Introduction
Nephrotic syndrome (NS) is a common chronic
glomerular disease in children (1).
The typical clinical manifestations are significant proteinuria,
edema, low concentrations of serum albumin and
hypercholesterolemia. However, other symptoms can be present,
including hypocalcemia, hyperparathyroidism, osteoporotic fractures
and other metabolic abnormalities. Glucocorticoid is the preferred
treatment for NS. However, the long-term administration of large
quantities of glucocorticoids may result in glucocorticoid-induced
osteoporosis by inhibiting the formation of osteoblasts,
stimulating bone resorption and contributing to a negative calcium
balance (2–4).
In recent years, several studies have suggested that
Dickkopf-1 (DKK-1) inhibits bone formation by its inhibition of the
WNT signaling pathway (5). It is a key
factor in maintaining the imbalance between bone resorption and
replacement. DKK-1 inhibits WNT signaling in cells by binding to
the DKK-1 receptors, thus preventing bone marrow stromal cells from
differentiating into bone cells, whereas it also induces the
differentiation and development of osteoclasts (6). DKK-1 expression has been used as a
biomarker of bone metabolism disorders in adults (7). The role of DKK-1 in diseases of bone loss
and the treatment of certain diseases by inhibiting DKK-1 have
recently become topical (8). However,
there has been limited research into secondary osteoporosis caused
by kidney disease.
Tartrate-resistant acid phosphatase 5b (TRACP-5b) is
an iron-containing glycoprotein (9).
Osteoclasts predominantly secrete TRACP-5b into serum, implying
that serum TRACP-5b has a unique specificity as a biomarker of
osteoclast activity, and it is therefore a useful marker of bone
resorption (10). Based on this, serum
TRACP-5b is used clinically as a serum marker for the diagnosis of
osteoporosis. However, there has been limited research into
TRACP-5b levels in preschoolers with NS.
Therefore, 50 preschoolers with NS and 20 healthy
preschooler children (control group) were the research subjects in
the present study. The serum levels of DKK-1 and TRACP-5b were
investigated prior to treatment and 3 and 6 months after treatment,
and these proteins were identified as novel biomarkers of abnormal
bone metabolism in NS patients.
Materials and methods
Patients and data collection
All the subjects provided written informed consent,
and the study was approved by the Ethics Committee of The First
Affiliated Hospital of Zhengzhou University (Zhengzhou, Henan,
China). The study sample comprised a consecutive series of children
who were admitted to the Department of Pediatrics, The First
Affiliated Hospital of Zhengzhou University between January 2012
and December 2013. In total, 50 preschool (<5 years old)
children (34 males, 16 females) who were diagnosed with primary NS
and 20 healthy preschool children (control group) were enrolled.
The patients were diagnosed with primary NS according to the
criteria of the International Study of Kidney Disease in Children
(11), and had no history of prior
treatment with glucocorticoids or other immunosuppressive agents.
The exclusion criteria of all subjects included the previous use of
glucocorticoids or other immunosuppressive agents,
hyperparathyroidism, chronic hepatitis, congenital bone disease,
multiple myeloma, chronic diarrhea, bone metastasis of a malignant
tumor, diabetes and thyroid disease.
The control group received no drug treatment. All
the NS patients received a sufficient amount of glucocorticoid to
induce remission and consolidation. To induce remission, the
patients were treated with 2 mg/kg/day of prednisone, to a maximum
dose of 80 mg/day, in divided doses. The patients were administered
prednisone every morning when their urine protein was negative and
the treatment was continued for 6 weeks. The dose of prednisone was
decreased by 1.5 mg/kg for the next day for 6 weeks and was
subsequently reduced gradually, so that in general, the treatment
was discontinued with 9–12 months. The children were followed-up
for 6 months from the time of diagnosis.
The serum levels of calcium, phosphorus, TRACP-5b,
DKK-1, 25-hydroxyvitamin D3 [25(OH)D3] and albumin were measured
prior to treatment and at 3 and 6 months after treatment in the NS
group, and were measured at enrolment in the control group. The
gender and ages of all the patients were recorded.
Measurements
Venous blood (3 ml) was collected from the NS
patients prior to treatment and at 3 and 6 months after treatment.
Venous blood samples were also collected from the healthy controls
in the same way. All samples were centrifuged at 1,000 rpm for 15
min to remove the cellular components, and the supernatants were
frozen in aliquots at −80°C until analysis.
The serum levels of DKK-1 (Ameko Medical Industries,
Shanghai, China) and TRACP-5b (Cusabio Biotech Co., Ltd., Wuhan,
China) were measured with enzyme-linked immunosorbent assays in
accordance with the manufacturer's protocol. The lowest limit of
DKK-1 detected with this assay was 1.25 pg/ml. The intra-assay
precision was <9% and the inter-assay precision was <15%. The
lowest limit of TRACP-5b detected with this assay was 0.078 U/l.
The intra-assay precision was <8% and the inter-assay precision
was <10%.
Statistical analysis
SPSS 20.0 (IBM, Corp., Armonk, NY, USA) was used for
all statistical analyses. Continuous data are expressed as the mean
± standard deviation or median (interquartile range), as
appropriate. The normally distributed continuous variables of the
two groups were compared with Student's t-test. When the variables
were not normally distributed, the Mann-Whitney and Kruskal-Wallis
tests were used. Dichotomous data were assessed using χ2
test. In all tests, P<0.05 was considered to indicate a
statistically significant difference.
Results
Characteristics and biochemical
parameters
The characteristics and biochemical parameters of
the patients are listed in Table I. In
total, 50 NS patients and 20 healthy children were enrolled. There
were no significant differences in the age or gender distributions
between the two groups (P>0.05). The serum calcium, albumin and
25(OH)D3 levels were higher in the control group compared to the NS
group prior to starting treatment (P<0.05).
 | Table I.General and biochemical
characteristics of the study groups. |
Table I.
General and biochemical
characteristics of the study groups.
| Variable | NS group | Control group | t/χ2 | P-value |
|---|
| Total, n | 50 | 20 |
|
|
| Gender, n
(male/female) | 34/16 | 11/9 |
1.052 | 0.305 |
| Age, years |
3.19±0.98 |
3.02±0.78 |
0.825 | 0.414 |
| Serum calcium,
mmol/l |
1.94±0.17 |
2.34±0.62 | −8.454 | 0.000 |
| Serum phosphorus,
mmol/l |
1.65±0.40 |
1.38±0.47 |
0.259 | 0.797 |
| 25-hydroxyvitamin D3,
ng/ml |
6.81±5.03 |
43.05±3.16 | −27.743 | 0.000 |
| Serum albumin,
g/l |
18.9±5.0 |
42.82±4.83 | −15.929 | 0.000 |
| Total urine protein,
g/day |
1.80±0.81 |
|
|
As shown in Tables II
and III, there was no significant
difference between the levels of serum calcium and phosphorus in
the two groups after the NS group had been treated for 3 or 6
months (P>0.05).
| Table II.Biochemical characteristics of the NS
group after treatment for 3 months. |
Table II.
Biochemical characteristics of the NS
group after treatment for 3 months.
| Variable | NS group | Control group | t | P-value |
|---|
| Serum calcium,
mmol/l |
2.38±0.17 |
2.34±0.62 | −0.368 | 0.714 |
| Serum phosphorus,
mmol/l |
1.67±0.19 |
1.38±0.47 | 0.573 | 0.569 |
| 25-hydroxyvitamin D3,
ng/ml |
24.86±3.05 |
43.05±3.16 | −6.186 | 0.000 |
| Serum albumin,
g/l |
42.8±5.74 |
42.82±4.83 | 1.258 | 0.214 |
| Total urine protein,
g/day |
0.12±0.06 |
|
|
|
| Table III.Biochemical characteristics of the NS
group after treatment for 6 months. |
Table III.
Biochemical characteristics of the NS
group after treatment for 6 months.
| Variable | NS group | Control group | t | P-value |
|---|
| Serum calcium,
mmol/l |
2.30±0.17 |
2.34±0.62 | −0.903 | 0.371 |
| Serum phosphorus,
mmol/l |
1.60±0.18 |
1.38±0.47 | −0.324 | 0.748 |
| 25-hydroxyvitamin D3,
ng/ml |
30.45±4.91 |
43.05±3.16 | −7.047 | 0.000 |
| Serum albumin,
g/l |
41.86±4.51 |
42.82±4.83 | 0.720 | 0.475 |
| Total urine protein,
g/day |
0.10±0.04 |
|
|
|
Table IV shows the
levels of serum DKK-1 in the NS group prior to treatment and 3 and
6 months after treatment. Prior to treatment, the levels of serum
DKK-1 and TRAP-5b were higher in the NS group compared to the
control group (P<0.05), whereas after 3 and 6 months treatment,
there was no significant difference between the two groups
(P>0.05).
| Table IV.Comparison of the DKK-1 and TRACP-5b
levels among the NS and control groups at different times. |
Table IV.
Comparison of the DKK-1 and TRACP-5b
levels among the NS and control groups at different times.
|
| DKK-1, pg/ml |
|
| TRACP-5b, U/l |
|
|
|---|
|
|
|
|
|
|
|
|
|---|
| Treatment | NS group | Control group | t | P-value | NS group | Control group | t | P-value |
|---|
| Prior to |
21.7±9.39 |
15.43±2.36 | 2.918 | 0.005 |
5.56±2.99 |
2.01±0.34 | 5.220 | 0.000 |
| After 3 months |
18.4±8.34 |
15.43±2.36 | 1.577 | 0.121 |
2.35±1.47 |
2.01±0.34 | 0.932 | 0.356 |
| After 6 months |
15.1±5.25 |
15.43±2.36 | −0.297 | 0.768 |
2.38±1.59 |
2.01±0.34 | 0.951 | 0.347 |
Table V compares the
correlation between the level of serum DKK-1, TRACP-5b and other
biochemical parameters in the NS group prior to treatment. Pearson
correlation analysis showed that the level of serum DKK-1 prior to
treatment was positively correlated with 24-h urinary protein
excretion (r=0.451, P=0.011 and P<0.05). There were no
correlations between the level of DKK-1 and calcium, phosphorus,
serum albumin and 25(OH)D3 (P>0.05). Pearson correlation
analysis showed that the level of serum TRACP-5b prior to treatment
was positively correlated with 24-h urinary protein excretion and
serum calcium (r=0.850, P=0.000; r=0418, P=0.019, respectively).
There were no correlations between the level of TRACP-5b and
phosphorus, serum albumin and 25(OH)D3 (P>0.05).
| Table V.Pearson correlation analysis among the
levels of serum DKK-1, TRACP-5b and other biochemical parameters in
the nephrotic syndrome group prior to treatment. |
Table V.
Pearson correlation analysis among the
levels of serum DKK-1, TRACP-5b and other biochemical parameters in
the nephrotic syndrome group prior to treatment.
|
| DKK-1 | TRACP-5b |
|---|
|
|
|
|
|---|
| Variable | r | P-value | r | P-value |
|---|
| Serum calcium,
mmol/l | −0.100 | 0.955 | 0.418 | 0.019 |
| Serum phosphorus,
mmol/l |
0.163 | 0.382 | 0.230 | 0.214 |
| Serum albumin,
g/l | −0.042 | 0.821 | 0.151 | 0.417 |
| Total urine
protein, g/day |
0.451 | 0.011 | 0.850 | 0.000 |
| 25-hydroxyvitamin
D3, ng/ml |
0.177 | 0.342 | 0.050 | 0.790 |
Discussion
Several previous studies have demonstrated that
children with primary NS are at risk of metabolic bone disease
(12). Long-term treatment with large
quantities of glucocorticoids may result in glucocorticoid-induced
osteoporosis. Children are particularly susceptible to bone
metabolic disorders, and even osteoporosis, during their growth
stages (13). Several studies have
reported the involvement of DKK-1 and TRACP-5b in primary and
secondary osteoporosis (14,15). However, their levels have not been
analyzed in children with NS. The gold standard for assessing
osteoporosis is the measurement of bone mineral density (16), and although these measurements can be
used to analyze the condition of the human bone mass, variations in
bone morphology are not evident in the early stages of bone
metabolic disorders. The measurement of bone density also involves
certain exposure to radioactivity, and parents are reluctant to
condone radioactive testing. Therefore, this technique is not used
to assess early osteoporosis or in following up osteoporosis in
children. Therefore, it is important to identify an effective
biomarker of bone metabolism. A previous study has indicated that
patients with higher DKK-1 values showed higher sublesional bone
mineral density loss in spinal cord injury (17). Further research is required to
determine whether DKK-1 and/or TRACP-5b have the utility as
biomarkers of bone metabolism.
In the present study, the levels of DKK-1 and
TRACP-5b were higher and 25(OH)D3 was lower in the NS patients
compared to the control group, suggesting that bone metabolic
abnormalities are present in the early stage of NS. Under normal
circumstances, the blood 25(OH)D3 exists in the human body by
combination with a carrier protein. The level of 25(OH)D3 decreased
as the urinary protein excretion increased in children with NS. The
intestinal absorption of calcium decreased in NS patients resulting
in hypocalcemia and hyperparathyroidism. These cause bone
demineralization and osteoporosis. Therefore, DKK-1 and TRACP-5b
were elevated and 25(OH)D3 was reduced early in NS patients.
Furthermore, the long-term administration of glucocorticoids may
increase these abnormalities as glucocorticoids can increase bone
resorption by inhibiting factors that protect the bone (18,19), and
they reduce the expression of a calcium ion transporter and
calcium-binding protein, thus inhibiting the intestinal
reabsorption of calcium (11,20). These factors can reduce bone mineral
density. Additionally, a glucocorticoid receptor is expressed on
the surfaces of osteoblasts, so long-term glucocorticoid therapy
can promote osteoblast apoptosis and reduce the formation of new
bone (21). In the present study,
DKK-1 and TRACP-5b levels in the NS patients and the control group
were not significantly different after the NS patients had been
treated with glucocorticoid for 3 and 6 months, indicating that the
levels of DKK-1 and TRACP-5b can recover to normal in the NS
remission time. This may be due to the glucocorticoid reduction in
the dosage and the total reduction of urine protein leakage.
The present study also identified that the level of
serum DKK-1 prior to treatment was positively correlated with 24-h
urinary protein excretion and the level of serum TRACP-5b prior to
treatment was positively correlated with 24-h urinary protein
excretion and serum calcium. This may also explain the phenomenon
that the levels of DKK-1 and TRACP-5b were higher compared to the
control group in the early stage of NS. However, there were no
correlations between the level of DKK-1 and 25(OH)D3. There were
also no correlations between the levels of TRACP-5b and 25(OH)D3.
This may be associated with the small number of cases.
In conclusion, DKK-1 and TRACP-5b can be used as
novel biomarkers of bone metabolism in children with NS. Bone
metabolic abnormalities exist in patients in the early stage of NS,
prior to initiating treatment with glucocorticoid. However, in the
present study, only preschool children with NS in northern China
were evaluated. Further studies of school-age children and
adolescents are required. These findings should improve the
clinical management of abnormal bone metabolism in children with
NS.
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