Serum pentraxin 3 concentrations in neonates


Upsala Journal of Medical Sciences. 2014; 119: 62–64

LETTER

Serum pentraxin 3 concentrations in neonates

ANDERS LANNERGÅRD1, FREDRIK ROSENSTRÖM1, ERIK NORMANN2 &
ANDERS LARSSON1

1Department of Medical Sciences, Uppsala University, Uppsala, Sweden, and
2Department of Women’s and Children’s Health, Uppsala University, Uppsala, Sweden

Dear Editor,
C-reactive protein (CRP) is one of the most com-

monly used diagnostic biomarkers in the clinical
setting for diagnosing and monitoring of inflamma-
tory and infectious diseases. However, in neonates
several questions remain, regarding the interpretation
of an increased serum CRP concentration during the
first days of life in otherwise healthy newborns, espe-
cially in preterms (1). Pentraxins are endogenous
substances that neutralize or eliminate a variety of
pathogenic agents in concert with the complement
system and macrophages. These complex biological
responses to tissue injury, necrosis, infections, or
immune-related diseases are part of the natural
innate defence system (2). The pentraxin family
consists of proteins with cyclic multimeric struc-
tures. The well-known acute-phase protein CRP
belongs to the short members of the family, while
pentraxin 3 (PTX3) belongs to the long counter-
parts. PTX3 is released from macrophages and endo-
thelial cells among a great variety of other cell types
in which the protein is synthesized and stored. On
stimuli from primary inflammatory signal proteins,
as interleukin-1 (IL-1), tumour necrosis factor-alpha
(TNF-a), and microbial lipopolysaccharides (LPS)
as well as toll-receptor-mediated signals, PTX3 will
be synthesized, and the serum concentration will
increase up to 100-fold in 6–8 hours. Interleukin-6
(IL-6) is a weak inducer for PTX3 (3,4). PTX3
synthesis is thus produced close to the site of inflam-
mation and is not dependent on cytokine production
or liver function.

All subjects in our study were recruited from the
Department of Women’s and Children’s Health,
Uppsala University Hospital, Uppsala, Sweden.
Three groups were included: umbilical venous cord
blood collected from term healthy newborns (n = 36),
venous blood from term healthy newborns at 3–7 days
of age at phenylketonuria (PKU) testing (n = 11), and
venous blood from very preterm (VPT) newborns at
the neonatal supportive care unit (n = 40). The
median gestational age and postnatal age were
26 weeks (range 23–31, IQR 4) and 27 days (range
4–103, IQR 26), respectively. The median birth
weight was 954 g (range 422–2244, IQR 400). The
study was approved by the local Ethical Review Board
of Uppsala University. Serum PTX3 was determined
by a commercial sandwich ELISA kit (DY1826, R&D
Systems, Minneapolis, MN, USA), as described else-
where (5).
Serum concentrations of PTX3 in term healthy

newborns were lower than in term healthy newborns
at 3–7 days of age and VPT newborns at the support-
ive care unit (P < 0.0001) (Figure 1). VPT newborns
showed a lower serum concentration of PTX3 than
term healthy newborns at 3–7 days of age (P < 0.0001)
(Figure 1). To our knowledge, no studies have pre-
sented such data before. Previous studies on serum
amyloid A and high-sensitivity (hs) CRP reported
gestational age-related differences, with higher con-
centrations in VPT compared with full-term healthy
babies, during the neonatal period (6-8). A similar
pattern seems to apply to PTX3. Because PTX3
may be a faster acute-phase protein that is not

Correspondence: Dr Anders Lannergård, MD, PhD, Department of Medical Sciences, Section of Infectious Diseases, Uppsala University, S-751 85 Uppsala,
Sweden. E-mail: anders.lannergard@akademiska.se

(Received 17 October 2013; accepted 19 December 2013)

ISSN 0300-9734 print/ISSN 2000-1967 online � 2014 Informa Healthcare
DOI: 10.3109/03009734.2013.878770

http://informahealthcare.com/journal/ups
mailto:anders.lannergard@akademiska.se


liver-dependent, it is probable that it is superior to
traditional biomarkers for mirroring rapid inflamma-
tory courses. Compelling indications are present that
a high serum concentration of PTX3 predicts shock,
poor outcome, and organ failure in meningococcal
disease and severe sepsis, respectively, in children and
adults (9,10).
The serum concentration of PTX3 in the cohort

should be interpreted with care because a part of the
sample was likely to have its origin from infants
treated with antibiotics or with inflammatory reac-
tions. It is important to remember that there is an
extremely rapid foetal development up to the
expected day of delivery. This means that there will
be differences between a prematurely born child with
a gestation age of 30 weeks from a child with a
gestation age of 36 weeks. The cause of the prema-
turity may also involve inflammatory reactions which
will further increase the variability in PTX3 values in
samples from prematurely born babies. Nevertheless,
the prematurely born cohort, despite the existence of
possible factors that may influence the serum
PTX3 concentration, could be representative for
this group of newborn infants.
In summary, serum PTX3 may be a promising

acute-phase protein for interpretation of affected new-
borns with symptoms and signs of sepsis. Serum
PTX3 is measurable in both term and preterm babies
in similarity with other acute-phase proteins. Consid-
ering the promising results from studies in adult
patients with sepsis, PTX3 might represent a helpful
tool in diagnosis of sepsis in the neonate as well. The
predictive value of PTX3 may thus be higher com-
pared with conventionally used acute-phase proteins.
However, regarding serum PTX3 concentrations in

infants with infection we propose a prospective study
on neonatal sepsis with well-defined established
criteria.

Acknowledgements

The staff members at Uppsala University Hospital
have skilfully assisted throughout this study.

Declaration of interest: Financial support by the
Faculty of Medicine, Uppsala University is gratefully
acknowledged. The authors report no conflicts of
interest. The authors alone are responsible for the
content and writing of the paper.

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0

2

4

6

8

10

12

Term healthy
newborns

Term healthy
newborns at

3-7 days of age

Very preterm (VPT)
newborns

P
T

X
3
 (

mg
/L

)

P < 0.0001

P < 0.0001 NS

Figure 1. Serum concentrations in term healthy newborns (n = 36), term healthy newborns at 3-7 days of age (n = 11), and very preterm
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PTX3 in neonates 63

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	ss1
	Acknowledgements
	Declaration of interest
	References