1. Introduction
Gaucher Disease (GD) is among the most prevalent, recessively inherited, lysosomal storage disorder caused by a deficiency in the enzyme β-glucocerebrosidase. The deficient enzymatic activity, results in the lysosomal accumulation of its substrate glucosylceramide, most prominently in macrophages [1]. Glycosphingolipid-laden macrophages, referred to as Gaucher cells, accumulate in the visceral tissues liver, spleen and bone marrow, inducing a pleiotropic array of symptoms, including hepatosplenomegaly and pancytopenia, in addition to bone complications such as non-specific bone pain, bone crises, avascular necrosis and pathologic fractures [2]. Three variants of GD are generally distinguished based on the absence (GD 1) or the presence of central nervous system involvement (GD 2 or GD 3).
In the past, the majority of GD cases manifested during childhood and adolescence, with almost half of the cases diagnosed before ten years of age [3]. In early symptomatic disease, early intervention with enzyme replacement therapy (ERT) has become the standard of care since 1991 [4], and it has led to improved GD-related symptoms and significant reduction of complications (particularly bone crises and osteonecrosis) [5]. With the extended use of carrier screening for GD, the phenotype of children with GD had changed, and many of them are asymptomatic or mildly symptomatic at diagnosis [6,7]. Under these circumstances, the question arises to whom ERT should be given and when to initiate it, as some of those children will remain asymptomatic for many years, while others may develop irreversible complications that may be avoided by early initiation of ERT.
Glucosylsphingosine (lyso-Gb1), a deacylated form of glucosylceramide, is also degraded by the glucocerebrosidase. Lyso-Gb1 was proved to be a highly sensitive and specific biomarker for diagnosis and monitoring of adults patients with GD [8,9]. This is the first study reporting the role of lyso-Gb1 for monitoring disease status in a relatively large cohort of treated and untreated children with GD.
2. Results
The clinical phenotype of all children at their last visit is presented in Table 1. As expected, the majority of children with severe GD1 and GD3 received ERT, whereas the majority of children with mild GD1 were untreated. At the time of the last visit, lyso-Gb1 levels were significantly lower in children with mild GD1 compared to those with severe GD1 (p = 0.009) and not different from children with GD3 (p = 0.81). No significant differences were found between children with mild and severe GD1 regarding the age, gender, platelet count, hemoglobin levels and spleen and liver MN (multiples of normal) volume. Significantly larger spleen and liver MN volume were found in children with GD3 compared to those with GD1 (p = 0.007 and p = 0.005, respectively).
In all groups combined, the lyso-Gb1 significantly correlated with platelet count (p < 0.0001, r = −0.42) and hemoglobin levels (p = 0.003, r = −0.35), but not with liver MN volume, spleen MN volume, child’s age, and weight. When analyzing according to genotype, a significant correlation between lyso-Gb1 and platelet was found only in children with mild GD1 and a significant correlation between lyso-Gb1 and hemoglobin was found only in children with severe GD1. Similarly, when analyzing according to treatment status, irrespective of genotype, a significant inverse correlation was found between lyso-Gb1 and platelet count only in untreated children (p = 0.002 vs. p = 0.178 [in treated children]) and between lyso-Gb1 and hemoglobin level only in treated children (p = 0.01 vs. p = 0.197 [in untreated children]) (Figure 1).
Pre-ERT data, available for ten children, were compared to the first visit data of the 28 untreated children (Table 2). As expected, children eventually treated had more symptomatic disease, i.e., thrombocytopenia, anemia, and hepatosplenomegaly. Importantly, although lyso-Gb1 was not used for treatment decisions, significantly higher levels of lyso-Gb1 levels were found in the pre-ERT group compared to untreated children (p = 0.0003).
The patterns of change in lyso-Gb1 levels from baseline to the last visit for untreated children, treated children with pre-ERT measurements and treated children with both measurements on-ERT are shown in Table 3. In treated children, the drop of lyso-Gb1 was significantly higher in the pre-ERT group compared to the on-ERT group (p = 0.007) (Table 3). Lyso-Gb1 levels increased with time in eight children, all from the on-ERT group (Table 4). Retrospective analysis of the clinical charts found compliance issues and weight gain (>15%) without dose adjustment, as a possible explanation. Age was not associated with the pattern of change in treated children (Figure 2A).
In untreated children, lyso-Gb1 levels increased with time in almost half of the cohort (Table 3). The group of children whose lyso-Gb1 levels increased during follow-up were significantly younger at baseline compared to the group of children whose lyso-Gb1 levels dropped or remained unchanged during follow-up (p = 0.01) (Figure 2B).
Time of follow-up and weight change were not associated with the pattern of change of lyso-Gb1 levels in treated and untreated children.
3. Discussion
In this study, we show the potential value of lyso-Gb1 in children with GD both for monitoring untreated and treated children. An association between GD severity and lyso-Gb1 levels was expressed in several ways. First, an association between genotype and the lyso-Gb1 level was shown; significantly higher levels of lyso-Gb1 in children with severe GD1 compared to children with mild GD1 (Table 1). Second, we found an association between lyso-Gb1 levels and clinical status, i.e., platelet count, in untreated children (Figure 1A). Third, we show that children who eventually started treatment, based on clinical criteria, had significantly higher levels of lyso-Gb1 compared to untreated children (Table 2).
Association between genotype and lyso-Gb1 levels are consistent with adult data showing that patients with less severe disease, i.e., homozygotes N370S, generally show more modest increases in plasma lyso-Gb1 [10]. As expected, clinical variability was found within the group of N370S homozygous patients [11]. Within this group of N370S homozygous patients, a clear relationship between disease severity and lyso-Gb1 levels was observed by us and others [12]. With the change in the phenotype of children with GD, a useful biomarker to guide therapy decisions in untreated children is important.
In treated children, the lyso-Gb1 increase in some of the cases was associated with compliance and significant weight gain (>15%). We believe that the increase in lyso-Gb1 was related to lower ERT dose/kg and not the weight change per se. The linkage between the dose of ERT and response was previously shown in patients with GD [13].
Recently, we have shown in adults with GD1 that lyso-Gb1 is a reliable response biomarker preceding changes in other disease parameters [14]. Initiation of ERT or a substrate reduction agent had a significant effect on lyso-Gb1 levels, which becomes less robust over time after the maximal change rate [8,9,10,15]. Similarly, we show a more considerable lyso-Gb1 change in those with pre-ERT levels compared to when both lyso-Gb1 levels are on-ERT. Still, lyso-Gb1 levels can also decrease after a prolonged period of therapy. Follow-up on therapy can reflect treatment response and detect treatement failures and compliance issues.
In children on ERT, who achieved a normal platelet count, lyso-Gb1 levels correlated only with hemoglobin levels; a parameter with a slower response to treatment. Similar findings were reported in the splenectomy era; in splenectomized patients, anemia was more prominent than thrombocytopenia, whereas, in non-splenectomized patients, thrombocytopenia is typically more prominent than anemia [3].
In a study which included treated patients, mainly adults, age had a significant inverse correlation with plasma lyso-Gb1 [12]. The authors concluded that this likely reflects the fact that children have a more severe disease at presentation than adults. In our cohort, age was not a predictor of lyso-Gb1 levels in either treated or untreated children. This may be explained by the changing phenotype of children with GD due to pre-natal screening [6,7] or by the fact that only children were included in our study.
Interestingly, age did play a role in the pattern of change in lyso-Gb1 levels over time in mildly effected untreated children. A younger age at first visit was associated with an increase in lyso-Gb1 levels. At an older age, the lyso-Gb1 levels may plateau or even mildly drop. Extended follow-up into adulthood is needed for those untreated children. The fact that lyso-Gb1 could drop without treatment suggests that only a consistent and significant increase in lyso-Gb1 levels should lead to treatment decisions in children presenting with asymptomatic/mildly symptomatic disease.
The additional interesting aspect of our study is the similarity between GD1 and GD3 concerning lyso-Gb1 levels. This might reflect the fact that the GD3 patients in our center belong to the so-called Type 3b (patients with severe visceral manifestation and relatively minimal neurological abnormalities [16]). Others are Type 3c (the so-called "cardiac variant" wherein there is minimal visceral involvement and minimal neurological features but massive calcifications of the aortic and mitral valves [17,18]).
4. Material and Methods 4.1. Patients Samples
Eighty-one consecutive children (<18 years) with GD who visited the Gaucher Unit at Shaare Zedek Medical Center from July 2014 to December 2018 were included in this study. Lyso-Gb1 measurement had been included in the routine clinical and laboratory assessment during all follow-up (annual/semiannual) visits.
Disease severity for this study was based on genotypes for GD1, i.e., mild GD1 were all children the with N370S/N370S or N370S/R496H genotypes and severe GD1 were N370S compound heterozygotes [19]. Type 3 (neuronopathic disease) was based on clinical phenotype, all with genotypes known to be associated with GD3. Demographic, baseline, and follow-up clinical and laboratory data were extracted from the medical records. The multiple of normal (MN) was calculated for spleen volume and liver volume based on three dimensions by ultrasonography [20,21]. Dried blood spots (DBS) were collected on filter cards (CentoCard®, Centogene, Rostock, Germany) and lyso-Gb1 analysis was carried out in Centogene, Rostock, Germany. Lyso-Gb1 levels were measured using liquid chromatography-mass spectrometry of DBS samples (Centogene AG, Rostock, Germany) as previously described [8]. The study was approved by the Institution Ethics Committee (0291-18-SZMC, 11/2018).
4.2. Statistical Methods
For data analysis, we defined in our study three cohorts. The first was an analysis of data at last visit for all patients (n = 81), the second was an analysis of data at first visit for untreated patients and patients with pre-treatment data (n = 38), and the last analysis was of patients data with more than one visit (n = 68). The delta of every measurement between the last and the first visit was calculated. Log transformation of lyso-Gb1 was done to achieve normal distribution. Results are presented as median and range. Correlations between the lyso-Gb1 levels and continuous measurements were tested by non-parametric Spearman's correlation and Pearson's correlation, for non-normal and normally distributed data, respectively. Mann–Whitney non-parametric test was used to compare non-normally distributed data in independent samples. Multivariate analysis was used to clarify the impact of ERT vs. non-ERT and impact of genotypes (mild vs. severe GD1) on the calculated correlation between the log of lyso-Gb1 and the other measurements. IBM SPSS version 25 was used for analysis. Results were considered to be statistically significant when two-tailed p-values were ≤0.01.
5. Conclusions
The correlations found between lyso-Gb1 levels and disease severity as well as the changes in levels with and without therapy support the importance of using this biomarker in monitoring children with GD, both untreated and treated, for the need to start treatment and to follow the response to therapy, respectively. At this point, we cannot recommend a specific cut-off for lyso-Gb1 levels as a sole indication for beginning ERT, in part because by the time lyso-Gb1 levels became available many children were already on ERT. We believe that within the coming years, with a more significant number of naïve patients, we will be able to define a specific value. In the interim, we strongly recommend including lyso-GB1 in the routine follow-up of all children with GD and a progressive increment in lyso-Gb1 should lead to consideration of ERT in untreated children or to a dose increase in treated children.
Enlarge this image.Figure 1.(A) Correlation analysis between lyso-Gb1 levels and the platelet count in treated (hollow dots, dotted line) and untreated children (full dots, continuous line). (B) Correlation analysis between lyso-Gb1 levels and the hemoglobin level in treated (hollow dots, dotted line) and untreated children (full dots, continuous line).
Enlarge this image.Figure 2. Age at first visit of the children with decreased, increased, and unchanged lyso-Gb1 levels (10%) between first and last visit for (A) treated children (B) untreated children.
| Total | Mild Type 1 | Severe Type 1 | Type 3 | |
|---|---|---|---|---|
| N | 81 | 35 | 34 | 12 |
| Age, years* | 11 (1–18) | 11 (4–18) | 12 (2–16) | 9.5 (1–18) |
| Male, % | 38 (47%) | 16 (38%) | 18 (52%) | 4 (33%) |
| ERT* | 42 (51%) | 2 (5.7%) | 30 (88%) | 10 (83%) |
| Platelet count, ×103/mL | 214 (59–383) | 251 (134–383) | 209 (76–334) | 190 (59–322) |
| Hemoglobin, mg/dl | 12.9 (8.7–16.4) | 12.8(11.5–16.4) | 13.15 (9.2–15.3) | 12.4 (8.7–16.3) |
| Spleen (MN)* | 1.3 (0–16.7) | 1.3 (0.5–4.7) | 1.3 (0.6–10.3) | 3.4 (1.2–16.7) |
| Liver (MN)* | 1.4 (0.3–3.6) | 1.4 (1–2.3) | 1.3 (0.3–2.8) | 2.3 (1.3–3.5) |
| Lyso-Gb1 level, ng/mL* | 76.3 (4.9–495) | 64 (4.9–208) | 98 (7.3–495) | 100.4 (21.4–210) |
| Weight, Kg* | 37.8 (10.1–76) | 34.1 (14.7–70.9) | 49 (15.4–76) | 29.8 (10.1–52.2) |
*, median (range); ERT, Enzyme replacement therapy; MN, multiple of normal; Kg, kilogram.
| Pre-Treatment | Un-Treated | |
|---|---|---|
| N | 10 | 28 |
| Age, years | 5.5 (2–14) | 8.5 (1–16) |
| Male, % | 5 (55%) | 11 (37%) |
| Platelet count, ×103/mL | 82.5 (68–228) | 236.5 (117–339) |
| Hemoglobin, mg/dl | 11.1 (6.7–12.4) | 12.7 (11.1–15.7) |
| Spleen (MN)* | 3.9 (1.1–22.9) | 1.35 (0.5–5.2) |
| Liver (MN)* | 2.4 (1.2–4.5) | 1.7 (1–3) |
| Lyso-Gb1 level, ng/mL* | 262.5 (101–1270) | 61.45 (6.1–157) |
*, median (range); MN, multiple of normal.
| Untreated | Treated, Pretreatment Baseline | ||
|---|---|---|---|
| Yes | No | ||
| N | 28 | 10 | 30 |
| Male | 11 | 5 | 16 |
| Age, years* | 12 (4–18) | 8.5 (3–18) | 16 (3–19) |
| Months of follow-up* | 31.85 ( 6.7–45) | 27.6 (6.7–44) | 28.75 (9.3–49.9) |
| Number of visits | 3 (2–6) | 4 (3-6) | 4 (2–9) |
| Unchanged** (n) | 9 (32%) | 1 (10%) | 5 (16%) |
| Increased (n) | 13 (46%) | 0 (0%) | 8 (26%) |
| Increase change* | 12 (1.29–128) | 67.4 (5.7–368) | |
| Decreased (n) | 6 (21%) | 9 (90%) | 17 (56%) |
| Decrease change* | 11.2 (4–50.4) | 143.6 (13–1207.7) | 32.7 (4.2–172) |
*, median (range); **, <10% change from baseline; n, number.
| Age (Y)* | Gender | Genotype | Mo. on Tx* | Dosa u/kg/mo* | Follow Up (mo) | Baseline Lyso- Gb1 | Change from Baseline | Possible Explanation | ||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Lyso-Gb1 | PLT | Hb | Spleen MN | Liver MN | ||||||||
| 9 | male | Severe GD1 | 72 | 36.7 | 140 | 79↑ | 9↓ | 0.5≈ | 0.5≈ | 0.4≈ | ||
| 9 | male | Severe GD1 | 81.2 | 52 | 23.6 | 168 | 18↑ | 31↓ | 0.4≈ | Weight gain** | ||
| 18 | male | Severe GD1 | 92.3 | 42 | 18.6 | 95 | 368↑ | 24↓ | 1.1↓ | 1.8↑ | 0.3≈ | Compliance |
| 18 | female | Severe GD1 | 130.9 | 35 | 36.9 | 281 | 180↑ | 18↓ | 0.5≈ | 0.6↓ | 0.1≈ | |
| 10 | male | Severe GD1 | 90.3 | 42 | 40.0 | 164 | 48↑ | 56↓ | 1.1↑ | 1.4↓ | 0.2≈ | |
| 14 | male | Severe GD1 | 113.7 | 114 | 38.3 | 45 | 6↑ | 4≈ | 1.3↓ | 6.4↑ | 1.2↓ | Weight gain** |
| 16 | male | Severe GD1 | 137.0 | 50 | 30.2 | 124 | 77↑ | 20↑ | 2.5↓ | 0.6↓ | 0.3≈ | Weight gain** |
| 17 | male | GD3 | 124.8 | 60 | 18.6 | 32 | 13↑ | 20↓ | 1.3↑ | 0.5↑ | 0.8↑ | |
Y, year; mo, months; PLT, platelets; Hb, hemoglobin; *, at last visit; **, more than 15% increment in the weight percentage.
Author Contributions
Conceptualizations, S.R.-V. and A.Z.; methodology, N.H., S.R.-V., and A.Z.; formal analysis, N.H., and S.R.-V.; investigation, A.A., H.Z., T.D., and M.B.-C.; resources, C.C., M.H., S.O., L.D. and A.R.; data curation, T.D., and C.C.; writing-original draft preparation, N.H., and S.R.-V.; writing-review and editing, A.Z., A.A., M.H., and L.D.; visualization, N.H., and S.R.-V.; supervision, A.Z.; project administration, T.D.
Funding
This research received no external funding.
Acknowledgments
This study was conducted as partial requirements of the Hebrew University and Hadassah School of Medicine for Noa Hurvitz. We thank Tali Bedolach for her help in the statistical analysis.
Conflicts of Interest
The SZMC Gaucher Unit receives support from Sanofi/Genzyme for participation in the ICGG Registry, from Shire for the GOS Registry, Pfizer for TALIAS. The Unit also receives research grants from Shire/Takeda and Pfizer and involved in Lyso-prove study, Centogene. C.C., M.H., S.O., and L.D. are employees of Centogene AG, the company that did the lysoGb1 analysis. A.R. is the founder and CEO of Centogene AG. He has received honoraria and speakers fees from Shire/Takeda. A.Z. receives honoraria from Shire/Takeda and Pfizer and a consultancy fee from TAKDA and Prevail therapeutics. S.R.V. receives speakers fees and travel support from Shire, Pfizer, and Sanofi/Genzyme.
© 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
1. Revel-Vilk, S.; Szer, J.; Mehta, A.; Zimran, A. How we manage Gaucher Disease in the era of choices. Br. J. Haematol. 2018, 182, 467-480.
2. Gary, S.E.; Ryan, E.; Steward, A.M.; Sidransky, E. Recent advances in the diagnosis and management of Gaucher disease. Expert Rev. Endocrinol. Metab. 2018, 13, 107-118.
3. Zimran, A.; Elstein, D. Chapter 72: Gaucher disease and related Lysosomal Storage Diseases. In Williams' Hematology; Kaushansky, K., Lichtman, M.A., Prchal, J.T., Levi, M.M., Press, O.W., Burns, L.J., Caligiuri, M.L., Eds.; McGraw-Hill: New York, NY, USA, 2016.
4. Barton, N.W.; Brady, R.O.; Dambrosia, J.M.; Di Bisceglie, A.M.; Doppelt, S.H.; Hill, S.C.; Mankin, H.J.; Murray, G.J.; Parker, R.I.; Argoff, C.E.; et al. Replacement therapy for inherited enzyme deficiency--macrophage-targeted glucocerebrosidase for Gaucher's disease. N. Engl. J. Med. 1991, 324, 1464-1470.
5. Andersson, H.; Kaplan, P.; Kacena, K.; Yee, J. Eight-year clinical outcomes of long-term enzyme replacement therapy for 884 children with Gaucher disease type 1. Pediatrics 2008, 122, 1182-1190.
6. Elstein, D.; Altarescu, G.; Abrahamov, A.; Zimran, A. Children with type 1 Gaucher disease: Changing profiles in the 21st century. Blood Cells Mol. Dis. 2018, 68, 93-96.
7. Yang, A.C.; Bier, L.; Overbey, J.R.; Cohen-Pfeffer, J.; Desai, K.; Desnick, R.J.; Balwani, M. Early manifestations of type 1 Gaucher disease in presymptomatic children diagnosed after parental carrier screening. Genet. Med. 2017, 19, 652-658.
8. Rolfs, A.; Giese, A.K.; Grittner, U.; Mascher, D.; Elstein, D.; Zimran, A.; Bottcher, T.; Lukas, J.; Hubner, R.; Golnitz, U.; et al. Glucosylsphingosine is a highly sensitive and specific biomarker for primary diagnostic and follow-up monitoring in Gaucher disease in a non-Jewish, Caucasian cohort of Gaucher disease patients. PLoS ONE 2013, 8, e79732.
9. Elstein, D.; Mellgard, B.; Dinh, Q.; Lan, L.; Qiu, Y.; Cozma, C.; Eichler, S.; Bottcher, T.; Zimran, A. Reductions in glucosylsphingosine (lyso-Gb1) in treatment-naive and previously treated patients receiving velaglucerase alfa for type 1 Gaucher disease: Data from phase 3 clinical trials. Mol. Genet. Metab. 2017, 122, 113-120.
10. Murugesan, V.; Chuang, W.L.; Liu, J.; Lischuk, A.; Kacena, K.; Lin, H.; Pastores, G.M.; Yang, R.; Keutzer, J.; Zhang, K.; et al. Glucosylsphingosine is a key biomarker of Gaucher disease. Am. J. Hematol. 2016, 91, 1082-1089.
11. Davidson, B.A.; Hassan, S.; Garcia, E.J.; Tayebi, N.; Sidransky, E. Exploring genetic modifiers of Gaucher disease: The next horizon. Hum. Mutat. 2018, 39, 1739-1751.
12. Dekker, N.; van Dussen, L.; Hollak, C.E.; Overkleeft, H.; Scheij, S.; Ghauharali, K.; van Breemen, M.J.; Ferraz, M.J.; Groener, J.E.; Maas, M.; et al. Elevated plasma glucosylsphingosine in Gaucher disease: Relation to phenotype, storage cell markers, and therapeutic response. Blood 2011, 118, e118-e127.
13. Grabowski, G.A.; Kacena, K.; Cole, J.A.; Hollak, C.E.; Zhang, L.; Yee, J.; Mistry, P.K.; Zimran, A.; Charrow, J.; vom Dahl, S. Dose-response relationships for enzyme replacement therapy with imiglucerase/alglucerase in patients with Gaucher disease type 1. Genet. Med. 2009, 11, 92-100.
14. Arkadir, D.; Dinur, T.; Revel-Vilk, S.; Becker Cohen, M.; Cozma, C.; Hovakimyan, M.; Eichler, S.; Rolfs, A.; Zimran, A. Glucosylsphingosine is a reliable response biomarker in Gaucher disease. Am. J. Hematol. 2018, 93, E140-E142.
15. Mistry, P.K.; Lukina, E.; Ben Turkia, H.; Shankar, S.P.; Baris, H.; Ghosn, M.; Mehta, A.; Packman, S.; Pastores, G.; Petakov, M.; et al. Outcomes after 18 months of eliglustat therapy in treatment-naive adults with Gaucher disease type 1: The phase 3 ENGAGE trial. Am. J. Hematol. 2017, 92, 1170-1176.
16. Brautbar, A.; Abrahamov, A.; Hadas-Halpern, I.; Elstein, D.; Zimran, A. Gaucher disease in Arab patients at an Israeli referral clinic. Isr. Med. Assoc. J. 2008, 10, 600-602.
17. Abrahamov, A.; Elstein, D.; Gross-Tsur, V.; Farber, B.; Glaser, Y.; Hadas-Halpern, I.; Ronen, S.; Tafakjdi, M.; Horowitz, M.; Zimran, A. Gaucher's disease variant characterised by progressive calcification of heart valves and unique genotype. Lancet 1995, 346, 1000-1003.
18. Mistry, P.K. Genotype/phenotype correlations in Gaucher's disease. Lancet 1995, 346, 982-983.
19. Zimran, A.; Gross, E.; West, C.; Sorge, J.; Kubitz, M.; Beutler, E. Prediction of severity of Gaucher's disease by identification of mutations at DNA level. Lancet 1989, 2, 349-352.
20. Yetter, E.M.; Acosta, K.B.; Olson, M.C.; Blundell, K. Estimating Splenic Volume: Sonographic Measurements Correlated with Helical CT Determination. Am. J. Roentgenol. 2003, 181, 1615-1620.
21. Elstein, D.; Hadas-Halpern, I.; Azuri, Y.; Abrahamov, A.; Bar-Ziv, Y.; Zimran, A. Accuracy of ultrasonography in assessing spleen and liver size in patients with Gaucher disease: Comparison to computed tomographic measurements. J. Ultrasound Med. 1997, 16, 209-211.
1Gaucher Unit, Shaare Zedek Medical Center, Hebrew University, Jerusalem 9103102, Israel
2Faculty of Medicine, The Hebrew University of Jerusalem, Ein Kerem, Jerusalem 9112102, Israel
3Centogene AG, Rostock 18055, Germany
4Faculty of Medicine, University of Rostock, Rostock 18051, Germany
*Author to whom correspondence should be addressed.
© 2019. This work is licensed under https://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.