In the last two decades, the development of high-throughput diagnostic methods and the availability of effective treatments have increased the interest in newborn screening for lysosomal storage disorders. However, long-term follow-up experience is needed to clearly identify risks, benefits and challenges. We report our 8-year experience of screening and follow-up on about 250,000 neonates screened for four lysosomal storage diseases (Pompe disease, mucopolysaccharidosis type I, Fabry disease, Gaucher disease), using the enzyme activity assay by tandem mass spectrometry, and biomarker quantification as a second-tier test. Among the 126 positive newborns (0.051%), 51 infants were confirmed as affected (positive predictive value 40%), with an overall incidence of 1:4874. Of these, three patients with infantile-onset Pompe disease, two with neonatal-onset Gaucher disease and four with mucopolysaccharidosis type I were immediately treated. Furthermore, another four Gaucher disease patients needed treatment in the first years of life. Our study demonstrates the feasibility and effectiveness of newborn screening for lysosomal storage diseases. Early diagnosis and treatment allow the achievement of better patient outcomes. Challenges such as false-positive rates, the diagnosis of variants of uncertain significance or late-onset forms and the lack of treatment for neuronopathic forms, should be addressed.
Abstract Gaucher disease is the most common of the lysosomal storage diseases. It presents a wide phenotypic continuum, in which one may identify the classically described phenotypes, including type 1 form with visceral involvement, type 2 acute neuropathic early‐infantile form, and type 3 subacute neuronopathic form. At the most severe end there is the perinatal form with onset in utero or during the neonatal period. The very few reported cases of neonatal onset Gaucher disease presented high and early mortality, due to neurological or visceral involvement, including liver failure. We report our experience treating a patient with the neonatal form of Gaucher disease who presented at birth with thrombocytopenia, hepatosplenomegaly and cholestasis. Despite early enzyme replacement therapy, liver disease was progressive. Liver biopsy showed hepatocellular giant‐cell transformation, a nonspecific finding consistent with inflammation. The lack of response to enzyme replacement therapy and the microscopic findings suggested that mechanisms apart from substrate accumulation and Gaucher cells may play a role in the hepatic pathogenesis in Gaucher disease. An attempt to use corticosteroids at the age of 3 months resulted in a dramatic improvement in liver function and resulted in long‐term survival. The patient is alive and 2 years old at this writing. Our case suggests that inflammatory processes may be important in the early pathogenesis of Gaucher disease and that early use of corticosteroids may open the way to a new therapeutic approach.
Acid sphingomyelinase deficiency (ASMD) is a rare lysosomal storage disorder with a broad clinical spectrum. Early diagnosis and initiation of treatment are crucial for improving outcomes, yet the disease often goes undiagnosed due to its rarity and phenotypic heterogeneity. This study aims to evaluate the feasibility and disease incidence of newborn screening (NBS) for ASMD in Italy. Dried blood spot samples from 275,011 newborns were collected between 2015 and 2024 at the Regional Center for Expanded NBS in Padua. Acid sphingomyelinase activity was assayed using tandem mass spectrometry. Deidentified samples with reduced enzyme activity underwent second-tier testing with LysoSM quantification and SMPD1 gene analysis. Two samples were identified with reduced sphingomyelinase activity and elevated LysoSM levels. Both carried two SMPD1 variants, suggesting a diagnosis of ASMD. Molecular findings included novel and previously reported variants, some of uncertain significance. The overall incidence was 1 in 137,506 newborns and the PPV was 100%. This study demonstrates the feasibility of NBS for ASMD in Italy and provides evidence of a higher disease incidence than clinically reported, suggesting ASMD is an underdiagnosed condition. Optimized screening algorithms and second-tier biomarker testing can enhance the accuracy of NBS for ASMD. The long-term follow-up of identified cases is necessary for genotype–phenotype correlation and improving patient management.
The standard treatment for phenylketonuria (PKU) is a lifelong low-phenylalanine (Phe) diet, supplemented with Phe-free protein substitutes; however, adult patients often show poor adherence to therapy. Alternative treatment options include the use of large neutral amino acids (LNAA). The aim of this study was to determine the Phe, tyrosine (Tyr), and Phe/Tyr ratio in a cohort of sub-optimally controlled adult patients with classical PKU treated with a new LNAA formulation. Twelve patients received a Phe-restricted diet plus a slow-release LNAA product taken three times per day, at a dose of 1 g/kg body weight (mean 0.8 ± 0.24 g/kg/day), over a 12-month period. The product is in a microgranulated formulation, which incorporates all amino acids and uses sodium alginate as a hydrophilic carrier to prolong its release. This LNAA formulation provides up to 80% of the total protein requirement, with the rest of the protein supplied by natural food. Patients had fortnightly measurements of Phe and Tyr levels over a 12-month period after the introduction of LNAA. All patients completed the 12-month treatment period. Overall, adherence to the new LNAA tablets was very good compared with a previous amino acid mixture, for which taste was a major complaint by patients. Phe levels remained unchanged (p = 0.0522), and Tyr levels increased (p = 0.0195). Consequently, the Phe/Tyr ratio decreased significantly (p < 0.05) in the majority of patients treated. In conclusion, LNAA treatment increases Tyr levels in sub-optimally controlled adult PKU patients, while offering the potential to improve their adherence to treatment.
Abstract Objectives Carbamoyl phosphate synthetase 1 (CPS1) deficiency is a severe urea cycle disorder. Patients can present with hyperammonemic coma in the first days of life. Treatment includes nitrogen scavengers, reduced protein intake and supplementation with L-arginine and/or L-citrulline. N-carbamoyl glutamate (NCG) has been hypothesized to stimulate the residual CPS1 function, although only few patients are reported. Case presentation We report a patient with neonatal-onset CPS1 deficiency who received NCG in association with nitrogen scavenger and L-citrulline. The patient carried the novel variants CPS1 -c.2447A>G p.(Gln816Arg) and CPS1 -c.4489T>C p.(Tyr1497His). The latter is localized in the C-terminal allosteric domain of the protein, and is implicated in the binding of the natural activator N-acetyl-L-glutamate. NCG therapy was effective in controlling ammonia levels, allowing to increase the protein intake. Conclusions Our data show that the response to NCG can be indicated based on the protein structure. We hypothesize that variants in the C-terminal domain may be responsive to NCG therapy.
Background: In 2011, a European phenylketonuria (PKU) survey reported that the blood phenylalanine (Phe) levels were well controlled in early life but deteriorated with age. Other studies have shown similar results across the globe. Different target blood Phe levels have been used throughout the years, and, in 2017, the European PKU guidelines defined new targets for blood Phe levels. This study aimed to evaluate blood Phe control in patients with PKU across Europe. Methods: nine centres managing PKU in Europe and Turkey participated. Data were collected retrospectively from medical and dietetic records between 2012 and 2018 on blood Phe levels, PKU severity, and medications. Results: A total of 1323 patients (age range:1–57, 51% male) participated. Patient numbers ranged from 59 to 320 in each centre. The most common phenotype was classical PKU (n = 625, 48%), followed by mild PKU (n = 357, 27%) and hyperphenylalaninemia (HPA) (n = 325, 25%). The mean percentage of blood Phe levels within the target range ranged from 65 ± 54% to 88 ± 49% for all centres. The percentage of Phe levels within the target range declined with increasing age (<2 years: 89%; 2–5 years: 84%; 6–12 years: 73%; 13–18 years: 85%; 19–30 years: 64%; 31–40 years: 59%; and ≥41 years: 40%). The mean blood Phe levels were significantly lower and the percentage within the target range was significantly higher (p < 0.001) in patients with HPA (290 ± 325 μmol/L; 96 ± 24%) and mild PKU (365 ± 224 μmol/L; 77 ± 36%) compared to classical PKU (458 ± 350 μmol/L, 54 ± 46%). There was no difference between males and females in the mean blood Phe levels (p = 0.939), but the percentage of Phe levels within the target range was higher in females among school-age children (6–12 years; 83% in females vs. 78% in males; p = 0.005), adolescents (13–18 years; 62% in females vs. 59% in males; p = 0.034) and adults (31–40 years; 65% in females vs. 41% in males; p < 0.001 and >41 years; 43% in females vs. 28% in males; p < 0.001). Patients treated with sapropterin (n = 222) had statistically significantly lower Phe levels compared to diet-only-treated patients (mean 391 ± 334 μmol/L; percentage within target 84 ± 39% vs. 406 ± 334 μmol/L; 73 ± 41%; p < 0.001), although a blood Phe mean difference of 15 µmol/L may not be clinically relevant. An increased frequency of blood Phe monitoring was associated with better metabolic control (p < 0.05). The mean blood Phe (% Phe levels within target) from blood Phe samples collected weekly was 271 ± 204 μmol/L, (81 ± 33%); for once every 2 weeks, it was 376 ± 262 μmol/L, (78 ± 42%); for once every 4 weeks, it was 426 ± 282 μmol/L, (71 ± 50%); and less than monthly samples, it was 534 ± 468 μmol/L, (70 ± 58%). Conclusions: Overall, blood Phe control deteriorated with age. A higher frequency of blood sampling was associated with better blood Phe control with less variability. The severity of PKU and the available treatments and resources may impact the blood Phe control achieved by each treatment centre.
In the last few decades, neonatal screening (NBS) has expanded to include lysosomal storage diseases, allowing for the early identification of both symptomatic and asymptomatic cases. However, neonatal diagnosis of late-onset disorders can cause parental stress and affect family well-being, possibly leading to overmedicalization. The impact of a positive NBS for Gaucher disease type 1 (GD1) can have an important impact on parental psychological well-being and psychosocial functioning. This study aims to study parental stress in parents of newborns who had a positive result for Gaucher disease in an NBS program in Northeastern Italy. Fourteen parents (7 fathers and 7 mothers) of seven children with confirmed GD1 (86% boys) completed the Parenting Stress Index-Short Form (PSI-SF) at diagnosis (T0), 12 months (T1), and 36 months (T2). A control group of fourteen parents (7 fathers and 7 mothers) whose children had normal NBS results was included. Interviews were conducted for the GD1 group at T2 to investigate the usefulness of the NBS program. At T0, higher parental stress was assessed in GD1 parents compared to the healthy controls. Subsequently, the parents of GD1 children reported significant reductions in Parental Distress at T1 compared to T0. Mothers showed further reductions at T2, while the fathers' distress decreased but not significantly. GD1 mothers had significantly higher distress scores than the controls at T1, but this difference diminished over time. Our study highlights the psychological impact of NBS on GD1, emphasizing the need for better multidisciplinary communication to reduce parental stress throughout the diagnostic and treatment process.
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