Elliot Vichinsky

Bone Disease in Thalassemia: A Frequent and Still Unresolved Problem

Adults with β thalassemia major frequently have low BMD, fractures, and bone pain. The purpose of this study was to determine the prevalence of low BMD, fractures, and bone pain in all thalassemia syndromes in childhood, adolescence, and adulthood, associations of BMD with fractures and bone pain, and etiology of bone disease in thalassemia. Patients of all thalassemia syndromes in the Thalassemia Clinical Research Network, ≥6 yr of age, with no preexisting medical condition affecting bone mass or requiring steroids, participated. We measured spine and femur BMD and whole body BMC by DXA and assessed vertebral abnormalities by morphometric X‐ray absorptiometry (MXA). Medical history by interview and review of medical records, physical examinations, and blood and urine collections were performed. Three hundred sixty‐one subjects, 49% male, with a mean age of 23.2 yr (range, 6.1–75 yr), were studied. Spine and femur BMD Z‐scores < −2 occurred in 46% and 25% of participants, respectively. Greater age, lower weight, hypogonadism, and increased bone turnover were strong independent predictors of low bone mass regardless of thalassemia syndrome. Peak bone mass was suboptimal. Thirty‐six percent of patients had a history of fractures, and 34% reported bone pain. BMD was negatively associated with fractures but not with bone pain. Nine percent of participants had uniformly decreased height of several vertebrae by MXA, which was associated with the use of iron chelator deferoxamine before 6 yr of age. In patients with thalassemia, low BMD and fractures occur frequently and independently of the particular syndrome. Peak bone mass is suboptimal. Low BMD is associated with hypogonadism, increased bone turnover, and an increased risk for fractures.

Efficacy and safety of the Gardos channel blocker, senicapoc (ICA-17043), in patients with sickle cell anemia

Senicapoc, a novel Gardos channel inhibitor, limits solute and water loss, thereby preserving sickle red blood cell (RBC) hydration. Because hemoglobin S polymerization is profoundly influenced by intracellular hemoglobin concentration, senicapoc could improve sickle RBC survival. In a 12-week, multicenter, phase 2, randomized, double-blind, dose-finding study, we evaluated senicapocs safety and its effect on hemoglobin level and markers of RBC hemolysis in sickle cell anemia patients. The patients were randomized into 3 treatment arms: placebo; low-dose (6 mg/day) senicapoc; and high-dose (10 mg/day) senicapoc. For the primary efficacy end point (change in hemoglobin level from baseline), the mean response to high-dose senicapoc treatment exceeded placebo (6.8 g/L [0.68 g/dL] vs 0.1 g/L [0.01 g/dL], P < .001). Treatment with high-dose senicapoc also produced significant decreases in such secondary end points as percentage of dense RBCs (-2.41 vs -0.08, P < .001); reticulocytes (-4.12 vs -0.46, P < .001); lactate dehydrogenase (-121 U/L vs -15 U/L, P = .002); and indirect bilirubin (-1.18 mg/dL vs 0.12 mg/dL, P < .001). Finally, senicapoc was safe and well tolerated. The increased hemoglobin concentration and concomitant decrease in the total number of reticulocytes and various markers of RBC destruction following senicapoc administration suggests a possible increase in the survival of sickle RBCs. This study is registered at http://clinicaltrials.gov as NCT00040677.

The Morbidity of Bone Disease in Thalassemia

Abstract: As thalassemia patients age, bone disease becomes a serious cause of morbidity. The frequency and type of bone disease is affected by the underlying type of thalassemia and its treatment. Problems include rickets, scoliosis, spinal deformities, nerve compression, fractures and severe osteoporosis. In early stages, patients may be asymptomatic but can present with back pain, a limp, dyspnea, neurological emergencies, or sudden fractures. The etiologies are often multifactorial, culminating with increased bone resorption and remodeling. They include hormonal deficiency, bone marrow expansion, nutritional deficiency, or desferal toxicity. Particular risk factors include older patients, low baseline hemoglobin, delayed puberty, hormonal failure, and high iron stores. Nutritional deficiencies may further compound the patients risk for bone disease. Increasing evidence suggests that these complications and their associated long‐term morbidity can be prevented if an annual screening is done, followed by long‐term intervention. Patients treated with amino biphosphonates inhibit bone resorption and may demonstrate rapid healing. Intra‐nasal calcitonin has also been successful in treating osteopenia. Early use of estrogen and testosterone appears to markedly lower the risk for selective patients. Both transfused and non‐transfused patients should be educated about risk factors and early symptoms. All patients should be screened annually for bone disease. Once adolescence occurs, annual testing in selected cases should include bone density studies with X‐ray absorptiometry.

Differentiation of homozygous hemoglobin E from compound heterozygous hemoglobin E-β0-thalassemia by hemoglobin E mutation analysis†

OBJECTIVES To facilitate the differential diagnosis of hemoglobin FE in newborn infants (homozygous hemoglobin E vs hemoglobin E-beta O-thalassemia). METHODS The beta-globin gene in DNA from infants found to have hemoglobin FE in the California newborn screening program was amplified by the polymerase chain reaction, and the product was digested with Mnl I, which fails to cut the product when the hemoglobin E mutation is present. When both amplified alleles fail to be cut, homozygous EE is diagnosed. If only one allele is cut, a beta-globin allele without the E mutation is present (non-E), which is most likely a gene with a beta O-thalassemia mutation. RESULTS Samples from 18 infants revealed an EE genotype, and from two samples a non-E/E genotype was determined. Clinical examination of these two patients confirmed a diagnosis of hemoglobin E-beta O-thalassemia. An independent clinical diagnosis agreed with DNA analysis for all 17 of the 20 infants for whom follow-up and family studies were available. The DNA results were obtained within a week, but the clinical diagnoses often could not be resolved unequivocally for months. CONCLUSIONS The direct analysis of patient DNA samples for the hemoglobin E mutation allowed rapid and accurate diagnosis in this sample of infants with hemoglobin FE on the newborn screen. This rapid discriminatory test should reduce cost and simplify the diagnostic approach for these patients, which currently consists of expensive and lengthy follow-up until clinical data and family studies result in a diagnosis.

NNKTT120, an anti-iNKT cell monoclonal antibody, produces rapid and sustained iNKT cell depletion in adults with sickle cell disease

Invariant NKT (iNKT) cells can be activated to stimulate a broad inflammatory response. In murine models of sickle cell disease (SCD), interruption of iNKT cell activity prevents tissue injury from vaso-occlusion. NKTT120 is an anti-iNKT cell monoclonal antibody that has the potential to rapidly and specifically deplete iNKT cells and, potentially, prevent vaso-occlusion. We conducted an open-label, multi-center, single-ascending-dose study of NKTT120 to determine its pharmacokinetics, pharmacodynamics and safety in steady-state patients with SCD. Doses were escalated in a 3+3 study design over a range from 0.001 mg/kg to 1.0 mg/kg. Twenty-one adults with SCD were administered NKTT120 as part of 7 dose cohorts. Plasma levels of NKTT120 predictably increased with higher doses. Median half-life of NKTT120 was 263 hours. All subjects in the higher dose cohorts (0.1 mg/kg, 0.3 mg/kg, and 1 mg/kg) demonstrated decreased iNKT cells below the lower limit of quantification within 6 hours after infusion, the earliest time point at which they were measured. In those subjects who received the two highest doses of NKTT120 (0.3, 1 mg/kg), iNKT cells were not detectable in the peripheral blood for a range of 2 to 5 months. There were no serious adverse events in the study deemed to be related to NKTT120. In adults with SCD, NKTT120 produced rapid, specific and sustained iNKT cell depletion without any infusional toxicity or attributed serious adverse events. The next step is a trial to determine NKTT120’s ability to decrease rate of vaso-occlusive pain episodes. Trial Registration: clinicaltrials.gov NCT01783691.

Nesidioblastosis in Sickle Cell Disease

Although the endocrine pancreas appears to play an important role in the pathophysiology of sickle cell disease, very little is known about the morphologic changes in this tissue. Our study was initiated to delineate the microscopic features of the endocrine pancreas in a large autopsy series of sickle cell hemoglobinopathies. From more than 650 cases archived at the Centralized Pathology Unit for Sickle Cell Disease (Mobile, AL), 224 autopsy cases were identified for review of clinical and gross autopsy findings and/or for microscopic studies, including histochemical stains (trichrome, reticulin, iron), and immunohistochemical stains (insulin, glucagon, somatostatin, and pancreatic polypeptide). The gross examinations were recorded as unremarkable in 65% of the autopsies. In childhood and adolescence (≤18 years), pancreas weights (50.76 ± 5.16SE gm) were significantly greater (p < 0.0001) than age-matched controls (30.42 ± 3.59SE gm). In adulthood, pancreas weights (108.34 ± 5.29SE gm) were not significantly different from controls (110 gm). Microscopic findings included vascular congestion (48%), edema (65%), siderosis (31%), and nesidioblastosis (76%), which included islet cell dispersion (53%), hyperplasia (23%), and hypertrophy (25%). Analysis by age groups suggested that islet cell dispersion hyperplasia persists unchanged, whereas diameters of compact islets tend to increase with age. These findings may be related to local tissue hypoxia and/or increased metabolic energy needs in sickle cell disease.