Gaucher disease (GD) encompasses a spectrum of clinical findings from a perinatal-lethal form to an asymptomatic form. However, for the purposes of determining prognosis and management, the classification of GD by clinical type is still useful in describing the wide range of clinical findings and broad variability in presentation. Three major clinical types are delineated by the absence (type 1) or presence (types 2 and 3) of primary central nervous system (CNS) involvement (see Table 1).
Type 1 GD
Bone disease. Clinical or radiographic evidence of bone disease occurs in 70%-100% of individuals with type 1 GD. Bone disease ranges from asymptomatic osteopenia to focal lytic or sclerotic lesions and osteonecrosis [Hughes et al 2019]. Bone involvement, which may lead to acute or chronic bone pain, pathologic fractures, and subchondral joint collapse with secondary degenerative arthritis, is often the most debilitating aspect of type 1 GD.
Acute bone pain manifests as "bone crises" or episodes of deep bone pain that are usually confined to one extremity or joint [Andrade-Campos et al 2018] and are often accompanied by fever, leukocytosis, and sterile blood culture. The affected region may be swollen and warm to touch; imaging studies may reveal signal abnormalities consistent with localized edema or hemorrhage; radiographs may show periosteal elevation ("pseudo-osteomyelitis").
Conventional radiographs may reveal undertubulation (Erlenmeyer flask configuration) in the distal femur and endosteal scalloping as a sign of bone marrow infiltration. MRI reveals the extent of marrow involvement and the presence of fibrosis and/or infarction. In general, marrow infiltration extends from the axial to the appendicular skeleton, and greater involvement is often seen in the lower extremities and proximal sites of an affected bone. The epiphyses are usually spared, except in advanced disease. Bone densitometry studies enable quantitative assessment of the degree of osteopenia.
Bone disease in GD may not correlate with the severity of hematologic or visceral problems.
Secondary neurologic disease. Although individuals with type 1 GD do not have primary CNS disease, neurologic complications (spinal cord or nerve root compression) may occur secondary to bone disease (e.g., severe osteoporosis with vertebral compression; emboli following long bone fracture) or coagulopathy (e.g., hematomyelia) [Pastores et al 2003].
Peripheral neuropathy has been described in individuals with type 1 GD, when testing is performed; however, in most individuals this is a subclinical finding [Andréasson et al 2019]. Among symptomatic individuals, assessments should be undertaken to assess for an alternative explanation (e.g., vitamin B12 deficiency).
Splenic manifestations. The spleen size is enlarged to 1,500-3,000 cc in adults with GD, compared to a normal adult spleen size of 50-200 cc. Infarction of the spleen can result in acute abdominal pain. Rarely, acute surgical emergencies may arise because of splenic rupture [Stone et al 2000b].
Liver manifestations. Hepatomegaly is common, although cirrhosis and hepatic failure are rare [Ayto et al 2010].
Cytopenias are almost universal in untreated individuals with GD. Anemia, thrombocytopenia, and leukopenia may be present simultaneously or independently [Linari & Castaman 2016, Linari & Castaman 2022]. The pattern of cytopenia in GD is dependent on spleen status. Hypersplenism is associated with pancytopenia (i.e., anemia, leukopenia, and thrombocytopenia).
Thrombocytopenia may result from hypersplenism, splenic pooling of platelets, or marrow infiltration or infarction. Immune thrombocytopenia has also been reported and should be excluded in individuals with persistent thrombocytopenia despite GD-specific therapy. Thrombocytopenia may be associated with easy bruising or overt bleeding, particularly with trauma, surgery, or pregnancy. The risk for bleeding may be increased in the presence of clotting abnormalities.
Anemia may result from hypersplenism, hemodilution (e.g., pregnancy), iron deficiency, vitamin B12 deficiency, and, in advanced disease, decreased erythropoiesis as a result of bone marrow failure from Gaucher cell infiltration or medullary infarction.
Leukopenia is rarely severe enough to require intervention. Deficient neutrophil function has been reported.
Coagulation abnormalities. Acquired coagulation factor deficiencies include low-grade disseminated intravascular coagulation and specific inherited coagulation factor deficiencies (e.g., factor XI deficiency among Ashkenazi Jews). An investigation of Egyptian individuals with type 1 GD revealed a wide variety of coagulation factor abnormalities (fibrinogen, factors II, VII, VIII, X, and XII) [Deghady et al 2006]. Abnormal platelet aggregation may contribute to bleeding diathesis in the presence of normal platelet counts [Linari & Castaman 2016].
Cholelithiasis occurs in a significant proportion of adults with GD. In a cohort of 417 affected individuals, the prevalence of gallstones was 32%, and they were more common in women with GD. Those with gallstones were more likely to be asplenic and older; they were also more likely to have higher low-density lipoprotein concentrations, more severe GD, family history of gallstones, and higher body mass index values than those without gallstones [Taddei et al 2010, Zimmermann et al 2016].
Pulmonary involvement. Lung disease in individuals with type 1 GD is infrequent, and mainly observed among historical cases (i.e., individuals subjected to splenectomy) [Ramaswami et al 2021]. The following findings have been observed:
Interstitial lung disease
Alveolar/lobar consolidation
Pulmonary arterial hypertension (PAH) is well documented in individuals with liver disease and is presumably the result of inability to detoxify gut-derived factors, which somehow adversely affect the pulmonary endothelium with resultant pulmonary hypertension. PAH can also occur in individuals with GD without liver disease, although in most individuals it is not clinically significant and is not progressive [
Mistry et al 2002]. In a study of 14 individuals with PAH, median age at GD diagnosis was 36 years (range: 22-63). There was a female preponderance (ratio of 5:2), and all individuals in this report had undergone splenectomy (median age: 12 years) [
Lo et al 2011].
Dyspnea and cyanosis with digital clubbing attributed to hepatopulmonary syndrome have been described in individuals with liver dysfunction; this is often caused by an intercurrent disease (e.g., viral hepatitis).
Note: Individuals with type 1 GD without evidence of pulmonary involvement who limit physical exertion because of easy fatigability may have impaired circulation [Miller et al 2003].
Pregnancy and childbirth. Except in women with significant PAH, pregnancy is not contraindicated in GD (see Pregnancy Management).
In some women the diagnosis of GD is first identified during pregnancy due to exacerbation of hematologic features.
Malignancy. Individuals with GD have an increased risk of multiple myeloma [Sudul et al 2023]. The increased risk for multiple myeloma has been attributed to chronic immune dysregulation secondary to antigenic properties of the incompletely metabolized substrate [Nair et al 2018].
Epidemiologic studies have also suggested an elevated risk of additional malignancies including hepatocellular carcinoma [de Fost et al 2006], non-Hodgkin lymphoma, malignant melanoma, and pancreatic cancer [Landgren et al 2007]. However, subsequent studies have failed to identify an increased risk of these additional malignancies [Cox et al 2015b].
Immunologic abnormalities. Children and adults with GD may have polyclonal gammopathy [Wine et al 2007]. An increased incidence of monoclonal gammopathy has been reported in adults [Brautbar et al 2004].
Psychological complications. Persons with GD exhibit moderate-to-severe psychological complications including somatic concerns and depressed mood [Packman et al 2006].
Parkinsonian features have been reported in a few individuals with type 1 GD and individuals heterozygous for a GBA1 pathogenic variant. The following findings suggest that pathogenic variants in GBA1 and/or alterations in glucosylceramide metabolism may be a risk factor for parkinsonism [Sidransky 2005]. Among those who developed PD, individuals with GD had a younger age at onset of PD than GBA1 heterozygotes (mean: 54.2 vs 65.2 years, respectively; P=0.003). Estimated age-specific risk for PD at age 60 and 80 years was 4.7% and 9.1%, respectively, among individuals with GD. The risk for PD was higher in individuals with GD than non-carriers (P=0.008, log-rank test) and in GBA1 heterozygotes than non-carriers (P=0.03, log-rank test), but it did not reach statistical significance between individuals with GD and GBA1 heterozygotes (P=0.07, log-rank test) [Alcalay et al 2014].
Additional genetic risk factors may contribute to the risk of PD in those with type 1 GD. A recent study found that non-GBA1 variants included in the PD genetic risk score were more frequent in individuals with type 1 GD who developed PD [Blauwendraat et al 2023].
Metabolic abnormalities. Serum concentrations of angiotensin-converting enzyme, tartrate-resistant acid phosphatase, ferritin, chitotriosidase, PARC/CCL18, and lyso-Gb1 (glucosylsphingosine) are usually elevated. Serum concentrations of total and high-density lipoprotein cholesterol are often low.
Type 2 GD / Type 3 GD (Primary Neurologic Disease)
Neurologic disease. Previously, affected individuals were classified into type 2 or type 3 GD based on the age of onset of neurologic signs and symptoms and the rate of disease progression. Children with onset before age two years with a rapidly progressive course, limited psychomotor development, and death by age two to four years were classified as having type 2 GD. Individuals with type 3 GD may have onset before age two years but often have a more slowly progressive course, with life span extending into the third or fourth decade in some individuals. However, these distinctions are not absolute, and it is increasingly recognized that neuropathic GD represents a phenotypic continuum, ranging from abnormalities of horizontal ocular saccades at the mild end to hydrops fetalis at the severe end [Daykin et al 2021].
Bulbar signs (i.e., stridor, squint, and swallowing difficulty) and pyramidal signs (i.e., opisthotonos, head retroflexion, spasticity, and trismus) in infancy are characteristic of type 2 GD.
Oculomotor apraxia, saccadic initiation failure, and opticokinetic nystagmus are common in type 3 GD [Nagappa et al 2015]. Oculomotor involvement may be found as an isolated sign of neurologic disease in individuals with a chronic progressive course and severe systemic involvement (e.g., massive hepatosplenomegaly).
Generalized tonic-clonic seizures and progressive myoclonic epilepsy have been observed in some individuals [Roshan Lal & Sidransky 2017]. In a study of 122 affected individuals, seizures and myoclonic seizures were reported in 19 (16%) and three (2%) persons, respectively [Tylki-Szymańska et al 2010].
Dementia and ataxia have been observed in the later stages of chronic neurologic disease.
Brain stem auditory evoked response (BAER) testing may reveal abnormal wave forms (III and IV) [Okubo et al 2014]. MRI of the brain may show mild cerebral atrophy. (A normal EEG, BAER, or brain MRI does not exclude neurologic involvement.)
