Thromb Haemost 2022; 122(07): 1239-1242
DOI: 10.1055/a-1692-1199
Letter to the Editor

The Proportions of Low- and Intermediate-Molecular-Weight von Willebrand Factor Multimers Are Different in Neonates and Infants Compared to Adults

Natasha Letunica
1   Haematology, Murdoch Children's Research Institute, Melbourne, Australia
,
Suelyn Van Den Helm
1   Haematology, Murdoch Children's Research Institute, Melbourne, Australia
,
Rebecca Barton
1   Haematology, Murdoch Children's Research Institute, Melbourne, Australia
2   Department of Paediatrics, The University of Melbourne, Melbourne, Australia
3   Department of Clinical Haematology, Royal Children's Hospital, Melbourne, Australia
,
Asami Weaver
1   Haematology, Murdoch Children's Research Institute, Melbourne, Australia
,
Vasiliki Karlaftis
1   Haematology, Murdoch Children's Research Institute, Melbourne, Australia
2   Department of Paediatrics, The University of Melbourne, Melbourne, Australia
,
Paul Monagle
1   Haematology, Murdoch Children's Research Institute, Melbourne, Australia
2   Department of Paediatrics, The University of Melbourne, Melbourne, Australia
3   Department of Clinical Haematology, Royal Children's Hospital, Melbourne, Australia
4   Kids Cancer Centre, Sydney Children's Hospital, Randwick, Australia
,
Vera Ignjatovic
1   Haematology, Murdoch Children's Research Institute, Melbourne, Australia
2   Department of Paediatrics, The University of Melbourne, Melbourne, Australia
› Author Affiliations
 

von Willebrand factor (vWF) exists as a multimeric glycoprotein, consisting of a series of multimers with varying number of subunits that play a major role in hemostasis, specifically in platelet adhesion and aggregation.[1] The activity of vWF is proportional to the size of the multimers, with high-molecular-weight multimer (HMWM) having increased platelet binding and platelet aggregation capacity compared with the low- and intermediate–molecular-weight multimers (LMWM and IMWM).[2]

Previous studies have shown that the overall vWF concentration increases with age in healthy children and adults, as well as in individuals with von Willebrand disease. However, there is little known about the changes in the vWF multimer composition across the age spectrum from neonates to adults.[3]

An understanding of the effect of age on vWF and its multimers is important for accurate diagnosis and management of neonates and children with hematological complications. This study aimed to investigate age-specific changes in vWF concentration and function, as well as the composition of the vWF multimers in a healthy population spanning the age spectrum from neonates to adults.

Plasma samples were obtained from healthy neonates, children, and adults, without previous thromboembolic events (e.g., thrombosis and hemorrhage) and not subjected to any form of anticoagulant therapy, according to the previously established protocol.[4] This study was approved by the Royal Children's Hospital, Human Research Ethics Committee (HREC #34183) and the Royal Women's Hospital Human Research Ethics Committee (#2/08). Written informed consent was obtained from parents/guardians of children and from adult participants themselves.

Blood samples were collected in S-Monovette tubes (Sarstedt, Australia), containing 1 volume of citrate per 9 volumes of blood, and were centrifuged at 3,000 rpm for 10 minutes at 10°C (Megafuge 1.0R, Heraeus) to obtain plasma.

vWF concentration and activity were measured using the STA R Max analyzer and Stago reagents, STA vWF antigen (vWF:Ag) and STA ristocetin cofactor activity (vWF:RCo) (Diagnostica Stago, France). vWF collagen binding (vWF:CB) was measured using a commercially available enzyme-linked immunosorbent assay (Diagnostica Stago, France). vWF multimers were analyzed using the Hydragel 11 vWF Multimer assay (Sebia, France), as previously described.[5]

Data analysis was performed using GraphPad Prism (Version 9.0). Results from the neonatal and pediatric age groups were compared with the results for adults using a one-way ANOVA (analysis of variance), followed by Dunnett's test to correct for multiple comparisons. p < 0.05 was considered to be statistically significant.

A representative image of the analyzed Hydragel vWF multimer gels is shown in [Fig. 1]. vWF activity and its associated multimers were assessed in 80 children and 20 adults, with participant characteristics described in [Table 1]. While vWF concentration and activity, as represented by vWF:RCo, vWF:Ag, and vWF:CB, in neonates and children were comparable to adults, the proportions of LMWM were significantly higher in neonates compared with adults, before reaching and maintaining adult levels at approximately 6 to 10 years of age ([Table 2]). In addition, IMWMs were significantly lower in neonates, and in children up to 5 years of age compared with adults.

Zoom Image
Fig. 1 Representative electrophoresis gel demonstrating vWF multimer patterns in a healthy adult (lane 1), <2 year old (lane 2), and a neonate (lane 3). Representative densitograms for lane 1(B), lane 2(C), and lane 3(D) are also shown. vWF, von Willebrand factor.
Table 1

Participant demographic data

Neonates

≤2 y

>2–5 y

6–10 y

11–17 y

Adults

Participants (n =)

20

22

11

8

19

20

Median age

48.0 h

0.9

3.5

9.5

13.9

32.7

Age range

24.0–96.0

0.3–1.4

2.3–4

8.8–10.3

11.7–17.6

20.5–53.9

Sex

10 M/10 F

18 M/4 F

5 M/6 F

5 M/3 F

10 M/9 F

7 M/13 F

Blood group

 O (n =)

5

6

2

2

4

Not available

 A/B/AB (n =)

7

8

5

4

8

Table 2

Age-specific results for vWF:RCo, vWF:Ag, vWF:CB, and vWF:CB/vWF:Ag ratio, vWF low-molecular-weight multimer (LMWM), vWF intermediate-molecular-weight multimer (IMWM), and vWF high-molecular-weight multimer (HMWM)

Neonates (h)

≤2 y

>2–5 y

6–10 y

11–17 y

Adults

vWF:RCo

 Mean

102.1

74.0

88.9

86.1

97.2

92.7

 95% CI

83.1–121.0

60.7–87.2

71.5–106.3

68.3–103.9

81.2–113.2

78.1–107.3

vWF:Ag

 Mean

112.6

83.8

98.8

91.3

89.8

101.9

 95% CI

96.3–128.9

71.0–96.5

82.2–115.4

70.2–112.3

68.9–110.5

88.6–115.2

vWF:CB

 Mean

113.6

89.1

90.5

112.9

78.8

72.6

 95% CI

81.9–145.6

64.9–113.3

35.9–145.2

43.5–182.4

63.1–94.6

51.7–93.5

vWF:CB/vWF:Ag

 Mean

1.0

1.3

0.9

1.2

1.3

0.8

 95% CI

0.7–1.3

0.7–1.9

0.4–1.4

0.5–1.8

0.3–2.3

0.5–1.0

vWF LMWM

 Mean

19.9 [a]

17.7

18.3

15.5

15.4

15.5

 95% CI

17.1–22.7

15.7–19.7

14.5–22.1

13.9–17.1

12.7–18.1

14.0–17.0

vWF IMWM

 Mean

27.5 [a]

27.7 [a]

26.9 [a]

30.5

28.4

30.5

 95% CI

25.5–29.6

26.5–28.8

24.7–29.1

28.3–32.7

26.9–29.8

29.1–31.8

vWF HMWM

 Mean

52.6

54.6

54.8

54.0

56.2

54.0

 95% CI

48.3–56.8

52.6–56.7

49.7–59.8

51.4–56.6

53.1–59.3

51.8–56.3

Abbreviations: CB, collagen binding; CI, confidence interval; vWF, von Willebrand factor.


Note: Test results are expressed as percentage (%).


a p-Value significantly different from adults (p < 0.05).


The results of our study demonstrate significant age-specific differences in proportions of some of the vWF multimers, with no age-specific differences observed when considering the overall vWF activity and concentration.

Our vWF concentration and activity findings are comparable with previously published work,[6] [7] [8] [9] [10] with no change across the age spectrum. vWF multimers have been previously investigated in critically ill children with varying comorbidities such as febrile seizures and in the setting of extracorporeal membrane oxygenation.[11] [12]

Previous studies investigating vWF multimers have shown that neonates have increased amounts of HMWM.[13] [14] Conversely, we demonstrated that in healthy neonates and children, proportions of LMWM are increased and proportions of IMWM are decreased in neonates and young children compared with adults. However, proportions of HMWM were relatively the same across the age spectrum. Differences between our findings and previous studies could be explained by: (1) differences in the age (e.g., neonates born <36 weeks' gestation) and health status (e.g., thrombotic thrombocytopenic purpura, necrotizing enterocolitis) of the participants used across studies, and (2) different methodological techniques used to investigate vWF multimers. Specifically, the vWF multimer analysis techniques utilized in the studies conducted by Katz et al[13] and Weinstein et al[14] are in-house, labor-intensive, manual laboratory tests that are operator-dependent. On the other hand, the semi-automated method produced by Sebia reduces operator dependence and has been shown to be reliable and successful in correctly visualizing and interpreting vWF multimers.[15]

Differences were seen in this study, across the pediatric age groups when vWF was characterized. Further research is required to gain a better understanding of the effect and interaction of the specific vWF multimers and current therapeutics.

In conclusion, while there are no changes in the overall activity and function of vWF, the sizes specific vWF multimers vary significantly with age in healthy neonates and children up to 5 years of age. Our findings highlight that physiological age-specific differences in hemostatic proteins such as vWF can only be detected using sensitive assays that account for the specific forms of proteins, such as the vWF multimers.


#

Conflict of Interest

None declared.

Acknowledgments

The authors would like to acknowledge Sebia for providing the analyzer and reagents for this study. We would also like to thank members of the Anesthetic and Surgical departments of the Royal Children's Hospital (RCH), Melbourne for facilitation of sample collection, the assistance of Chauvy Burgess, Kathryn Bowers, and Jody Hand. We would also like to thank the newborn and children participants and their families.

Author Contributions

N.L., S.V.D.H., R.B., and V.K. planned and performed the experiments and analyzed the data. N.L., S.V.D.H., and A.W. wrote the manuscript. V.I. and P.M. oversaw the project and reviewed the manuscript. All authors reviewed and approved the final version of the manuscript.


  • References

  • 1 Leebeek FWG, Eikenboom JCJ. Von Willebrand's disease. N Engl J Med 2016; 375 (21) 2067-2080
  • 2 Moake JL, Turner NA, Stathopoulos NA, Nolasco LH, Hellums JD. Involvement of large plasma von Willebrand factor (vWF) multimers and unusually large vWF forms derived from endothelial cells in shear stress-induced platelet aggregation. J Clin Invest 1986; 78 (06) 1456-1461
  • 3 Biguzzi E, Castelli F, Lijfering WM. et al. Rise of levels of von Willebrand factor and factor VIII with age: Role of genetic and acquired risk factors. Thromb Res 2021; 197: 172-178
  • 4 Hoq M, Karlaftis V, Mathews S. et al. A prospective, cross-sectional study to establish age-specific reference intervals for neonates and children in the setting of clinical biochemistry, immunology and haematology: the HAPPI Kids study protocol. BMJ Open 2019; 9 (04) e025897
  • 5 Oliver S, Lau KKE, Chapman K, Favaloro EJ. Laboratory testing for von Willebrand factor multimers. In: Favaloro EJ, Lippi G. eds. Hemostasis and Thrombosis. Vol 1646. Methods in Molecular Biology. New York, NY: Springer; 2017: 495-511
  • 6 Andrew M, Vegh P, Johnston M, Bowker J, Ofosu F, Mitchell L. Maturation of the hemostatic system during childhood. Blood 1992; 80 (08) 1998-2005
  • 7 Flanders MM, Crist RA, Roberts WL, Rodgers GM. Pediatric reference intervals for seven common coagulation assays. Clin Chem 2005; 51 (09) 1738-1742
  • 8 Appel IM, Grimminck B, Geerts J, Stigter R, Cnossen MH, Beishuizen A. Age dependency of coagulation parameters during childhood and puberty. J Thromb Haemost 2012; 10 (11) 2254-2263
  • 9 Klarmann D, Eggert C, Geisen C. et al. Association of ABO(H) and I blood group system development with von Willebrand factor and factor VIII plasma levels in children and adolescents. Transfusion 2010; 50 (07) 1571-1580
  • 10 Toulon P, Berruyer M, Brionne-François M. et al. Age dependency for coagulation parameters in paediatric populations. Results of a multicentre study aimed at defining the age-specific reference ranges. Thromb Haemost 2016; 116 (01) 9-16
  • 11 Pechmann A, Wellmann S, Stoecklin B, Krüger M, Zieger B. Increased von Willebrand factor parameters in children with febrile seizures. PLoS One 2019; 14 (01) e0210004
  • 12 Pasala S, Fiser RT, Stine KC, Swearingen CJ, Prodhan P. von Willebrand factor multimers in pediatric extracorporeal membrane oxygenation support. ASAIO J 2014; 60 (04) 419-423
  • 13 Katz JA, Moake JL, McPherson PD. et al. Relationship between human development and disappearance of unusually large von Willebrand factor multimers from plasma. Blood 1989; 73 (07) 1851-1858
  • 14 Weinstein MJ, Blanchard R, Moake JL, Vosburgh E, Moise K. Fetal and neonatal von Willebrand factor (vWF) is unusually large and similar to the vWF in patients with thrombotic thrombocytopenic purpura. Br J Haematol 1989; 72 (01) 68-72
  • 15 Pikta M, Zemtsovskaja G, Bautista H. et al. Preclinical evaluation of a semi-automated and rapid commercial electrophoresis assay for von Willebrand factor multimers. J Clin Lab Anal 2018; 32 (06) e22416

Address for correspondence

Vera Ignjatovic, PhD
Department of Paediatrics, Murdoch Children's Research Institute, The University of Melbourne
50 Flemington Road, Parkville, Victoria 3052
Australia   

Publication History

Received: 07 September 2021

Accepted: 05 November 2021

Accepted Manuscript online:
09 November 2021

Article published online:
17 January 2022

© 2022. Thieme. All rights reserved.

Georg Thieme Verlag KG
Rüdigerstraße 14, 70469 Stuttgart, Germany

  • References

  • 1 Leebeek FWG, Eikenboom JCJ. Von Willebrand's disease. N Engl J Med 2016; 375 (21) 2067-2080
  • 2 Moake JL, Turner NA, Stathopoulos NA, Nolasco LH, Hellums JD. Involvement of large plasma von Willebrand factor (vWF) multimers and unusually large vWF forms derived from endothelial cells in shear stress-induced platelet aggregation. J Clin Invest 1986; 78 (06) 1456-1461
  • 3 Biguzzi E, Castelli F, Lijfering WM. et al. Rise of levels of von Willebrand factor and factor VIII with age: Role of genetic and acquired risk factors. Thromb Res 2021; 197: 172-178
  • 4 Hoq M, Karlaftis V, Mathews S. et al. A prospective, cross-sectional study to establish age-specific reference intervals for neonates and children in the setting of clinical biochemistry, immunology and haematology: the HAPPI Kids study protocol. BMJ Open 2019; 9 (04) e025897
  • 5 Oliver S, Lau KKE, Chapman K, Favaloro EJ. Laboratory testing for von Willebrand factor multimers. In: Favaloro EJ, Lippi G. eds. Hemostasis and Thrombosis. Vol 1646. Methods in Molecular Biology. New York, NY: Springer; 2017: 495-511
  • 6 Andrew M, Vegh P, Johnston M, Bowker J, Ofosu F, Mitchell L. Maturation of the hemostatic system during childhood. Blood 1992; 80 (08) 1998-2005
  • 7 Flanders MM, Crist RA, Roberts WL, Rodgers GM. Pediatric reference intervals for seven common coagulation assays. Clin Chem 2005; 51 (09) 1738-1742
  • 8 Appel IM, Grimminck B, Geerts J, Stigter R, Cnossen MH, Beishuizen A. Age dependency of coagulation parameters during childhood and puberty. J Thromb Haemost 2012; 10 (11) 2254-2263
  • 9 Klarmann D, Eggert C, Geisen C. et al. Association of ABO(H) and I blood group system development with von Willebrand factor and factor VIII plasma levels in children and adolescents. Transfusion 2010; 50 (07) 1571-1580
  • 10 Toulon P, Berruyer M, Brionne-François M. et al. Age dependency for coagulation parameters in paediatric populations. Results of a multicentre study aimed at defining the age-specific reference ranges. Thromb Haemost 2016; 116 (01) 9-16
  • 11 Pechmann A, Wellmann S, Stoecklin B, Krüger M, Zieger B. Increased von Willebrand factor parameters in children with febrile seizures. PLoS One 2019; 14 (01) e0210004
  • 12 Pasala S, Fiser RT, Stine KC, Swearingen CJ, Prodhan P. von Willebrand factor multimers in pediatric extracorporeal membrane oxygenation support. ASAIO J 2014; 60 (04) 419-423
  • 13 Katz JA, Moake JL, McPherson PD. et al. Relationship between human development and disappearance of unusually large von Willebrand factor multimers from plasma. Blood 1989; 73 (07) 1851-1858
  • 14 Weinstein MJ, Blanchard R, Moake JL, Vosburgh E, Moise K. Fetal and neonatal von Willebrand factor (vWF) is unusually large and similar to the vWF in patients with thrombotic thrombocytopenic purpura. Br J Haematol 1989; 72 (01) 68-72
  • 15 Pikta M, Zemtsovskaja G, Bautista H. et al. Preclinical evaluation of a semi-automated and rapid commercial electrophoresis assay for von Willebrand factor multimers. J Clin Lab Anal 2018; 32 (06) e22416

Zoom Image
Fig. 1 Representative electrophoresis gel demonstrating vWF multimer patterns in a healthy adult (lane 1), <2 year old (lane 2), and a neonate (lane 3). Representative densitograms for lane 1(B), lane 2(C), and lane 3(D) are also shown. vWF, von Willebrand factor.