Portal vein thrombosis in a patient with severe hemophilia B: A challenging balanced management.

Key Clinical Message: The increased life expectancy in patients with hemophilia (PwH) over the last years has raised the incidence of comorbidities, including thromboembolic events. Thromboembolic events are rare in PwH and most of them occur in the presence of exogenous risk factors. There is still scarce scientific evidence on the optimal antithrombotic treatment and management approach in this population. Abstract: In the hemophilic population thromboembolic events are rare. Most of them are often multifactorial and occur in the presence of both exogenous (orthopedic surgery, intensive replacement therapy, use of central venous catheters…) and endogenous (cardiovascular diseases) risk factors. We describe the case of a 43-year-old patient with severe hemophilia B (sHB) receiving prophylaxis with eftrenonacog alfa (rFIXFc) and antithrombotic treatment due to portal vein thrombosis. The patient was treated with extended half- life factor IX (EHL-FIX) prophylaxis maintaining higher trough levels to avoid new bleeding episodes associated to the underlying disease and the use of antithrombotic therapy with low molecular weight heparin. EHL-FIX concentrates allow prolonged intervals between intravenous infusions and higher hemostatic protection thanks to increased factor trough levels. This current case report provides clinical evidence in antithrombotic management in a patient with severe hemophilia B.

Neurosurgery in a patient with severe hemophilia B: an experience using eftrenonacog alfa as perioperative management.

Extended half-life FIX (EHL-FIX) concentrates have been developed with the purpose of reducing the frequency of infusions in patients with severe or moderate hemophilia B. We describe the case of a 63-year-old patient with severe hemophilia B (sHB) treated with FIX-Fc fusion protein (rFIXFc) who underwent neurosurgery.

Zanubrutinib for the treatment of MYD88 wild-type Waldenström macroglobulinemia: a substudy of the phase 3 ASPEN trial.

Patients with Waldenström macroglobulinemia (WM) lacking activating mutations in the MYD88 gene (MYD88WT) have demonstrated relatively poor outcomes to ibrutinib monotherapy, with no major responses reported in a phase 2 pivotal study. Zanubrutinib is a novel, selective Bruton tyrosine kinase (BTK) inhibitor designed to maximize BTK occupancy and minimize off-target activity. The ASPEN study consisted of a randomized comparison of zanubrutinib and ibrutinib efficacy and safety in patients with WM who have the MYD88 mutation, as well as a separate cohort of patients without MYD88 mutation (MYD88WT) or with unknown mutational status who received zanubrutinib. Results from the latter single-arm cohort are reported herein. Efficacy endpoints included overall, major and complete (CR) or very good partial response (VGPR) rates, progression-free survival (PFS), duration of response (DOR), and overall survival (OS). Twenty-eight patients (23 relapsed/refractory; 5 treatment-naïve) were enrolled, including 26 with centrally confirmed MYD88WT disease and 2 with unknown MYD88 mutational status. At a median follow-up of 17.9 months, 7 of 26 MYD88WT patients (27%) had achieved a VGPR and 50% a major response (partial response or better); there were no CRs. At 18 months, the estimated PFS and OS rates were 68% and 88%, respectively, while the median DOR had not been reached. Two patients discontinued zanubrutinib due to adverse events. Treatment-emergent hypertension, atrial fibrillation, and major hemorrhages were reported in 3, 1 and 2 patients (including 1 concurrent with enoxaparin therapy), respectively. Results of this substudy demonstrate that zanubrutinib monotherapy can induce high quality responses in patients with MYD88WT WM. This trial is registered on www.clinicaltrials.gov as NCT #03053440.

La realidad asistencial del tratamiento del mieloma múltiple de alto riesgo en España / Healthcare reality of the treatment of the high-risk multiple myeloma in Spain

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Avances en el tratamiento de la amiloidosis / New trends in the treatment of amyloidosis

La amiloidosis es un trastorno causado por el depósito extracelular de proteínas, que normalmente son solubles, en forma de fibras insolubles, que alteran el funcionamiento de los órganos donde se depositan. Más de 20 tipos de proteínas no relacionadas entre sí pueden producir depósitos amiloides in vivo. Todas las fibras amiloides comparten la característica de que adoptan una estructura secundaria en disposición en β plegada, lo que les hace adoptar una birrefringencia verde manzana tras ser teñidas con la tinción de Rojo Congo y ser observadas bajo un microscopio de luz polarizada. La amiloidosis puede ser adquirida o hereditaria, sistémica o localizada, y se clasifica en función del precursor proteico para cada tipo. Avances en la patogénesis de la amiloidosis han permitido desarrollar técnicas diagnósticas y de tratamiento que están actualmente en desarrollo y que en el futuro constituirán nuevas estrategias terapéuticas (AU)

Amyloidosis is a clinical disorder caused by extracellular deposition of proteins that are normally soluble as insoluble fibrils that damage different organs. More than 20 proteins can form amyloid deposits. All types of amyloid fibrils have a secondary structure with a β folded shape that is characteristic and makes them to adopt a green birefringence after stained with Congo red and viewed under cross-polarized light. Amyloidosis can be acquired or hereditary, systemic or localized, and are classified by the fibril precursor protein. Advances in the knowledge of the pathogenesis of amyloidosis allows the development of new diagnostic and therapeutical schemes that are currently under investigation (AU)

[New trends in the treatment of amyloidosis]. / Avances en el tratamiento de la amiloidosis.

Amyloidosis is a clinical disorder caused by extracellular deposition of proteins that are normally soluble as insoluble fibrils that damage different organs. More than 20 proteins can form amyloid deposits. All types of amyloid fibrils have a secondary structure with a ß folded shape that is characteristic and makes them to adopt a green birefringence after stained with Congo red and viewed under cross-polarized light. Amyloidosis can be acquired or hereditary, systemic or localized, and are classified by the fibril precursor protein. Advances in the knowledge of the pathogenesis of amyloidosis allows the development of new diagnostic and therapeutical schemes that are currently under investigation.