Niemann-Pick Disease Type B

Niemann–Pick Disease Type B (Chronic Visceral ASMD): Disease Characteristics Research Report

2026-06-13
Falcon MONDO:0011871 Model: Edison Scientific Literature 62 citations

Niemann–Pick Disease Type B (Chronic Visceral ASMD): Disease Characteristics Research Report

Executive summary (current understanding)

Niemann–Pick disease type B is the chronic visceral (non–CNS-predominant) phenotype within acid sphingomyelinase deficiency (ASMD), an autosomal recessive lysosomal storage disease caused by biallelic pathogenic variants in SMPD1 encoding lysosomal acid sphingomyelinase (ASM; EC 3.1.4.12). ASM deficiency leads to progressive lysosomal sphingomyelin accumulation and multisystem disease dominated by splenomegaly/hepatomegaly, cytopenias (esp. thrombocytopenia), interstitial lung disease (ILD) with reduced diffusion capacity, and atherogenic dyslipidemia. The treatment landscape changed with approval and real-world implementation of olipudase alfa (recombinant human ASM; Xenpozyme®) for non-CNS manifestations, with large sustained improvements in organomegaly and lung function in adults and children in trials and extensions. (mcgovern2021prospectivestudyof pages 1-2, geberhiwot2023consensusclinicalmanagement pages 1-2, lipinski2024chronicacidsphingomyelinase pages 1-2, wasserstein2023continuedimprovementin pages 1-2)


| Preferred name | Key synonyms | Causal gene | Inheritance | OMIM IDs mentioned in evidence | MONDO ID in retrieved evidence | Key references (year; DOI/URL) |

|---|---|---|---|---|---|---| | Niemann-Pick disease type B; chronic visceral acid sphingomyelinase deficiency (ASMD) (lipinski2024chronicacidsphingomyelinase pages 1-2, lipinski2019chronicvisceralacid pages 1-2) | Acid sphingomyelinase deficiency type B; ASMD type B; chronic visceral ASMD; NPD type B; Niemann–Pick disease type B (mcgovern2021prospectivestudyof pages 1-2, geberhiwot2023consensusclinicalmanagement pages 1-2, pulikottiljacob2023healthcareserviceuse pages 1-2, mauhin2024acidsphingomyelinasedeficiency pages 1-2, lipinski2019chronicvisceralacid pages 1-2) | SMPD1 / sphingomyelin phosphodiesterase 1 (mengel2024aretrospectivestudy pages 1-2, geberhiwot2023consensusclinicalmanagement pages 1-2, lipinski2024chronicacidsphingomyelinase pages 1-2, pulikottiljacob2023healthcareserviceuse pages 1-2, mauhin2024acidsphingomyelinasedeficiency pages 1-2) | Autosomal recessive (geberhiwot2023consensusclinicalmanagement pages 1-2, lipinski2024chronicacidsphingomyelinase pages 1-2, pulikottiljacob2023healthcareserviceuse pages 1-2, mauhin2024acidsphingomyelinasedeficiency pages 1-2) | Disease OMIM: 607616 for NPD type B / chronic visceral ASMD; related disease OMIM: 257200 for type A; gene MIM/OMIM: 607608 for SMPD1 (geberhiwot2023consensusclinicalmanagement pages 1-2, lipinski2024chronicacidsphingomyelinase pages 1-2, lipinski2019chronicvisceralacid pages 1-2) | MONDO_0100464 for acid sphingomyelinase deficiency; disease-target evidence links SMPD1 to ASMD (OpenTargets Search: acid sphingomyelinase deficiency,Niemann-Pick disease type B-SMPD1) | Geberhiwot et al. 2023, doi:10.1186/s13023-023-02686-6, https://doi.org/10.1186/s13023-023-02686-6 (geberhiwot2023consensusclinicalmanagement pages 1-2); Lipiński et al. 2024, doi:10.17219/acem/193696, https://doi.org/10.17219/acem/193696 (lipinski2024chronicacidsphingomyelinase pages 1-2); Lipiński et al. 2019, doi:10.1186/s13023-019-1029-1, https://doi.org/10.1186/s13023-019-1029-1 (lipinski2019chronicvisceralacid pages 1-2); McGovern et al. 2021, doi:10.1186/s13023-021-01842-0, https://doi.org/10.1186/s13023-021-01842-0 (mcgovern2021prospectivestudyof pages 1-2); Mauhin et al. 2024, doi:10.1186/s13023-024-03234-6, https://doi.org/10.1186/s13023-024-03234-6 (mauhin2024acidsphingomyelinasedeficiency pages 1-2) |

Table: This table summarizes the core disease naming, synonyms, genetic basis, inheritance, and identifiers for Niemann-Pick disease type B/chronic visceral ASMD using only retrieved evidence. It is useful as a compact normalization reference for a disease knowledge base entry.


1. Disease information

1.1 What is the disease?

ASMD is a spectrum of disorders historically called Niemann–Pick disease types A and B. Type B corresponds to chronic visceral ASMD (NPD type B) and typically lacks overt neurodegeneration compared with infantile neurovisceral ASMD (type A). (mcgovern2021prospectivestudyof pages 1-2, lipinski2024chronicacidsphingomyelinase pages 1-2, lipinski2019chronicvisceralacid pages 1-2)

Direct abstract quote (definition): “Acid sphingomyelinase deficiency (ASMD)… is a rare and debilitating lysosomal storage disorder.” (mcgovern2021prospectivestudyof pages 1-2)

1.2 Key identifiers (availability in retrieved sources)

1.3 Synonyms/alternative names

Commonly used synonyms include ASMD type B, chronic visceral ASMD, and Niemann–Pick disease type B. (mcgovern2021prospectivestudyof pages 1-2, geberhiwot2023consensusclinicalmanagement pages 1-2, pulikottiljacob2023healthcareserviceuse pages 1-2, lipinski2019chronicvisceralacid pages 1-2)

1.4 Evidence source type

This report is derived from aggregated disease-level resources and cohort/trial studies (guidelines, prospective natural history cohort, retrospective national cohorts, clinical trials, and newborn screening studies). (mcgovern2021prospectivestudyof pages 1-2, geberhiwot2023consensusclinicalmanagement pages 1-2, mauhin2024acidsphingomyelinasedeficiency pages 1-2, wasserstein2023continuedimprovementin pages 1-2, gragnaniello2024newbornscreeningfor pages 1-2)


2. Etiology

2.1 Disease causal factors

2.2 Risk factors

No strong environmental “risk factors” for disease onset apply in the Mendelian sense; however, clinical burden is shaped by organ complications (lung infections, liver disease), which function as risk modifiers for morbidity and mortality. (mcgovern2021prospectivestudyof pages 1-2, geberhiwot2023consensusclinicalmanagement pages 20-21)

2.3 Protective factors

Not established in retrieved clinical evidence. (No relevant evidence in retrieved sources)

2.4 Gene–environment interactions

Not established in retrieved clinical evidence. (No relevant evidence in retrieved sources)


3. Phenotypes (clinical features)

3.1 Core phenotype set for chronic visceral ASMD (type B)

A standard clinical definition for chronic visceral ASMD includes hepatosplenomegaly, thrombocytopenia, ILD, and dyslipidemia. (mcgovern2021prospectivestudyof pages 1-2)

Direct quote (phenotype definition): “Chronic visceral ASMD (ASMD type B, NPD type B) is characterized by hepatosplenomegaly, thrombocytopenia, interstitial lung disease, and dyslipidemia…” (mcgovern2021prospectivestudyof pages 1-2)

Recent pediatric cohort features (Poland, 2024 update): splenomegaly in all patients (7/7), mild liver enlargement in 4/7, decreased HDL-C in all, hypercholesterolemia in 6/7, and elevated lyso-sphingomyelin in DBS in all screened. (lipinski2024chronicacidsphingomyelinase pages 1-2)

3.2 Frequencies and quantitative phenotyping from cohorts

Prospective multinational natural history cohort (n=59; chronic ASMD types B and A/B): * Interstitial lung disease: 66% (39/59) baseline, 78% (25/32) at final visit (4.5–11 years) (mcgovern2021prospectivestudyof pages 1-2) * Splenomegaly: spleen volumes 4–29 multiples of normal; moderate/severe splenomegaly in 86% baseline (mcgovern2021prospectivestudyof pages 1-2) * Mortality: 9/59 deaths (15%) during follow-up; 8 ASMD-related (most commonly pneumonia) (mcgovern2021prospectivestudyof pages 1-2)

Poland type B long-term cohort (n=16): * Splenomegaly: 100% at diagnosis * Hepatomegaly: 88% * Dyslipidemia: 50% * ILD: 44% * Elevated transaminases: 38% * Biomarkers: plasmatic lysosphingomyelin (SPC) elevated in all but one very mild case; SPC-509 used with SPC for course assessment (lipinski2019chronicvisceralacid pages 1-2)

Germany chronic ASMD chart cohort (n=33): * Spleen manifestations 100.0%, liver 93.9%, respiratory 77.4% (mengel2024aretrospectivestudy pages 1-2)

3.3 Phenotype characteristics: onset, progression, severity

Type B onset ranges from infancy through adulthood with gradual progression of visceral disease and limited neurologic involvement. (mengel2024aretrospectivestudy pages 1-2)

Direct quote (type B course): “Patients with ASMD type B show symptom onset from infancy to adulthood, with gradual progression of visceral manifestations without significant neurodegeneration…” (mengel2024aretrospectivestudy pages 1-2)

3.4 Quality-of-life (QoL) impacts

Guidelines and observational summaries emphasize substantial burden including respiratory symptoms, fatigue, pain, and psychosocial impacts; quantitative QoL evidence is limited. (mcgovern2017diseasemanifestationsand pages 1-2, geberhiwot2023consensusclinicalmanagement pages 8-9)

3.5 Suggested HPO terms (non-exhaustive)


4. Genetic / molecular information

4.1 Causal gene(s)

4.2 Pathogenic variant classes

Across a recent pediatric cohort, missense variants were the most common lesion type (71% of alleles) in one national series (Poland). (lipinski2024chronicacidsphingomyelinase pages 1-2)

4.3 Functional consequence

Primary mechanism is loss of enzymatic activity of ASM (variable residual activity across phenotypes), producing lysosomal sphingomyelin storage. (mcgovern2021prospectivestudyof pages 1-2, mauhin2024acidsphingomyelinasedeficiency pages 1-2)

4.4 Modifier genes / epigenetics

Not established in retrieved clinical evidence for ASMD type B. (No relevant evidence in retrieved sources)


5. Environmental information

No validated environmental or lifestyle determinants for disease onset are established for this Mendelian disorder in retrieved sources. Management does include prevention/mitigation of secondary complications (e.g., respiratory infections) via vaccination and clinical monitoring. (geberhiwot2023consensusclinicalmanagement pages 20-21)


6. Mechanism / pathophysiology

6.1 Causal chain (trigger → cellular pathway → tissue injury → clinical manifestations)

  1. Trigger (upstream): biallelic pathogenic SMPD1 variants → reduced lysosomal ASM activity. (mauhin2024acidsphingomyelinasedeficiency pages 1-2)
  2. Biochemical defect: impaired hydrolysis of sphingomyelin → ceramide + phosphocholine; progressive accumulation of sphingomyelin and other lipids in lysosomes of multiple tissues including spleen, liver, lungs, bone marrow. (mengel2024aretrospectivestudy pages 1-2)
  3. Cellular pathology: storage-laden macrophages (“foam cells” / Niemann–Pick cells) and tissue infiltration drive organomegaly and inflammation; lung disease manifests as ILD with diffusion impairment. (mcgovern2017diseasemanifestationsand pages 1-2, mcgovern2021prospectivestudyof pages 1-2)
  4. Organ injury (downstream): hepatosplenic enlargement with cytopenias (hypersplenism), progressive liver fibrosis/cirrhosis in some, ILD with reduced DLCO and risk for infections/respiratory failure, and dyslipidemia with cardiovascular risk. (mcgovern2021prospectivestudyof pages 1-2, geberhiwot2023consensusclinicalmanagement pages 20-21, geberhiwot2023consensusclinicalmanagement pages 8-9)

6.2 Key pathways and processes (ontology suggestions)

GO biological process (suggestions): * Lysosomal lipid catabolic process (e.g., GO:0044255 lipid catabolic process; lysosome-associated lipid catabolism) * Sphingomyelin catabolic process (ASM-mediated) * Ceramide biosynthetic process * Macrophage activation / inflammatory response

GO cellular component (suggestions): * Lysosome * Lysosomal lumen

Cell Ontology (CL) (suggestions): * Macrophage CL:0000235 (storage macrophages) * Alveolar macrophage CL:0000583 * Hepatocyte CL:0000182

Key CHEBI entities (suggestions): * Sphingomyelin * Ceramide

These ontology mappings are mechanistically consistent with ASM deficiency and lysosomal sphingomyelin storage described in cohort and guideline sources. (mengel2024aretrospectivestudy pages 1-2, mcgovern2021prospectivestudyof pages 1-2)


7. Anatomical structures affected

7.1 Organ level (primary)

UBERON suggestions: spleen (UBERON:0002106), liver (UBERON:0002107), lung (UBERON:0002048)

7.2 Tissue/cell level

Storage-laden macrophages in reticuloendothelial organs and the lung are central to pathology (CL: macrophage, alveolar macrophage). (mcgovern2017diseasemanifestationsand pages 1-2, mcgovern2021prospectivestudyof pages 1-2)

7.3 Subcellular level

Lysosomal storage (GO cellular component: lysosome). (mcgovern2021prospectivestudyof pages 1-2)


8. Temporal development

8.1 Onset

Type B: symptom onset from infancy to adulthood. (mengel2024aretrospectivestudy pages 1-2)

8.2 Progression

Slowly progressive multisystem disease; longitudinal worsening seen in splenomegaly, hepatomegaly, ILD/DLCO, and dyslipidemia. (mcgovern2021prospectivestudyof pages 1-2)


9. Inheritance and population

9.1 Inheritance

Autosomal recessive. (geberhiwot2023consensusclinicalmanagement pages 1-2, mauhin2024acidsphingomyelinasedeficiency pages 1-2)

9.2 Epidemiology and survival (recent 2024 studies emphasized)

France (retrospective survival study; 2024, Orphanet J Rare Dis): * Type B median age at diagnosis: 5.5 years (range 0–73) * Type B deaths: 10/94 (10.6%); median age at death 57.6 years (range 3.4–74.1) * Type B SMR: 3.5 (95% CI 1.6–5.9) (mauhin2024acidsphingomyelinasedeficiency pages 3-5, mauhin2024acidsphingomyelinasedeficiency pages 1-2)

Germany (retrospective cohort; 2024, Orphanet J Rare Dis): * Median age at diagnosis (type B): 8.0 years (IQR 3.0–20.0) * SMR (chronic ASMD overall): 21.6 (95% CI 9.8–38.0) * Median overall survival since birth: 45.4 years (95% CI 17.5–65.0) * Type B median age at death (among deaths): 31.0 years (IQR 11.0–55.0) * Organ involvement in cohort: spleen 100.0%, liver 93.9%, respiratory 77.4% (mengel2024aretrospectivestudy pages 1-2)

Prospective natural history (multinational; 2021): 15% mortality over 4.5–11 years, and severe splenomegaly/splenectomy strongly associated with death (OR 10.29). (mcgovern2021prospectivestudyof pages 1-2)


| Category | Study (year) | Population (n; type) | Design | Key quantitative findings | DOI/URL |

|---|---|---|---|---|---| | Epidemiology / natural history | McGovern et al. (2021) (mcgovern2021prospectivestudyof pages 1-2) | 59 patients; chronic ASMD types A/B and B; age 7-64 y; 31 male/28 female (mcgovern2021prospectivestudyof pages 1-2) | Prospective, multicenter, multinational longitudinal natural history study; follow-up 4.5-11 years (mcgovern2021prospectivestudyof pages 1-2) | ILD in 66% (39/59) at baseline and 78% (25/32) at final visit; spleen volumes 4-29 multiples of normal; moderate/severe splenomegaly in 86% baseline, 83% year 1, 90% final; median % predicted DLCO decreased by >10%; 9/59 deaths (15%), 8 ASMD-related, most commonly pneumonia; severe splenomegaly or prior splenectomy associated with mortality (OR 10.29, 95% CI 1.7-62.7) (mcgovern2021prospectivestudyof pages 1-2) | https://doi.org/10.1186/s13023-021-01842-0 | | Epidemiology / natural history | Mengel et al. (2024) (mengel2024aretrospectivestudy pages 1-2) | 33 chart records; 24 type B, 9 type A/B (mengel2024aretrospectivestudy pages 1-2) | Retrospective multicenter German cohort, 1990-2021 (mengel2024aretrospectivestudy pages 1-2) | Manifestations: spleen 100.0%, liver 93.9%, respiratory 77.4%; median age at diagnosis 8.0 y (IQR 3.0-20.0) for type B and 1.0 y (1.0-2.0) for type A/B; 9 deaths, all ASMD-related; median age at death 31.0 y for type B and 9.0 y for type A/B; median overall survival 45.4 y (95% CI 17.5-65.0); SMR 21.6 (95% CI 9.8-38.0) (mengel2024aretrospectivestudy pages 1-2) | https://doi.org/10.1186/s13023-024-03174-1 | | Epidemiology / natural history | Mauhin et al. (2024) (mauhin2024acidsphingomyelinasedeficiency pages 1-2, mauhin2024acidsphingomyelinasedeficiency pages 3-5) | 118 ASMD records total; 94 type B, 15 type A, 9 type A/B (mauhin2024acidsphingomyelinasedeficiency pages 1-2, mauhin2024acidsphingomyelinasedeficiency pages 3-5) | Retrospective multicenter French survival study, 1990-2020 (mauhin2024acidsphingomyelinasedeficiency pages 1-2, mauhin2024acidsphingomyelinasedeficiency pages 3-5) | For type B: estimated birth prevalence in France ~1/230,000 births; median age at diagnosis 5.5 y (range 0-73); 10/94 deaths (10.6%); median age at death 57.6 y (range 3.4-74.1); SMR 3.5 (95% CI 1.6-5.9); type-B deaths mostly adults; cancer accounted for 5/10 type-B deaths in one detailed breakdown (mauhin2024acidsphingomyelinasedeficiency pages 3-5, mauhin2024acidsphingomyelinasedeficiency pages 1-2) | https://doi.org/10.1186/s13023-024-03234-6 | | Epidemiology / natural history | Pulikottil-Jacob et al. (2023) (pulikottiljacob2023healthcareserviceuse pages 1-2) | 47 patients in primary claims cohort; 59 in sensitivity cohort; ASMD type B/high-probability type B (pulikottiljacob2023healthcareserviceuse pages 1-2) | Retrospective US claims analysis using IQVIA Open Claims, 2010-2019 (pulikottiljacob2023healthcareserviceuse pages 1-2) | 70% of primary cohort aged <18 y; liver, spleen, and lungs were the most frequently affected organs; respiratory/lung disorders drove most ED visits and hospitalizations; demonstrates high healthcare-service use in real-world practice (pulikottiljacob2023healthcareserviceuse pages 1-2) | https://doi.org/10.1007/s12325-023-02453-w | | Olipudase alfa clinical outcomes | Wasserstein et al. (2023) ASCEND open-label extension (wasserstein2023continuedimprovementin pages 1-2, wasserstein2023continuedimprovementin pages 9-11) | 35 adults with chronic ASMD (type B and A/B) continued/crossed over after ASCEND; 33 completed year 2 (wasserstein2023continuedimprovementin pages 1-2, wasserstein2023continuedimprovementin pages 9-11) | Open-label extension of randomized placebo-controlled ASCEND adult trial; NCT02004691 (wasserstein2023continuedimprovementin pages 1-2) | Cross-over group after 1 year: DLCO +28.0 ± 6.2%, spleen volume -36.0 ± 3.0%, liver volume -30.7 ± 2.5%; continuous olipudase alfa for 2 years: DLCO +28.5 ± 6.2%, spleen -47.0 ± 2.7%, liver -33.4 ± 2.2%; lipid profiles and elevated transaminases improved/normalized and remained stable; 99% of TEAEs mild/moderate; one treatment-related serious AE (extrasystoles); no discontinuations due to AEs (wasserstein2023continuedimprovementin pages 1-2, wasserstein2023continuedimprovementin pages 9-11) | https://doi.org/10.1186/s13023-023-02983-0 | | Olipudase alfa clinical outcomes | Diaz et al. (2022) ASCEND-Peds 2-year results (diaz2022longtermsafetyand pages 1-2, diaz2022longtermsafetyand pages 2-4) | 20 pediatric patients; chronic ASMD types B or A/B; 4 adolescents, 9 children, 7 infants/early child (diaz2022longtermsafetyand pages 1-2, diaz2022longtermsafetyand pages 2-4) | Pediatric clinical trial plus long-term continuation; completed ASCEND-Peds (NCT02292654) and continued in NCT02004704 (diaz2022longtermsafetyand pages 1-2, diaz2022longtermsafetyand pages 2-4) | Mean reductions from baseline at 2 years: spleen volume -61%, liver volume -49% (p<0.0001); mean % predicted DLCO +46.6% (p<0.0001) in 9 evaluable patients; mean height Z-score +1.17 (p<0.0001); no discontinuations; 99% of AEs mild/moderate; one patient had 2 treatment-related serious hypersensitivity events that resolved (diaz2022longtermsafetyand pages 1-2, diaz2022longtermsafetyand pages 2-4) | https://doi.org/10.1186/s13023-022-02587-0 | | Olipudase alfa clinical outcomes | Lachmann et al. (2023) long-term adult study (wasserstein2018olipudasealfafor pages 1-2) | 5 adults with chronic ASMD (wasserstein2018olipudasealfafor pages 1-2) | Open-label long-term study; 30-month results from NCT02004704 (wasserstein2018olipudasealfafor pages 1-2) | Liver volume -31%, spleen volume -39%, mean DLCO +35% at 30 months; lipid profiles improved in all patients; no deaths, serious or severe events, or discontinuations; no anti-drug antibodies detected (wasserstein2018olipudasealfafor pages 1-2) | https://doi.org/10.1007/s10545-017-0123-6 | | Olipudase alfa clinical outcomes | Syed (2023) drug profile summarizing ASCEND/ASCEND-Peds (syed2023olipudasealfain pages 4-5) | Adults in ASCEND and pediatric patients in ASCEND-Peds (numbers not restated in excerpt) (syed2023olipudasealfain pages 4-5) | Narrative drug profile/review of trial evidence (syed2023olipudasealfain pages 4-5) | Adults at week 52: 27.7% on olipudase alfa had ≥15% absolute DLCO increase vs 0% placebo; 94.4% had ≥30% spleen-volume reduction vs 0% placebo; FVC +6.76% vs +1.48%; ALT -36.5% vs -0.98%; AST -31.6% vs +2.0%; total bilirubin -29.9% vs +12.5%; anti-atherogenic lipids increased and pro-atherogenic lipids decreased (syed2023olipudasealfain pages 4-5) | https://doi.org/10.1007/s40261-023-01270-x |

Table: This table compiles the main quantitative epidemiology/natural-history studies and the pivotal olipudase alfa outcome studies for chronic ASMD type B/A-B. It is useful for quickly comparing disease burden, survival, and treatment effects across recent authoritative sources.


10. Diagnostics

10.1 Clinical suspicion and differential diagnosis

Guidelines emphasize that hepatosplenomegaly and cytopenias overlap with Gaucher disease and other conditions; clinicians should evaluate concurrent differentials and proceed to ASM enzyme testing when ASMD is suspected. (geberhiwot2023consensusclinicalmanagement pages 8-9, mcgovern2017consensusrecommendationfor pages 3-4)

10.2 Biochemical confirmation: ASM enzyme activity

Consensus diagnostic guideline (Genetics in Medicine, 2017): * First test: ASM enzyme assay; SMPD1 sequencing after biochemical confirmation (mcgovern2017consensusrecommendationfor pages 3-4) * Preferred analytic method: tandem mass spectrometry (MS/MS) over fluorometry due to false negatives in some contexts (e.g., p.Q294K) (mcgovern2017consensusrecommendationfor pages 3-4) * Sample types: leukocytes, cultured fibroblasts, DBS; fibroblasts useful to confirm equivocal results (mcgovern2017consensusrecommendationfor pages 3-4)

Operational cutoffs used in a 2024 cohort study: ASMD diagnosis based on low ASM activity <10% (study inclusion/diagnostic criterion). (mengel2024aretrospectivestudy pages 1-2)

10.3 Biomarkers

Direct quote (first-tier screening proposition): in one pediatric update, “Both acid spingomyelinase activity and lyso-spingomyelin concentration in DBS should be regarded as a first-tier screening method into ASMD.” (lipinski2024chronicacidsphingomyelinase pages 1-2)

10.4 Imaging and functional testing

Natural history and treatment trials use: * High-resolution chest CT (HRCT) for ILD/ground-glass opacities * Pulmonary function tests including DLCO as key endpoints (mcgovern2021prospectivestudyof pages 1-2, wasserstein2023continuedimprovementin pages 1-2)

10.5 Newborn screening / early detection (major 2024 development)

Italy expanded NBS feasibility (Dec 2024; Int J Neonatal Screening): * Screened 275,011 newborns (2015–2024) * First-tier: ASM activity on DBS via MS/MS * Second-tier: LysoSM quantification and SMPD1 sequencing * Incidence 1 in 137,506; PPV 100% reported in the study summary (gragnaniello2024newbornscreeningfor pages 1-2) * Example second-tier cutoff in this program: LysoSM >51.68 nmol/L considered abnormal (gragnaniello2024newbornscreeningfor pages 3-5)


11. Outcome / prognosis

11.1 Mortality and survival (recent statistics)

France and Germany national cohorts (2024) show elevated mortality versus general population (SMR 3.5 in French type B; SMR 21.6 in German chronic ASMD cohort) with cause-of-death patterns including respiratory and liver disease and, in some type B series, cancers. (mauhin2024acidsphingomyelinasedeficiency pages 3-5, mauhin2024acidsphingomyelinasedeficiency pages 1-2, mengel2024aretrospectivestudy pages 1-2)

11.2 Prognostic factors

In an 11-year prospective natural history study, severe splenomegaly or prior splenectomy was associated with markedly higher mortality risk (OR 10.29). (mcgovern2021prospectivestudyof pages 1-2)


12. Treatment

12.1 Disease-modifying therapy: olipudase alfa (Xenpozyme®)

Olipudase alfa is a recombinant human ASM enzyme replacement therapy for non-CNS manifestations of ASMD. (wasserstein2023continuedimprovementin pages 1-2)

Adult evidence (ASCEND + extension)

ASCEND adult open-label extension (Orphanet J Rare Dis, Dec 2023; NCT02004691): * DLCO: +28.0 ± 6.2% (cross-over group after 1 year) and +28.5 ± 6.2% (continuous-treatment group after 2 years) * Spleen volume: −36.0 ± 3.0% (cross-over 1 year), −47.0 ± 2.7% (2 years) * Liver volume: −30.7 ± 2.5% (cross-over 1 year), −33.4 ± 2.2% (2 years) * Safety: 99% TEAEs mild/moderate; 1 treatment-related serious AE (extrasystoles); no discontinuations for AEs (wasserstein2023continuedimprovementin pages 1-2)

Visual evidence from this study (HRCT/organ/lung endpoints) is available in the retrieved table/figures. (wasserstein2023continuedimprovementin media e0b00a30, wasserstein2023continuedimprovementin media 84e619b3, wasserstein2023continuedimprovementin media 3d663125, wasserstein2023continuedimprovementin media 3a33f2b4)

Pediatric evidence (ASCEND-Peds + long-term)

Two-year pediatric outcomes (Orphanet J Rare Dis, Dec 2022; NCT02292654 → NCT02004704): * Mean spleen volume reduction: −61% * Mean liver volume reduction: −49% * Mean % predicted DLCO increase: +46.6% (in 9 evaluable patients) * Growth: mean height Z-score change +1.17 * Safety: 99% AEs mild/moderate; no discontinuations; one patient had two serious hypersensitivity events that resolved (diaz2022longtermsafetyand pages 1-2)

Biomarker response

In adult extension data, baseline plasma lyso-sphingomyelin was markedly elevated (ULN 10 μg/L) and “pre-infusion levels steadily decreased and stabilized after 6 months” on therapy. (wasserstein2023continuedimprovementin pages 6-9)

12.2 Supportive/symptomatic management (guideline-based)

The 2023 international consensus management guidelines stress multidisciplinary care and recommend: * Close monitoring of liver disease; avoid splenectomy where possible due to risk of worsening disease (geberhiwot2023consensusclinicalmanagement pages 20-21) * Vigilance for respiratory infections; encourage vaccination (influenza, COVID-19, pneumococcal) (geberhiwot2023consensusclinicalmanagement pages 20-21) * Hematology evaluation for severe thrombocytopenia/bleeding; management individualized (geberhiwot2023consensusclinicalmanagement pages 20-21)

12.3 Experimental / pipeline therapeutics

Gene therapy approaches are being explored broadly across sphingolipidoses, but no ASMD type B gene therapy clinical outcomes were identified within the retrieved clinical evidence set. (vlad2025fromgenesto pages 19-21)

12.4 MAXO (Medical Action Ontology) suggestions

  • Enzyme replacement therapy (olipudase alfa)
  • Vaccination to prevent respiratory infections
  • Pulmonary function monitoring
  • Management of dyslipidemia
  • Genetic counseling (These are ontology suggestions; specific MAXO IDs not available in retrieved sources.)

13. Prevention

13.1 Primary prevention

Not applicable in the conventional infectious/environmental sense for a Mendelian disorder.

13.2 Secondary prevention (early detection)

13.3 Genetic counseling and reproductive options

Consensus management guidelines explicitly recommend access to a genetic counsellor to discuss recurrence risk and prenatal diagnosis options for families. (geberhiwot2023consensusclinicalmanagement pages 14-15)


14. Other species / natural disease

A naturally occurring SMPD1-associated Niemann–Pick-like disease is reported in cats, including a nonsense SMPD1 mutation in a kitten with neurodegenerative and visceral storage pathology (analogous to human type A). ()


15. Model organisms

15.1 Mouse models

ASM knockout (Smpd1−/−) mice show progressive lipid accumulation (sphingomyelin as principal lipid) in reticuloendothelial organs and brain; these models are used for mechanistic studies and therapeutic testing. (schuchman2007thepathogenesisand pages 2-4, schuchman2017typesaand pages 6-8)

Mutation-specific transgenic mice expressing human SMPD1 mutations (R496L, ΔR608) on an ASMKO background were generated to support evaluation of enzyme enhancement strategies and to model residual activity in specific alleles. (jones2008characterizationofcommon pages 1-2)

15.2 Zebrafish models

Zebrafish smpd1 deficiency has been used as a genetic modifier background in sphingolipidosis models (e.g., psap knockout) to assess survival and mechanistic rescue, supporting SMPD1 as a modifiable node in sphingolipid pathology. (zhang2023azebrafishmodel pages 13-15)


Recent developments (2023–2024 prioritized)

  1. International consensus clinical management guidelines (2023) formalized multidisciplinary monitoring and supportive care standards for ASMD across phenotypes in anticipation of/enabled by ERT availability. (geberhiwot2023consensusclinicalmanagement pages 1-2, geberhiwot2023consensusclinicalmanagement pages 20-21)
  2. National survival and morbidity studies (2024) in France and Germany quantified mortality burden using standardized mortality ratios and age-at-diagnosis distributions for chronic ASMD, including type B. (mauhin2024acidsphingomyelinasedeficiency pages 3-5, mengel2024aretrospectivestudy pages 1-2)
  3. Expanded newborn screening evidence (Dec 2024) supports feasibility of NBS with MS/MS ASM activity plus second-tier LysoSM and genetic testing, with a reported incidence of ~1:137,506 in one Italian program. (gragnaniello2024newbornscreeningfor pages 1-2, gragnaniello2024newbornscreeningfor pages 3-5)
  4. ASCEND adult extension results (Dec 2023) and ongoing long-term datasets continue to demonstrate sustained multi-organ benefit and manageable safety of olipudase alfa. (wasserstein2023continuedimprovementin pages 1-2, wasserstein2023continuedimprovementin pages 6-9)

Limitations of this evidence set (important for knowledge-base curation)

  • Orphanet/ICD/MeSH identifiers were not present in the retrieved sources and therefore cannot be filled with citation support here.
  • Many sources in the retrieved set provide DOIs/URLs but do not display PMIDs in the provided excerpts; when PMIDs are required, they should be extracted from PubMed directly for each DOI.

Key URLs (with publication dates when available in retrieved text)

References

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  2. (geberhiwot2023consensusclinicalmanagement pages 1-2): Tarekegn Geberhiwot, Melissa Wasserstein, Subadra Wanninayake, Shaun Christopher Bolton, Andrea Dardis, Anna Lehman, Olivier Lidove, Charlotte Dawson, Roberto Giugliani, Jackie Imrie, Justin Hopkin, James Green, Daniel de Vicente Corbeira, Shyam Madathil, Eugen Mengel, Fatih Ezgü, Magali Pettazzoni, Barbara Sjouke, Carla Hollak, Marie T. Vanier, Margaret McGovern, and Edward Schuchman. Consensus clinical management guidelines for acid sphingomyelinase deficiency (niemann–pick disease types a, b and a/b). Orphanet Journal of Rare Diseases, Apr 2023. URL: https://doi.org/10.1186/s13023-023-02686-6, doi:10.1186/s13023-023-02686-6. This article has 105 citations and is from a peer-reviewed journal.

  3. (lipinski2024chronicacidsphingomyelinase pages 1-2): Patryk Lipiński, Agnieszka Ługowska, and Anna Tylki-Szymańska. Chronic acid sphingomyelinase deficiency diagnosed in infancy/childhood in polish patients: 2024 update. Advances in clinical and experimental medicine : official organ Wroclaw Medical University, 33:1163-1168, Oct 2024. URL: https://doi.org/10.17219/acem/193696, doi:10.17219/acem/193696. This article has 1 citations.

  4. (wasserstein2023continuedimprovementin pages 1-2): Melissa P. Wasserstein, Robin Lachmann, Carla Hollak, Antonio Barbato, Renata C. Gallagher, Roberto Giugliani, Norberto Bernardo Guelbert, Julia B. Hennermann, Takayuki Ikezoe, Olivier Lidove, Paulina Mabe, Eugen Mengel, Maurizio Scarpa, Ebubekir Senates, Michel Tchan, Jesus Villarrubia, Beth L. Thurberg, Abhimanyu Yarramaneni, Nicole M. Armstrong, Yong Kim, and Monica Kumar. Continued improvement in disease manifestations of acid sphingomyelinase deficiency for adults with up to 2 years of olipudase alfa treatment: open-label extension of the ascend trial. Orphanet Journal of Rare Diseases, Dec 2023. URL: https://doi.org/10.1186/s13023-023-02983-0, doi:10.1186/s13023-023-02983-0. This article has 27 citations and is from a peer-reviewed journal.

  5. (lipinski2019chronicvisceralacid pages 1-2): Patryk Lipiński, Ladislav Kuchar, Ekaterina Y. Zakharova, Galina V. Baydakova, Agnieszka Ługowska, and Anna Tylki-Szymańska. Chronic visceral acid sphingomyelinase deficiency (niemann-pick disease type b) in 16 polish patients: long-term follow-up. Orphanet Journal of Rare Diseases, Feb 2019. URL: https://doi.org/10.1186/s13023-019-1029-1, doi:10.1186/s13023-019-1029-1. This article has 46 citations and is from a peer-reviewed journal.

  6. (pulikottiljacob2023healthcareserviceuse pages 1-2): Ruth Pulikottil-Jacob, Michael L. Ganz, Marie Fournier, and Natalia Petruski-Ivleva. Healthcare service use patterns among patients with acid sphingomyelinase deficiency type b: a retrospective us claims analysis. Advances in Therapy, 40:2234-2248, Mar 2023. URL: https://doi.org/10.1007/s12325-023-02453-w, doi:10.1007/s12325-023-02453-w. This article has 8 citations and is from a peer-reviewed journal.

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  8. (mengel2024aretrospectivestudy pages 1-2): Eugen Mengel, Nicole Muschol, Natalie Weinhold, Athanasia Ziagaki, Julia Neugebauer, Benno Antoni, Laura Langer, Maja Gasparic, Sophie Guillonneau, Marie Fournier, Fernando Laredo, and Ruth Pulikottil-Jacob. A retrospective study of morbidity and mortality of chronic acid sphingomyelinase deficiency in germany. Orphanet Journal of Rare Diseases, Apr 2024. URL: https://doi.org/10.1186/s13023-024-03174-1, doi:10.1186/s13023-024-03174-1. This article has 10 citations and is from a peer-reviewed journal.

  9. (OpenTargets Search: acid sphingomyelinase deficiency,Niemann-Pick disease type B-SMPD1): Open Targets Query (acid sphingomyelinase deficiency,Niemann-Pick disease type B-SMPD1, 5 results). Buniello, A. et al. (2025). Open Targets Platform: facilitating therapeutic hypotheses building in drug discovery. Nucleic Acids Research.

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  14. (mauhin2024acidsphingomyelinasedeficiency pages 3-5): Wladimir Mauhin, Nathalie Guffon, Marie T. Vanier, Roseline Froissart, Aline Cano, Claire Douillard, Christian Lavigne, Bénédicte Héron, Nadia Belmatoug, Yurdagül Uzunhan, Didier Lacombe, Thierry Levade, Aymeric Duvivier, Ruth Pulikottil-Jacob, Fernando Laredo, Samia Pichard, Olivier Lidove, Marie-Thérèse Abi-Wardé, Marc Berger, Emilie Berthoux, Aurélie Cabannes-Hamy, Fabrice Camou, Pascal Cathebras, Vincent Grobost, Jérémy Keraen, Alice Kuster, Bertrand Lioger, Anas Mehdaoui, Claire Merlot, Martin Michaud, Martine-Louise Reynaud-Gaubert, Fréderic Schlemmer, Amélie Servettaz, Chloé Stavris, and Sébastien Trouillier. Acid sphingomyelinase deficiency in france: a retrospective survival study. Orphanet Journal of Rare Diseases, Aug 2024. URL: https://doi.org/10.1186/s13023-024-03234-6, doi:10.1186/s13023-024-03234-6. This article has 10 citations and is from a peer-reviewed journal.

  15. (wasserstein2023continuedimprovementin pages 9-11): Melissa P. Wasserstein, Robin Lachmann, Carla Hollak, Antonio Barbato, Renata C. Gallagher, Roberto Giugliani, Norberto Bernardo Guelbert, Julia B. Hennermann, Takayuki Ikezoe, Olivier Lidove, Paulina Mabe, Eugen Mengel, Maurizio Scarpa, Ebubekir Senates, Michel Tchan, Jesus Villarrubia, Beth L. Thurberg, Abhimanyu Yarramaneni, Nicole M. Armstrong, Yong Kim, and Monica Kumar. Continued improvement in disease manifestations of acid sphingomyelinase deficiency for adults with up to 2 years of olipudase alfa treatment: open-label extension of the ascend trial. Orphanet Journal of Rare Diseases, Dec 2023. URL: https://doi.org/10.1186/s13023-023-02983-0, doi:10.1186/s13023-023-02983-0. This article has 27 citations and is from a peer-reviewed journal.

  16. (diaz2022longtermsafetyand pages 1-2): George A. Diaz, Roberto Giugliani, Nathalie Guffon, Simon A. Jones, Eugen Mengel, Maurizio Scarpa, Peter Witters, Abhimanyu Yarramaneni, Jing Li, Nicole M. Armstrong, Yong Kim, Catherine Ortemann-Renon, and Monica Kumar. Long-term safety and clinical outcomes of olipudase alfa enzyme replacement therapy in pediatric patients with acid sphingomyelinase deficiency: two-year results. Orphanet Journal of Rare Diseases, Dec 2022. URL: https://doi.org/10.1186/s13023-022-02587-0, doi:10.1186/s13023-022-02587-0. This article has 61 citations and is from a peer-reviewed journal.

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  19. (syed2023olipudasealfain pages 4-5): Yahiya Y. Syed. Olipudase alfa in non-cns manifestations of acid sphingomyelinase deficiency: a profile of its use. Clinical Drug Investigation, 43:369-377, May 2023. URL: https://doi.org/10.1007/s40261-023-01270-x, doi:10.1007/s40261-023-01270-x. This article has 15 citations and is from a peer-reviewed journal.

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