Osteopetrosis, also called “marble bone disease,” refers to a group of rare hereditary disorders characterized by osteoclast dysfunction resulting in abnormally dense bone and excessive skeletal mass with paradoxical bone fragility. Heinrich Albers-Schönberg, a German gynecologist and radiologist (born in 1891), first described osteopetrosis in 1904 [1]. Since then many types of the disease have been identified, and in 1963, Harry Mullins Worth, a British radiologist (born in 1897) who graduated with degrees in dentistry and medicine, and worked in the UK as well as Canada, introduced the term osteopetrosis (from the Greek “osteo” meaning bone and “petros” meaning stone) because of the rock-like appearance of the bone [2,3]. Osteopetrosis has for decades been categorized by its clinical severity and inheritance pattern into a malignant infantile autosomal recessive form, an intermediate autosomal recessive form and an adult autosomal dominant form, which is the most benign type, frequently identified incidentally [4,5]. The incidence of these conditions is estimated about 1 in 250,000 live births for autosomal recessive osteopetrosis (ARO) and about 1 in 20,000 live births for autosomal dominant adult type (ADO) [3]. The disease is more frequently seen in ethnic groups where consanguinity is common [6]. Recent advances in genetics progressively allow the classification of osteopetrosis by its underlying molecular pathogenesis [5]. Mutations in at least 10 genes have been identified in humans, accounting for 70.0% of all cases, among them
Infantile osteopetrosis can manifest with severe bone marrow failure that can mimic hematological malignancy including anemia, thrombocytopenia, leukopenia, susceptibility to infections and hepatosplenomegaly. Narrowing of osseous foramina can lead to compressive cranial neuropathies, vision impairment and deafness [5,7, 8, 9]. If therapy is unsuccessful, death occurs by early childhood as a result of bleeding, anemia or infection [9]. In a setting of intense positive body calcium, rickets is a paradoxical complication of osteopetrosis, a condition called osteopetrorickets. This case reports osteopetrorickets in an infant with coexisting congenital cytomegalovirus (CMV), infection, successfully treated by bone marrow transplantation (BMT).
A full-term 2 and a half-month-old female, the second child of consanguine parents with an uneventful perinatal and neonatal history, was admitted to our clinic due to hepatosplenomegaly, pallor and petechiae noted by their pediatrician at routine check. Upon admission, the infant was afebrile, in a good general condition. Physical examination showed mild growth retardation, hepatosplenomegaly, slightly enlarged anterior fontanelle, abnormal eye movements, mild hypertonia of low extremities. Sporadic petechiae in head, neck and lower abdomen were also noticed. Laboratory findings demonstrated leukocytosis [white blood cell (WBC): 41,350 × 109/L], normocytic normochromic anemia [hemoglobin (Hb) 7.5 g/dL, packed cell volume (PCV) 0.24 L/L, mean corpusucular volume (MCV) 86.9 fL, mean corpuscular Hb (MCH) 28.4 pg, reticulocytes 11.37%] and thrombocytopenia [platelet (PLT) count 46,000 × 109/L]. Coagulation exams, direct and indirect Coombs tests were negative. Serology revealed high levels of alkaline phosphatase (ALP) 1290.0 U/L, lactate dehydrogenase (LDH) 1003.0 U/L, lactic acid (18.0 mmol/L) and ferritin (241.0 ng/mL). Serum calcium (Ca) was in lower limits at 8.2 mg/dL and phosphorus (P) under normal range 2.3 mg/dL, with a Ca × P product of less than 20. Vitamin 25-OH-D level was also low (21.3 ng/mL) and parathyroid hormone was elevated (17.7 pmol/L). Due to high levels of thyroid-stimulating hormone (TSH) (14.10 μIU/mL) indicative of hypothyroidism, the patient was put on levothyroxine therapy. Blood and urine cultures were sterile, stool culture showed normal flora. Infection control was negative for hepatitis B virus (HBV), hepatitis C virus (HCV), hepatitis A virus (HAV), syphilis, rubella, Ebstein Barr virus (EBV) and toxoplasma.
The CMV DNA was detected in urine and blood and ganciclovir was administered for 21 days. Metabolic control with measurement of organic acids in urine and amino acids in blood and urine was also negative. Abdominal ultrasound evidenced hepatosplenomegaly, heart and brain ultrasonography were normal. Small, grayish papillae and bilateral optic hypoplasia were noted in fundoscopy. Visual and auditory evoked potentials showed absence of waveform (blindness) and conductive hearing loss, respectively. Due to persistent anemia, thrombocytopenia and leukocytosis, a bone marrow aspiration was performed, which excluded leukemia and revealed T and NK cells immunophenotypic disorders. The karyotype was normal. Radiological findings [osteosclerotic elements in X-rays with “bone within bone” appearance (Figure 1), marked sclerosis within the skull base (Figure 2), narrowing of cranial foramina in brain computed tomography (CT) scan] raised the suspicion of osteopetrosis, which was finally confirmed by bone biopsy and molecular diagnostics. The latter revealed a
During hospitalization, the infant remained in good clinical condition and was treated with ganciclovir, ceftazidime due to
Osteopetrosis seems to be related to defects in the acidification process of resorption lacuna, mainly caused by mutations in the
Remarkable in this case, was the biochemical and radiological evidence of rickets, which is a paradoxical complication of osteopetrosis. Despite a positive total body calcium balance, patients with osteopetrosis tend to develop rickets because the dysfunctional osteoclasts are unable to maintain a normal calcium-phosphorus balance in the extracellular fluid [9]. In osteopetrorickets the serum calcium-phosphate product decreases (<30.0 mg2/dL2) so that the mineralization of growing bones is insufficient [4]. The diagnostic radiological findings of rickets superimposed on the osteopetrosis are changes in metaphyses of long bones and in costochondral junctions (rachitic rosary), which was also noticed in our patient, along with the biochemical markers of rickets [4]. Treatment of rickets with calcitriol and calcium supplementation improves the overall condition of these patients and is essential for successful BMT.
At present, hematopoietic stem cell transplantation offers the only chance of cure for malignant infantile osteopetrosis (MIOP), and ideally, it should be performed early, before the irreversible neurologic impairment [7]. Hematopoietic stem cell transplantation (HSCT) using HLA identical donors results in 73.0% 5-year disease-free survival [3]. The purpose of transplantation is to provide hematopoietic stem cells from which normal osteoclasts can differentiate. However, BMT cannot cure patients with osteopetrorickets, as normal osteoclasts cannot resorb the hypomineralized osteoid. Therefore, it is important to diagnose and treat the rickets before BMT [4].
Another therapeutic option is interferon γ-1b, mainly recommended in non infantile osteopetrosis or as a bridge to transplantation [3,5]. Hatzipantelis
Malignant infantile osteopetrosis is a rare hereditary skeletal disease, in some cases complicated by rickets. As high clinical suspicion is required for diagnosis, MIOP should be kept in mind as a rare cause of pancytopenia and hepatosplenomegaly. Some cases of successful bone marrow transplantation in patients with infantile osteopetrosis exist in the literature, and a similar case of MIOP with coexistent CMV infection has been reported by Lee