletion in the I+V and IR arms relative to I monotherapy. B-progenitors persist through FCR treatment but were depleted during I, I+R or I+V treatment. Normal B-cell levels at 24 and 36 months after randomisation, with time off-treatment if applicable, are shown in Figure 1. In the ibrutinib-containing arms (IR, I, and I+V), there was a trend towards fewer COVID-associated SAE at any time point for participants with detectable B-cells at 24M (4/181, 2.2%) compared to those with no detectable B-cells (14/344, 4.1%) and COVID-associated SAEs were not observed in FCR-treated participants who had recovered any level of normal B-cells by 24M (0/215). However, the data on COVID infections are limited and there was no apparent association between normal B-cell levels at 24M with the proportion of participants experiencing an infectious SAE overall. Assessment of normal B-cell subsets during ibrutinib-based treatment demonstrated a mix of naïve and memory B-cells. Serological response to COVID infection/vaccination in this cohort is currently being performed. Participants stopping I+V treatment at 24-30 months post-randomisation due to MRD eradication showed rapid recovery of normal naive B-cells within 6-12 months after end of treatment in the vast majority (>95%) of evaluable cases. Summary/Conclusion: Normal circulating B-cells are depleted during treatment with rituximab but can persist at a low level during I, IR or I+V treatment. Most patients in remission after treatment with FCR or I+V show recovery of normal B-cells at 12 months of stopping treatment.
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Background: Systemic AL amyloidosis is an incurable relapsing plasma cell disorder. Despite therapeutic advances, there are no approved treatments for relapse disease. Treatment is often challenging due to underlying organ dysfunction. Belantamab mafodotin is an antibody-drug conjugate targeting B-cell maturation antigen with approval for relapsed refractory myeloma. In multiply pre-treated myeloma, the DREAMM-2 phase II trial showed an overall response rate of 32% for those with 2.5 mg/kg dose administered every three weeks with 2/3rd patients reporting keratopathy. A small case series of 6 patients with relapsed AL amyloidosis (Zhang et al , ASH 2021) was recently reported and a phase 2 trial is recruiting for patients with refractory amyloidosis (NCT04617925). Aims: We report our initial results using Belantamab monotherapy for the treatment of patients with AL amyloidosis with relapsed disease. Methods: Data for consecutive patients who were administered Belantamab at a specialist referral centre, National Amyloidosis Centre, University College London, was analysed. Results: Eleven patients were included 8 male, 3 female. Median age at Belantamab initiation was 65 (range 42-74) years. Eight patients had λ AL-type and three κ AL-type. At diagnosis, median involved free light-chain concentration was 534 (range 73-7181) mg/l. A median of two organs involved at baseline (range 1-3): 4 had cardiac involvement (half Mayo stage 2;half Mayo stage 3a) and 8 had renal involvement. The median prior lines of therapy was 3 (range 2-5) with all exposed to prior immunomodulatory drugs, proteasome inhibitors and 73% to anti-CD38 antibody treatments. Thirty-six percent had relapsed after melphalan-conditioned autologous stem cell transplantation. A median of 3 cycles of belantamab were delivered (range 1-8). The most frequent adverse event was ocular toxicity which was experienced in 8 patients (grade 1-3), necessitating dose modification of the three-weekly schedule. One patient developed transient grade 1 dyspnoea and liver dysfunction. No patients developed cytopenias, unlike previous reports (Zhang et al , 2021), nor infections beyond COVID (2 patients mild with no hospital admissions). The majority of the cohort required dose reduction either at initiation (patient 4, due to end stage renal failure;patient 11, post-renal transplant) or during therapy (n=5;three to 1.9mg/kg, two to 1.25mg/kg) due to ocular toxicity. Only one patient remained on the standard dose of 2.5mg/kg for >3 cycles. Ocular toxicity improved after treatment interruption (drug intervals 4-6 weeks) and no patients required complete treatment cessation. One patient is too early to assess response. Haematological responses (PR or better) were seen in 7 patients with 3 complete responses and two very good partial responses (VGPR) which are ongoing. Both renal patients (patients 4 and 11) commenced a dose of 1.25mg/kg and sustained a VGPR with no additional toxicity. Patient 3 had a 42% reduction in sFLC after two doses but then a prolonged gap due to keratopathy and has lost the response. There were no cardiac or renal toxicities observed. Summary/Conclusion: Belantamab mafodotin demonstrates significant activity in patients with heavily pre-treated AL amyloidosis with 70% achieving a ≥PR. Apart from keratopathy requiring dose modification, no other substantial toxicity was observed. Two patients with renal impairment (stage V CKD and ESRD) and one patient post-renal transplant tolerated treatment with no additional toxicity. Belantamab mafodotin shows promise in treatment of relapsed AL and needs further prospective trials.
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Background: Patients (pts) with cancer are at increased risk of severe COVID-19. Both underlying malignancy and anti-cancer treatments influence the immune system, potentially impacting the level of vaccine protection achieved. Methods: A systematic literature search of PubMed, Embase, CENTRAL and conference proceedings (ASCO annual meetings and ESMO congress) up to 28/09/21, was conducted to identify studies reporting anti-SARS-CoV-2 spike protein immunoglobulin G seroconversion rates (SR) at any time point after complete COVID-19 immunization (mRNA- or adenoviral-based vaccines) in cancer pts. Complete immunization was defined as 1 dose of JNJ-78436735 vaccine or 2 doses of BNT162b2, mRNA-1273 or ChAdOx1 nCoV-19 vaccines. Subgroup analyses were performed to examine the impact of cancer diagnosis, disease stage, and anticancer therapies on the SR. Overall effects were pooled using random-effects models and reported as pooled SR with 95% confidence intervals (CI). Results: Of 1,548 identified records, 64 studies were included in this analysis reporting data from 10,511 subjects. The Table shows the SR in the overall population and specific subgroups. In pts with solid malignancies (SM), disease stage and primary site did not significantly impact the SR. In pts with hematologic malignancies (HM), SR were significantly lower in pts with chronic lymphocytic leukemia (CLL) and non-Hodgkin lymphoma (NHL) compared to acute lymphoblastic leukemia (ALL), Hodgkin lymphoma (HL), and multiple myeloma (MM). Concerning the impact of cancer therapies on SR, pts with SM undergoing chemotherapy had numerically lower SR (N = 1,234, SR 87%, CI 81-92) compared to those treated with immune checkpoint inhibitors (N = 574, SR 94%, CI 88-97) or endocrine therapy (N = 326, SR 94%, CI 86-97) with or without another targeted therapy. Pts with HM treated with anti-CD20 therapy (within the last 12 months: N = 360, SR 7%, CI 2-20;or more than 12m: N = 175, SR 59%, CI 35-80), immune-modulating agents (BTK or BCL2 inhibitors) (N = 462, SR 47%, CI 32-64%) or other immunotherapies (anti-CD19/CART or anti-CD38) (N = 293, SR 37%, CI 23-53) had lower SR compared to pts treated with autologous (N = 353, SR 77%, CI 67- 85) or allogenic stem cell transplantation (N = 509, SR 77%, CI 68-84). Conclusions: SR varies between cancer types and anticancer therapies with some cancer pts having low protection against COVID- 19 even after complete vaccination.
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Background: The defective immune system in plasma cell dyscrasia places patients at a higher risk of developing a severe infection, which is one of the leading causes of death in such patients. In an era of a global pandemic, it is essential to protect them against COVID-19, but fewer effective plasma cells lead to a suboptimal response to vaccines. There is still a lack of evidence whether the seroconversion is truly clinically relevant and if patients with plasma cell disorders would benefit from frequent boosters to maintain antibody levels. Methods: Online databases including PubMed, CINAHL, Ovid, and Cochrane were searched (January 11th, 2022), following the PRISMA (Preferred Reporting Items for Systematic Review and Meta-Analysis) guidelines. Only articles published in the English language were included. s, case reports, and case series were excluded. Out of 40 studies, 5 articles were selected for a systematic review. Results: In all 5 studies (N=654), seroconversion post-vaccination was used as a positive response to COVID-19 vaccination. Although patients with plasma cell disorders had a lower seroconversion rate compared to controls, the overall percentage was substantial and ranged between 23-95.5%. Amongst patients on active therapy, lower seroconversion rates were seen in patients on a CD-38 inhibitor, ranging from 20.2-92.1% (N=174). Also, a significantly lower percentage was recorded in patients above 65 years and those who have been treated with multiple therapies previously. Better seroconversion rates were seen in mRNA vaccines compared to J&J. Conclusions: Variable seropositive rates are seen in patients with plasma cell dyscrasias, lower rates are reported in patients on active therapy, CD-38 targeting therapy, and elderly patients. Hence, these patients should receive a 4 shot series.
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Background: GC012F is a B cell maturation antigen (BCMA)/CD19 dual-targeting CAR-T developed on the novel FasT CAR-T platform with overnight manufacturing and designed to improve depth of response and efficacy. Data was presented at ASCO and EHA 2021 for initial 19 pts. We present updated data for study (NCT04236011;NCT04182581) with longer follow up and 9 additional pts treated (n = 28) in 3 different dose levels. Methods: From October 2019 to November 2021, 28 heavily pretreated RRMM pts (age 27-76) median of 5 prior lines (range 2-9) were treated on a single-arm, open label, multicenter Investigator Initiated Trial receiving a single infusion of GC012F. 89.3% (25/ 28) were high risk (HR- mSMART), 8 pts had EM disease, 3 had never achieved a CR including after transplant, 1 pts presented with plasma cell leukemia, 24/28 pts were refractory to last therapy, 3 pts primary refractory. 9/28 pts had received prior anti-CD38, 27/28 pts prior IMiDs. 26/28 pts were refractory to PI, 26/28 pts to IMiDs. After lymphodepletion over 2-3 days (30 mg/m2/d, 300mg/ m2/d Flu/Cy) GC012F was administered as single infusion at 3 dose levels: 1x105/kg (DL1) n = 2, 2x105/kg (DL2) n = 10 and 3x105/kg (DL3) n = 16. Results: As of Jan 26th 2022, 28 pts - median follow-up (f/ u) 6.3 mths (1.8-29.9) - had been evaluated for response. Overall response rate (ORR) in DL1 was 100% (2/2)- DL 2 -80% (8/10) DL 3 -93.8% (15/16) with 27 pts MRD negative by flow cytometry (sensitivity 10-4-10-6). 100% of MRD assessable pts (27/27) achieved MRD negativity. One patient out of 28 could not get assessed. At d28, 21/24 assessable patients were MRD negative (81.5%), 4/ 28 pts could not get d28 MRD assessment f/u due to COVID-19 restrictions however were assessed at a later timepoint. To date best response is MRD- sCR in 21/28 patients(75.0%) across all dose levels. Some pts after short f/u show responses that are still deepening. Cytokine Release Syndrome (CRS) was mostly low grade: gr 0 n = 3 (10.7%), gr 1-2 n = 23 (82.1%), gr 3 n = 2 (7.1%) - no gr 4/5 CRS and no ICANs were observed (Graded by ASBMT criteria). Median duration of CRS was 3 d (1-8 d). PK results showed no difference amongst dose levels DL1 to DL3. Overall, CAR-T median Tmax was 10 d (range 8-14 d), median peak copy number (Cmax) was 97009 (16,011-374,346) copies /μg DNA with long duration of persistence of up to d793 (data cut-off). CAR-T geometric mean AUC0-28 for DL1, DL2 and DL3 were 468863, 631540 and 581620 copies/μg DNA×day, respectively. Pts continue to be monitored for safety and efficacy including DOR. Conclusions: BCMA-CD19 dual FasT CAR-T GC012F continues to provide deep and durable responses with a favorable safety profile in additional RRMM pts across all dose levels demonstrating a very high MRD negativity rate including in pts refractory to anti-CD38, PI and IMIDs. GC012F is currently being studied in earlier lines of therapy as well as additional indications.
ABSTRACT
During the first period of the Covid-19 pandemic, most of the immunological studies on SARS-CoV-2 were based on hospitalized-and intensive care unit patients. In this study, a healthy population continuously exposed to the virus, Swedish primary health care workers (n = 156), were monitored for 6 months and the development of antibody patterns and T-cell responses to SARS-CoV-2 were evaluated. In addition to blood sampling, demographic-and clinical information such as PCR-tests, self-reported symptoms, underlying medical conditions, and medications were collected. Multivariate statistical analysis using OPLS-DA showed that Covid-19 infection was associated with SARS-CoV-2 specific IgG antibodies, T-cell responses, male sex, hypertension, and higher BMI and contrary, that not contracting the infection, was associated with female sex, no-or only SARS-CoV-2 specific IgA antibodies, smoking and airborne allergy. Analysis with Cytometry by Time-of-flight (CyTOF) revealed a unique cytotoxic CD4+ T cell population in participants with IgG-dominated antibody responses which expressed CD25, CD38, CD69, CD194, CD279, CTLA-4 and granzyme B. 10% of the study participants had only SARS-CoV-2 specific IgA antibodies with no detectable SARS-CoV-2 specific IgG antibodies. These IgA antibodies could partially neutralize the virus in vitro and none of the participants with this antibody pattern contracted Covid-19 during the study period. These results have the potential to further help us understand the immunological responses to SARS-CoV-2 infection.
ABSTRACT
Background: Although respiratory failure is the hallmark of severe disease, it is increasingly clear that Coronavirus Disease 2019 (COVID-19) is a multi-system disorder. The presence of gastrointestinal (GI) involvement by Severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) has been suggested by epidemiological, clinical, non-human primate, in-vitro (enteroid) and ex-vivo (human biopsy) studies. Having recently documented persistence of SARS-CoV-2 within the intestinal epithelium 7 months after infection, here we aimed to study mucosal immune cell abnormalities in individuals with prior history of COVID-19. Methods: Individuals with previous COVID-19 diagnosis (by either RT–PCR or seroconversion) and controls (without RT-PCR or serological evidence of prior COVID-19 infection) undergoing endoscopic evaluation were recruited into the study (Table 1). Colonic and small intestinal (duodenal and ileal) biopsies were analyzed by multiparameter flow cytometry for mucosal immune cell populations including myeloid cells (classical and non-classical monocytes, dendritic cell subsets), T cells (subsets and activation state), B cells (including plasma cells) and NK cells. Persistence of viral antigens was determined by immunofluorescence microscopy (n=30) using a previously published anti-nucleocapsid (NP) antibody. Results: Thirty subjects with a previous history of COVID-19 (post-COVID), median of 4 months from diagnosis (range 1-10 months), were recruited and compared with 40 normal volunteer (NV) controls. Relative to controls, post-COVID subjects displayed higher frequencies of classical (CD14+) monocytes in both, the colon and the small bowel, while significantly higher frequencies of conventional dendritic cells (cDC)1 (lin-HLA-DRhiCD14- CD11c+CD141+) and cDC2 (lin-HLA-DRhiCD14-CD11c+CD1c+) were noted in the colon. Among NK subsets, CD56bright CD16- NK cells were significantly higher in the colon of post-COVID subjects. Among T cell subsets, CD8+ tissue resident memory T cells (CD8+CD69+CD103+) were significantly increased in colon of post-COVID subjects compared to NV. Among B cell subsets, plasma cells (CD3-CD27+CD38hi) trended higher (p= 0.06), while mucosal B cells (CD3-CD19+) were significantly lower in the terminal ileum of post-COVID subjects compared to NV. Finally, with IF, we detected SARS-CoV-2 NP in 10 out of 30 (33%) of post-COVID subjects (Figure 1). Conclusion: Innate and adaptive immune cell abnormalities persist in the intestinal mucosa of post-COVID subjects for up to 10 months and may reflect viral persistence or immune cell dysregulation in the intestines. These findings have major implications for understanding the pathogenesis of long-term sequelae of COVID-19, including long-haul COVID.(Table Presented)(Figure Presented)
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Background: SARS-COV-2 anti-Spike IgG response following mRNA vaccination (BNT162b2) is suboptimal and highly variable in MM patients. Patients and Methods: We report here a single-institution retrospective analysis of 127 consecutive patients with symptomatic MM (71 males, 56 females), [median age 69.5 years (range 45-85)], 63 patients with untreated MM and 64 patients with MM refractory to one or more previous treatment lines. Myeloma therapies included PI+IMiD combos, IMiD-based regimens, PI-based regimens, anti-CD38 mAb-based therapies, antibody-drug conjugates (Belantamab Mafodotin monotherapy), dexamethasone and high dose melphalan. Anti-spike IgG antibody were detected also in 50 healthy volunteers. Patients with symptomatic MM and healthy controls received two dose of COVID-19 mRNA vaccine (Pfizer BioNTech) on days 1 and 21 between 29 April and 15 May 2021. Patients with prior history of SARS-CoV-2 were excluded from analysis. Quantitative determination of anti-spike S1/S2 IgG antibody was performed at 4 weeks from vaccination completion (LIAISONR SARS-COV-2 S1/S2 IgG, LIAISONR). It was previously established a threshold >15 AU/ml of anti-Spike IgG which was related to neutralizing activity of anti-SARS-COV-2 antibodies. Results: Sixty-five out of 127 patients were evaluable for response. Antispike IgG antibody were detected in 50/65 (76.9%) MM patients, defined as responders [177 AU/mL (range 26.4 - 1430)]. 23.1% of MM patients, defined as non-responders, failed to respond at two doses of COVID-19 mRNA vaccine [3.8 AU/mL (range 0.65 - 9.33)]. Seroprotection rate at cutoff of 15 AU/mL was 100% in controls [249 AU/mL (range 104 - 2430)]. No statistically significant differences were found between the two subgroups of patients for myeloma disease phase (relapse/refractory MM vs. untreated symptomatic MM), LDH, residual gammaglobulin levels, WBC, ANC, lymphocytic response, age and sex (Tab. 2). Conversely, plasmacytosis, B2M and haemoglobin concentration were associated with a different response to vaccine. Patients with extreme plasmacytosis (60.0 20.3 vs. 28.218.8 meanSD;p <0.001) (Tab. 2) had a mean titer less than 15 AU/ml of anti-Spike IgG compared with patients with a low plasmacytosis, who, conversely, showed significantly higher mean titers of anti-Spike IgG. B2M was significantly higher in non-responders compared to responders (4.6 4.1 vs. 3.23.6 mean SD;p = 0.006) (Tab. 2). Haemoglobin value was significantly lower in non-responders compared to responders (10.8 1.8 vs. 12.11.8 mean SD;p = 0.008) (Tab. 2). Multivariate analysis confirmed the bone marrow infiltration pattern and haemoglobin value as statistically significant variables. In addition, in the present cohort, the myeloma treatment, including high-dose melphalan and autologous stem cell transplantation, have not been associated with SARS-CoV-2 infection. Conclusions: In our experience, significant fraction of MM patients (23.1%) does not developed any detectable anti-Spike IgG after two dose of COVID-19 mRNA vaccine. Lack of IgG response associated with three statistically significant variables: extreme plasmacytosis, B2M, and haemoglobin concentration. In the subgroup of patients with good response to vaccine, after a median follow-up of 7 months from second dose of COVID-19 mRNA vaccine, no cases of COVID-19 occurred. .
ABSTRACT
The disease- and treatment-induced immunosuppression in MM accounts for a two-fold higher risk for infection with the SARS-CoV-2 virus, an increased risk for a prolonged, severe symptomatic disease, and an increased mortality. Most pts are aware of these risks and show a higher compliance with vaccination recommendations compared to the general population. Several studies revealed differences in the humoral and cellular immune response between pts with MGUS, SMM, and MM, with normal median antibody titers in MGUS, moderately impaired response in SMM, and significantly reduced antibody response in MM, albeit with a wide variation in titers between individual pts. Pts with active, poorly controlled disease and those exposed to CD38 and BCMA-targeting treatments frequently show no or reduced SARS-CoV-2 antibody responses. The EMN issued a consensus that MM pts should ideally be vaccinated before onset of active disease and/or during periods of well controlled disease. A third dose should be administered after an interval of approximately 6 months, and early data in immunocompromised pts show a vaccination response in several previously poorly responding pts after a forth dose. An open question pertains to the role of the interrelationship between the innate, humoral and cellular immune system. Neutralizing antibodies provide the best proxy for protection, although specific thresholds associated with protection against infection are unlikely to be established given the many factors associated with infection control. Antibody titers decline with time from vaccination and more so in vaccinated pts compared to those who have been infected and vaccinated, mandating booster shots in time intervals that need to be established. Pts may present without measurable antibody titers but with detectable cellular immunity or vice versa, although in most reports, correlations between antibody and cellular response were noted. Data suggest that SARSCoV- 2 specific memory B and T cells persist for prolonged periods. One of the threads to patient protection is the substantial mutational activity of the SARS-CoV-2 virus with reduced neutralizing capacity of vaccine induced antibodies against recent variants of concern, particularly the omicron variant, posing vaccinated pts at risk for breakthrough infections. Recent research efforts resulted in new prophylactic treatments for pts with high risk for severe COVID-19 disease (Table 1) that have been shown to reduce the incidence of severe complications. .
ABSTRACT
Introdução: A macroglobulinemia de Waldenstrom (MW) é uma patologia linfoproliferativa neoplásica maligna das células plasmáticas e linfócitos B, normalmente responsável pela síntese das cadeias pesadas de imunoglobulinas. Diferente da leucemia linfoblástica aguda, os linfócitos mantêm a capacidade de se diferenciar e amadurecer em células plasmáticas. A MW possui características que variam de células linfoides maduras a plasmócitos. Imunofenotipagem de células obtidas a partir da medula óssea, dos linfonodos ou do sangue periférico de pacientes com essa doença mostram IgM citoplasmática detectável em células plasmáticas e imunoglobulina superficial na maioria dos linfócitos. Objetivo: Apresentar um caso de MW. Material e métodos: Revisão de prontuáriros médicos e literatura. Descrição do caso: Paciente do sexo masculino, 61 anos, apresentou epistaxe de grande volume com repetição, fadiga e astenia, além de perda de 15 quilos em 6 meses. Na admissão hospitalar apresentava os seguintes exames: anemia com hemoglobina 5,4 g/dL, hemácias de 1,45 milhão/mm3, plaquetopenia (87.000/mm3), presença de esplenomegalia importante, roleaux eritrocitário, esplenomegalia e linfonodomegalia abdominal. Solicitada avaliação com hematologista por paciente referir repetidas anemias ao longo da vida e histórico de transfusões de repetição. Seguem os resultados da investigação com especialisgta: Mielograma apresentou células linfoides de tamanho pequeno e aspecto maduro, algumas apresentando aspecto plasmocitoide. Imunofenotipagem de sangue periférico com CD20/CD38, CD38, CD200, CD19/CD200 positivo fraco;CD19, CD45, CD45/CD22, KAPPA, CD20: positivo de alta intensidade;KAPPA cito- plasmático e CD43 positivo. Dosagem de Imunoglobulinas: IgM 10.100 mg/dL, IgG 242 mg/dL e IgA 91,5 mg/dL. Pico monoclonal IgM/Lambda na imunofixação sérica. Exame de Coombs direto negativo. Como terapêutica, iniciou-se Ciclofosfamida associado a Rituximabe. O paciente evoluiu ao óbito devido ao Covid-19 durante a internação. Discussão: A MW é uma neoplasia rara, sendo que o paciente deste relato enquadra-se na idade média do diagnóstico de MW, que ocorre em torno dos 60 anos, maioria do sexo masculino. Grande parte dos pacientes apresenta sintomas como fadiga, fraqueza e sangramento (principalmente epistaxe). Outras manifestações como perda de peso, distúrbios visuais e fenômeno de Raynaud são menos comuns. Ao exame físico, encontra-se rotineiramente hepatoesplenomegalia e linfadenopatia. Proteinúria de Bence Jones está presente em um quarto de todos os pacientes com MW, devido a uma lesão predominantemente glomerular com depósitos de IgM e material amiloide. A função plaquetária está prejudicada pelo revestimento de plaquetas com IgM, e alguns pacientes podem apresentar defeitos da cascata de coagulação. Os níveis de IgM são marcadamente aumentados, e a crioglobulina pode ser detectada em alguns pacientes. O tratamento deve ser individualizado de acordo com as manifestações clínicas de cada paciente e seu curso clínico é variável. Causas de morte relacionam-se geralmente a hiperviscosidade, anemia, hemorragia, trombose e infecções, sendo que neste caso a infecção por Covid-19 atuou como fator definidor. Conclusão: É oportuno o relato de um caso de MW devido a raridade de seu diagnóstico e importância de estabelecer diagnóstico diferencial com doenças de maior prevalência.
ABSTRACT
Background: Since the first case of COVID19 infection in 2019, this RNA virus has led an unprecedented pandemic that infected more than 232 million people. Although the disease is studied extensively, much remains poorly understood. Here, we performed the first correlation study on the peripheral blood morphology and immunophenotype of the white blood cells (WBCs) from COVID19 patients. Design: A total of 52 samples from COVID19 patients and 15 blood samples as control group were analyzed. COVID19 patients were divided into two groups based on clinical severity, severe (respiratory failure) or non-severe (hospitalized but stable). The controls were the patients with negative COVID19 results by PCR and antibody tests. The WBC morphology was examined either by blood smear review or via CellaVision DM analyzer captured images. Navios flow cytometer and Beckman Kaluza C software were used for immunophenotype analysis. Two-tailed T-test was performed on the COVID19 groups and the control group Results: Almost all COVID19 patients showed marked neutrophilia and lymphopenia on the CBC tests. Morphologically, the neutrophils showed irregularities like hypogranulation, toxic granules and pseudo Pelger-Huet anomaly (Fig 1A). In severe COIVD19 group, there was an increase in neutrophils with immatures phenotypes, showing CD33 positivity while CD10, CD13 and CD16 negative (Fig 1B). Conversely, the CD10(+) mature neutrophils aberrantly expressed CD56 (Fig 1B). The percentage of CD56(+) neutrophils was significantly higher in both COVID19 groups, suggesting a stronger cellular adhesion and interaction. The monocytes from the COVID19 patients had increased cytoplasm with cytoplasmic protrusion and vacuolization (Fig 2A). Phenotypically they were positive for CD13, CD33, CD38 and HLA-DR. The lymphocytes were also atypical, including increased cytoplasm with large granules and vacuoles. Phenotypically, they are activated, expressing CD38, HLA-DR, and mainly α/β subtype. Giant platelets with cytoplasmic vacuoles and projections were easily seen. Platelet aggregations were observed (Fig 2B). These platelets were CD45(-) and expressed CD61 at lower-than-normal intensity, while expressing increased CD42b intensity when compared to the control group on a log scale. Conclusions: Despite being a small study, we were able to correlate the morphologic and phenotypic alterations of the WBCs in COVID19 patients. As such, this helped to explain some of the clinical hematologic manifestation of the disease. (Figure Presented).