Introduction
Cerebral hemorrhage is a serious disease that has
high disability and mortality rates (1–3).
Therefore, an indicator that is closely associated with clinical
manifestations, that may be measured quickly and gives a good
prediction of the mortality rate, would be beneficial in the early
prognosis of cerebral hemorrhage. Currently, it is considered that
cerebral hemorrhage-related hematoma formation (4,5),
increased bleeding and persistent hypertension are associated with
early neurological degeneration and poor prognosis (6).
Arginine vasopressin (AVP), which is one of the most
important stress hormones, is a bioactive peptide with nine amino
acid residues, that is produced by the hypothalamus (7). However, when AVP is released into the
blood in pulse mode, it is extremely unstable with a short
biological half-life. Thus, the clinical application of AVP
measurement is limited. Copeptin (5 kDa) is the 39-amino acid
carboxy-terminal domain of pro-AVP, which includes a leucine-rich
core fragment. AVP and copeptin are released equally in the body,
thus the direct measurement of AVP may be replaced by the
measurement of copeptin (8).
Copeptin is important in the maturation, transportation and
intracellular processing of AVP and it enables the misfolded
monomers to re-fold, to ensure the stability of its biological
effects (9).
Copeptin levels are considered to reflect the
severity and prognosis of a variety of diseases. Jochberger et
al(10) compared the serum
copeptin levels of 70 healthy individuals with those of 157
intensive care unit (ICU) patients within 24 h of cardiac surgery
and identified that the copeptin levels of the ICU group were
significantly higher than those of the healthy individuals. Neuhold
et al(11) performed a
1-year follow-up of 786 patients with various stages of heart
failure and revealed that copeptin was the most effective predictor
of mortality in New York Heart Association (NYHA) stage II and III
patients. Voors et al(12)
completed a 2-year follow-up of 224 patients and identified that
copeptin was an effective prognostic indicator of heart failure
following acute myocardial infarction (AMI); it was found to be
more effective than the currently accepted indicators, B-type
natriuretic peptide (BNP) and amino-terminal B-type natriuretic
peptide (NT-proBNP).
In the current study, copeptin was identified to be
significantly elevated in the serum of acute cerebral hemorrhage
patients and the levels of copeptin increased as the amount of
bleeding and cerebral hemorrhage worsened. Logistic regression
analysis revealed that copeptin level, Glasgow coma scale (GCS)
score and Hemphill score were independent indicators in the
evaluation of impaired 90-day nerve function following cerebral
hemorrhage.
Materials and methods
Patients
A total of 120 patients with acute intracerebral
hemorrhage (ICH) were enrolled, including 76 males and 44 females.
Sixty healthy individuals were selected as a control group. Prior
written and informed consent was obtained from every patient and
the study was approved by the ethics review board of Ji Ning
Medical University (Shandong, China).
Clinical evaluation
The severity of ICH was assessed. The hematoma
volume was calculated based on a brain computed tomography (CT)
scan with ABC/2 methods (A, the maximum diameter of the maximum
bleeding layer; B, the diameter of the vertical to A; C, the number
of vertical planes multiplied by the thickness of each layer). The
GCS and Hemphill ICH scores were calculated. A prognostic
evaluation of impaired nerve function was performed according to
the Rankin scale score (modified Rankin scale, mRS) after 90 days.
A positive outcome was defined as mRS<3 and a poor outcome was
defined as mRS≥3.
Vital signs and biochemical
indicators
Fasting blood glucose, white blood cell count and
serum sodium were determined. Body temperature, systolic blood
pressure and diastolic blood pressure were also measured.
Enzyme-linked immunosorbent assay
(ELISA)
Venous blood (3 ml) was drawn when fasting and
centrifuged for 10 min at 3,000 rpm to collect plasma. The serum
following centrifugation was stored at −80°C in a refrigerator.
Copeptin levels were assessed by ELISA. The ELISA kit was purchased
from Phoenix Pharmaceuticals (Burlingame, CA, USA).
Statistical analysis
Statistics analyses were carried out using SPSS 19.0
software (SPSS Inc., Chicago, IL, USA). Continuous variables were
expressed as the mean ± standard deviation. An independent samples
t-test was used when comparing two groups. The Chi-square test was
applied to enumeration data. The prognostic accuracy of copeptin
and other prognostic parameters were analyzed with univariate and
multivariate logistic regression models. Spearman's Rho was applied
in the correlation analysis. P<0.05 was considered to indicate a
statistically significant difference.
Results
Clinical characteristics
Among the 120 ICH patients, there were 76 males and
44 females with ages from 32 to 84 years. Bleeding sites differed
among the patients: 96 cases were in the basal ganglia region
(80%), 12 cases were in a lobe of the brain (10%), 6 cases were in
the brain stem (5%) and 6 cases were in the cerebellum (5%). The
average plasma copeptin level of the 120 ICH patients was 3.71±0.82
ng/ml compared with 2.82±0.36 ng/ml for the control group of
healthy individuals. General clinical data of the ICH patients are
listed in Table I.
 | Table I.General clinical data of the patients
in this study. |
Table I.
General clinical data of the patients
in this study.
| Variable | n=120 | High copeptin group
(n=58) | Low copeptin group
(n=62) | Test value | P-value |
|---|
| Male/total (%) | 76 (63%) | 32 (55%) | 44 (71%) | 1.78a | 0.075 |
| Age (years) | 60±14 | 60±13 | 61±14 | −0.59 | 0.554 |
| Body temperature
(°C) | 36.4±0.5 | 36.5±0.6 | 36.4±0.4 | 1.09 | 0.279 |
| Systolic blood
pressure (mmHg) | 175±32 | 181±40 | 169±22 | 2.05 | 0.044 |
| Diastolic blood
pressure (mmHg) | 103±22 | 101±22 | 105±23 | −0.92 | 0.362 |
| White blood cell
count (×1012/l) | 9.98±4.25 | 11.59±4.82 | 8.47±3.04 | 4.25 | 0.000 |
| Blood glucose
(mM) | 6.63±2.41 | 7.50±2.58 | 5.81±1.96 | 4.10 | 0.000 |
| Hyponatremia
(mM) | 142.38±7.53 | 144.28±9.99 | 140.61±3.55 | 2.67 | 0.060 |
| Hematoma volume
(ml) | 57.46±46.76 | 78.68±49.70 | 37.60±34.50 | 5.27 | 0.000 |
| GCS score | 10.60±4.64 | 6.86±3.62 | 14.10±2.12 | −13.39 | 0.000 |
| Hemphill score | 2.05±1.62 | 3.24±1.20 | 0.94±1.08 | 10.99 | 0.000 |
| mRS score | 3.32±1.95 | 4.79±1.23 | 1.94±1.42 | 11.75 | 0.000 |
Copeptin and other prognostic
indicators
Copeptin, Hemphill scores, white blood cell count
and Glasgow coma scale (GCS) were determined on admission.
The copeptin level correlated positively with
hematoma volume (r=0.61, P=0.000), Hemphill score (r=0.78, P=0.000)
and white blood cell count (r=0.58, P=0.000), and negatively with
GCS score (r=−0.79, P=0.000). The average level of copeptin (3.71
ng/ml) divided the high and low copeptin groups (Table I). Analyses revealed that hematoma
volume, GCS score, Hemphill score, mRS score, systolic blood
pressure, white blood cell count and blood glucose differed
significantly between the two groups; however, there were no
significant differences in the other parameters.
Copeptin and prognosis of impaired nerve
function
After 90 days, prognosis of impaired nerve function
was positive in 48 cases (40%) and poor in 72 cases (60%). Plasma
copeptin levels were higher at admission in patients with a poor
prognosis than in those with a positive prognosis (4.14±0.87 vs.
3.09±0.30 ng/ml, t=8.001, P=0.000). Univariate logistic regression
analysis of prognostic indicators of impaired nerve function
revealed that copeptin level, white blood cell count, blood
glucose, brain hemorrhage and Hemphill score were prognostic
indicators (Table II).
Multivariate logistic regression analysis revealed that copeptin
level, GCS score and Hemphill score were independent prognostic
factors for cerebral hemorrhage (Table
III).
| Table II.Univariate logistic regression
analysis of prognostic indicators of impaired nerve function. |
Table II.
Univariate logistic regression
analysis of prognostic indicators of impaired nerve function.
| Prognostic
indicators | OR | 95% CI | P-value |
|---|
| White blood cell
count | 1.06 | 1.01–1.12 | 0.003 |
| Blood glucose | 1.09 | 1.01–1.18 | 0.002 |
| Hemphill score | 2.19 | 1.46–3.27 | 0.000 |
| GCS score | 1.62 | 0.96–2.43 | 0.001 |
| Hematoma volume | 1.02 | 1.01–1.04 | 0.000 |
| Copeptin | 3.17 | 2.01–4.35 | 0.003 |
| Table III.Independent prognostic factors for
cerebral hemorrhage. |
Table III.
Independent prognostic factors for
cerebral hemorrhage.
| Prognostic
indicators | OR | 95% CI | P-value |
|---|
| Hemphill score | 1.09 | 0.86–1.27 | 0.000 |
| GCS score | 1.22 | 0.96–1.43 | 0.000 |
| Copeptin | 1.28 | 1.05–1.48 | 0.000 |
Copeptin and mortality rates
During the 90 days of follow-up, 24 patients (20%)
succumbed. The copeptin level was higher in the non-survivors than
in the survivors (4.97±0.73 vs. 3.40±0.46 ng/ml, t=1.58, P=0.000).
Hematoma volume, GCS score, Hemphill score, white blood cell count
and blood glucose were significantly different between the
non-survivors and survivors (Table
IV). No significant differences existed in the other
parameters. Univariate logistic regression analysis revealed that
the copeptin level, white blood cell count, GCS score, Hemphill
score and hematoma volume were valuable for mortality prediction
(Table V).
| Table IV.Prognostic indicators for survivors
and non-survivors. |
Table IV.
Prognostic indicators for survivors
and non-survivors.
| Prognostic
indicators | Survivors (n=96) | Non-survivors
(n=24) | Test value | P-value |
|---|
| Copeptin (ng/ml) | 3.40±0.46 | 4.97±0.73 | 1.58 | 0.000 |
| Hematoma volume
(ml) | 42.39±31.16 | 117.72±50.66 | 75.32 | 0.000 |
| GCS score | 12.25±3.59 | 4.00±1.25 | −8.25 | 0.000 |
| Hemphill score | 1.48±1.26 | 4.33±0.48 | 2.85 | 0.000 |
| Blood glucose
(mM) | 6.39±2.54 | 7.59±1.46 | 1.21 | 0.030 |
| White blood cell
count (×1012/l) | 8.73±2.70 | 14.95±5.57 | 6.21 | 0.000 |
| Table V.Univariate logistic regression
analysis of the 90-day mortality rate of patients. |
Table V.
Univariate logistic regression
analysis of the 90-day mortality rate of patients.
| Prognostic
indicators | OR | 95% CI | P-value |
|---|
| White blood cell
count | 1.21 | 1.01–1.43 | 0.003 |
| GCS score | 0.34 | 0.16–0.72 | 0.001 |
| Hemphill score | 5.14 | 2.05–8.89 | 0.000 |
| Hematoma volume | 1.11 | 1.05–1.17 | 0.000 |
| Copeptin | 5.29 | 3.68–8.03 | 0.000 |
Discussion
The close correlation between copeptin level and
hypothalamic-pituiary-adrenal (HPA) axis activation was the basis
of the use of copeptin as a prognostic biomarker (13–16).
The current study found that the plasma copeptin level increased in
patients with acute ICH. In accordance with the Hemphill score and
GCS score, the level of copeptin increased with the severity of
ICH. Univariate logistic regression analysis indicated that
copeptin level, hematoma volume, GCS score, Hemphill score, white
blood cell count and blood glucose are independent prognostic
indicators for impaired nerve function, 90 days after ICH.
In the acute stage of ICH, the body enters a state
of stress, activated by the HPA axis. Then, corticotropin-releasing
hormone is secreted by the hypothalamic paraventricular nucleus.
AVP is a hypothalamic-stimulating factor in the HPA axis and has a
significant synergistic effect with corticotropin-releasing
hormone. Together, they promote the anterior pituitary to release
adrenocorticotropic hormone and then stimulate the adrenal cortex
to produce cortisol. The level of copeptin increased with the
severity of stress and at a far quicker pace than that of cortisol
in severe stress conditions (15).
Copeptin may receive endogenous information through the thalamus,
thus respond to the damage accurately. However, its mechanism
remains unclear. Cerebral edema in patients with ICH indicates poor
prognosis. The copeptin level may reflect the brain edema formation
and its severity, thus helping to determine the existence of
cerebral edema, which may be treated with an AVP receptor
antagonist.
A previous study demonstrated that higher levels of
copeptin in patients with acute progression of chronic obstructive
pulmonary disease (COPD) indicated significantly prolonged hospital
stay and intensive care unit treatment (17). The Kaplan-Meier survival curve
revealed that copeptin levels were significantly higher in patients
with poor long-term prognosis. Katan et al(15) found that the copeptin level was an
independent predictor of brain function and mortality rate three
months after acute cerebral infarction and it may improve the
accuracy of the National Institute of Health Stroke Score (NIHSS)
on neurological damage prognosis and mortality prediction and thus
further improve the risk stratification of stroke patients. Urwyler
et al(18) performed a
one-year follow-up based on the above studies and found that
copeptin was an independent predictor of brain function and
mortality rates one year after cerebral infarction.
Zweifel et al(16) determined the copeptin levels of 40
patients with spontaneous ICH and the results revealed the
prognostic value of copeptin levels in patients with ICH. However,
due to small sample volumes, clinical studies with larger sample
numbers are required for further validation. If the prognostic
value of copeptin in ICH is verified in large-scale cohort studies,
particularly in combination with other prognostic indicators, the
risk assessment would be improved. In summary, copeptin is expected
to become a new prognostic indicator of ICH.
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