Invest Clin 65(1): 16 - 26, 2024 https://doi.org/10.54817/IC.v65n1a02
Corresponding Author: Feixiong Chen, Department of Cerebrovascular Disease, Second Affiliated Hospital of Kun-
ming Medical University, No. 374 Yunnan-Burma Road, Wuhua District, Kunming, Yunnan, 650106, China. Phone:
+86-15808893575. Email: hbchenfx@163.com
Predictive value of intracranial pressure-
related parameters and coagulation
on the prognosis in patients with
traumatic brain injury.
Linna Shen1, Haibin Lu2, Shuibo Yang3 and Feixiong Chen4
1Department of Critical Care Medicine, Yunnan St. John's Hospital, Kunming, China.
2Department of Critical Care Medicine, Daping Hospital, Army Medical University,
Chongqing, China.
3Department of Anesthesiology, People’s Hospital of Yuxi City, Yuxi, China.
4Department of Cerebrovascular Disease, Second Affiliated Hospital of Kunming Medical
University, Kunming, China.
Keywords: brain trauma; intracranial pressure; coagulation; prognosis.
Abstract. This study investigated the factors affecting the prognosis of
patients with traumatic brain injury (TBI) and assessed the predictive value of
intracranial pressure-related parameters and coagulation on prognosis. Seventy
TBI patients admitted between January 2020 and January 2021 were catego-
rized into good prognosis (n=42) and poor prognosis (n=28) groups according
to the Glasgow Outcome Scale (GOS) score upon discharge. Factors affecting
prognosis were analyzed, and differences in intracranial pressure and coagula-
tion between the two groups were compared. The receiver operating charac-
teristic curve (ROC) was used to calculate the predictive value of intracranial
pressure-related parameters and coagulation function on prognosis. Within
24 h postoperatively, the good prognosis group had lower levels of intracra-
nial pressure (ICP) and partial pressure of oxygen in brain tissue (PbtO2) and
higher cerebral perfusion pressure (CPP) and cerebral hemodynamic param-
eters than the poor prognosis group (p<0.05). The good prognosis group had
significantly lower prothrombin time (PT), activated partial thromboplastin
time (aPTT),and prothrombin time (TT) levels and higher platelets (PLT) and
fibrinogen (Fib) levels than the poor prognosis group (p<0.05). Regression
analysis revealed that CPP, systolic blood flow velocity (Vs), end-diastolic blood
flow velocity (Vd), mean blood flow velocity (Vm), PLT, Fib were independent
protective factors for the prognosis, and ICP, PbtO2, PT, APTT, and TT were
risk factors for prognosis. The ROC revealed that ICP, CPP, PbtO2, Vs, Vd, Vm,
APTT, PLT, Fib exhibited high diagnostic value for poor prognosis (AUC=0.732,
0.940, 0.796, 0.706, 0.914, 0.729, 0.876, 0.709, 0.866), with ICP showing the
Factors affecting the prognosis of patients with traumatic brain injuries 17
Vol. 65(1): 16 - 26, 2024
Valor predictivo de los parámetros relacionados con la presión
intracraneal y la coagulación en el pronóstico de pacientes
con traumatismo craneoencefálico.
Invest Clin 2024; 65 (1): 16 – 26
Palabras clave: traumatismo cerebral; presión intracraneal; coagulación; pronóstico.
Resumen. Este estudio investigó factores influyentes en el pronóstico de pa-
cientes con traumatismo craneoencefálico (TCE) y evaluó la utilidad predictiva de
parámetros relacionados con la presión intracraneal y la coagulación. Setenta pa-
cientes ingresados entre enero de 2020 y enero de 2021 se dividieron en dos grupos
según su pronóstico: bueno (n=42) y malo (n=28), según la Escala de Resultados
de Glasgow (GOS) al alta. Se analizaron factores de pronóstico y se compararon
las diferencias en presión intracraneal y coagulación. La curva ROC evaluó el valor
predictivo de estos parámetros. En las primeras 24 horas postoperativas, el grupo
de buen pronóstico mostró menor presión intracraneal (PIC) y mayor presión de
perfusión cerebral (CPP) y parámetros hemodinámicos cerebrales (p<0,05). Tam-
bién presentaron niveles más bajos de tiempo de protrombina (TP), tiempo parcial
de tromboplastina (TTPA) y trombina (TT), y niveles más altos de plaquetas (PLT) y
fibrinógeno (Fib) (p<0,05). El análisis de regresión identificó a CPP, la velocidad de
flujo sistólico (Vs), la velocidad de flujo diastólico (Vd) , la velocidad de flujo medio
(Vm), PLT y Fib como factores protectores independientes, mientras que PIC, oxí-
geno cerebral (PbtO2), TP, TTPA y TT fueron factores de riesgo. La ROC demostró
que PIC, CPP, la presión parcial de oxigeno cerebral (PbtO2), Vs, Vd, Vm, TTPA, PLT
y Fib tenían un alto valor diagnóstico para mal pronóstico (AUC=0.732, 0.940,
0.796, 0.706, 0.914, 0.729, 0.876, 0.709, 0.866), siendo PIC el más sensible y Vd el
más específico. Los parámetros intracraneales y de coagulación se relacionan con
el pronóstico en pacientes con TCE, y mejorar el control de la PIC y la coagulación
puede mejorar la supervivencia.
Received: 17-01-2023 Accepted: 26-09-2023
INTRODUCTION
Traumatic brain injury (TBI) is an in-
jury to the brain caused by a blow or jolt to
the head from blunt or penetrating trauma
where the dura mater remains intact while
the contents of the cranial cavity have not
yet come into contact with the outside. A
blow or bump mainly causes it, or a jolt to
the head, the head suddenly and violently
hitting an object, or when an object pierc-
es the skull and enters brain tissue 1,2. The
highest diagnostic sensitivity and Vd showing the highest diagnostic specificity.
Intracranial pressure-related parameters and coagulation indicators are prog-
nosis-related indexes in patients with TBI, and the prognosis and survival can
be improved by controlling intracranial pressure and improving coagulation.
18 Shen et al.
Investigación Clínica 65(1): 2024
skull of patients with TBI is deformed and
fractured, causing movement of brain tissue
in the cranial cavity, resulting in increased
pressure on the cranial vault, compression of
cerebral vessels, damage to the central ner-
vous system, and inadequate vascular perfu-
sion, which seriously threatens the patients’
lives3. For now, monitoring of intracranial
pressure and pre-and post-operative coagula-
tion can aid in selecting surgical procedures,
and strict control and adjustment of the in-
tracranial pressure can minimize post-oper-
ative mortality in patients. However, their
effect on post-operative recovery and prog-
nostic outcome still needs to be explored 4.
Seventy patients with TBI were enrolled in
this study, and the effects of intracranial
pressure-related parameters and coagula-
tion indicators on prognosis were explored,
aiming to provide new ideas for improving
the quality of prognosis of TBI patients.
MATERIALS AND METHODS
Baseline data
Seventy patients with TBI admitted to
The First People’s Hospital of Yibin between
January 2020 and January 2021 were en-
rolled, and patients with Glasgow Outcome
Scale (GOS) 5 scores of grades III-IV were clas-
sified as the good prognosis group (n=42),
and patients with GOS scores of grades I-II
or death were defined as the poor prognosis
group (n=28). The study has been approved
by the medical ethics committee of The First
People’s Hospital of Yibin. The research ob-
jects and their families were informed, and
they signed a fully informed consent form.
Inclusion criteria: TBI was confirmed by
cranial CT scan, and history of cranial trauma
was determined; patients with TBI confirmed
by clinical examination; patients who sought
medical help within a short period after the
onset of the disease, and there might be pro-
gression; patients who received craniocere-
bral trauma surgery in our hospital. Exclu-
sion criteria: TBI combined with more severe
organ dysfunction; combined or with other
coagulation-related diseases; developed criti-
cal and life-threatening conditions after ad-
mission, with a predicted survival time of less
than three months; incomplete medical re-
cords and lost to follow-up.
METHODS
After patients were enrolled, baseline
data was collected from both groups, includ-
ing gender, age, cause of injury, Glasgow
coma scale (GCS) upon admission, time
from injury to admission, length of stay
in the neurosurgical intensive care unit
(NICU), and parameters related to intracra-
nial pressure (ICP).
In both groups, 5 mL of venous blood
were collected from the anterior region of
the elbow in a fasting state, followed by cen-
trifugation (3000 r/min, 10 min) at 4 °C to
obtain platelet-poor plasma, and was stored
at -80 °C. The coagulation indicators were
measured by an optical coagulation analyzer
(BIObase, XL1000C, China), including pro-
thrombin time (PT), activated partial throm-
boplastin time (APTT), thrombin time (TT),
platelets (PLT), and fibrinogen (Fib) 6,7.
TBI surgery was determined according
to the Guidelines for the Treatment of Major
Craniocerebral Trauma (4th edition), and
ICP, partial oxygen pressure (PbtO2), cere-
bral perfusion pressure (CPP), and cerebral
blood flow velocity were recorded within 24
h after surgery 8,9. ICP was monitored using
an intracranial pressure monitor (HP Inc.,
USA). ICP levels and ICP waveform ampli-
tude were recorded every hour, and non-in-
vasive mean ICP was calculated according to
the potential superposition principle. With a
GMS-5002 oxygen sensor (GMS, Germany),
PbtO2 was measured during surgery and 24
h after surgery with a normal brain area in
the lateral brain as the puncture point by
piercing the electrode and probing the nee-
dle about 34 mm deep into the meninges.
The recording interval was 15 seconds. The
arterial blood pressure was monitored using
a non-invasive blood pressure monitor (HP,
Factors affecting the prognosis of patients with traumatic brain injuries 19
Vol. 65(1): 16 - 26, 2024
USA). The instrument depicted pressure
waves by arterial blood pressure fluctuations.
The mean arterial blood pressure was calcu-
lated with multiple sets of pressure waves.
Cerebral hemodynamics was monitored us-
ing an EK-1000B transcranial Doppler ul-
trasound instrument (Jiangsu Yikang Elec-
tronic Technology Co., Ltd., 201182230620)
with a probe frequency of 2 MHz to detect
cerebral blood flow velocity in the cerebral
arteries, including systolic blood flow veloc-
ity (Vs), end-diastolic blood flow velocity
(Vd), and mean blood flow velocity (Vm) 10.
Follow-up visits
Patients were followed up consistently
for three months after discharge, and GOS
scores were recorded. Grade V (low disabil-
ity): light damage with minor neurological
and psychological deficits; Grade IV (mod-
erate disability): no need for assistance in
everyday life; employment was possible but
may require special equipment; Grade III
(Severe disability): severe injury with perma-
nent need for help with daily living, Grade II
(Persistent vegetative state): severe damage
with prolonged state of unresponsiveness
and a lack of higher mental functions; Grade
I (Death): severe injury or death without re-
covery of consciousness.
Statistical analysis
The data of this study were analyzed
using IBM® SPSS 22.0 software. The count
data were expressed as n and % and exam-
ined by the χ2 test. The measurement data
were expressed by (x±sd) and examined by
the t-test. The correlation of intracranial
pressure-related parameters with coagula-
tion function and poor prognosis was ana-
lyzed using the Pearson correlation analysis.
Binary logistic regression was used to ana-
lyze the factors influencing the prognosis of
TBI, and the ROC was used to calculate the
predictive value of intracranial pressure-re-
lated parameters and coagulation for prog-
nosis. An area under the curve (AUC) of 0.7
to 0.9 represents a specific predictive value,
and an AUC > 0.9 represents a higher pre-
dictive value. p<0.05 represents a statisti-
cally significant difference.
RESULTS
Comparison of baseline data
There were no significant differences be-
tween the two groups in terms of gender, age,
cause of injury, GCS score upon admission,
time from injury to admission, duration of
ICP-related parameter monitoring, and dura-
tion of NICU stay (p>0.05) (Table 1).
Comparison of intracranial pressure-
related parameters between the two groups
Within 24 h after surgery, patients in
the good prognosis group had significantly
lower ICP and PbtO2 levels and significantly
higher CPP and cerebral hemodynamic in-
dexes than those in the poor prognosis group
(p<0.05) (Table 2).
Changes in coagulation in both groups
Within 24 h after surgery, patients in the
good-prognosis group had significantly lower
PT, APTT, and TT levels and significantly high-
er PLT and Fib levels than those in the poor-
prognosis group (p<0.05) (Table 2).
The predictive value of intracranial
pressure-related parameters and
coagulation on prognosis
ICP, PbtO2, PT, APTT, TT were signifi-
cantly positively correlated with poor progno-
sis, and CPP, Vs, Vd, Vm, PLT, and Fib were
significantly negatively correlated with poor
prognosis (p<0.05, Table 3). Logistic regres-
sion analysis revealed that CPP, Vs, Vd, Vm,
PLT, and Fib were prognostic independent
protective factors, and ICP, PbtO2, PT, APTT,
and TT were prognostic risk factors (Table 4).
ICP, CPP, PbtO2, Vs, Vd, Vm, APTT, PLT, and
Fib exhibited high diagnostic value for poor
prognosis (AUC>0.7), with ICP showing the
highest diagnostic sensitivity and Vd showing
the highest diagnostic specificity (Table 5
and Fig. 1).
20 Shen et al.
Investigación Clínica 65(1): 2024
DISCUSSION
Closed craniocerebral trauma is a com-
mon and severe TBI, and its incidence in-
creases year by year. Compared with open
craniocerebral trauma, the symptoms and
signs of closed craniocerebral trauma are
less obvious, but its potential harm cannot be
ignored. Patients with closed craniocerebral
trauma not only face the threat of life safety
but also may lead to long-term neurological
dysfunction and decreased quality of life.
Table 1
Comparison of general information between the two groups.
Variable Good prognosis
group (n=42)
Poor prognosis
group (n=28)
t/χ2 values p
Gender (m/f, n) 23/19 15/13 0.010 0.922
Age (years) 41.72±14.48 43.88±15.36 0.597 0.553
Cause of injury Blow 8 (19.05) 6 (21.43) 0.060 0.807
Fall 11 (26.19) 8 (28.57) 0.048 0.826
Traffic accidents 16 (38.10) 11 (39.29) 0.010 0.920
Other 7 (16.67) 3 (10.71) 0.486 0.486
Admission GCS score 8.45±3.04 7.84±2.42 0.890 0.377
Time from injury to admission (hours) 2.25±1.53 2.40±1.32 0.424 0.673
Duration of ICP-related parameters
monitoring (hours)
148.68±10.72
151.76±12.19
1.115
0.269
Length of stay in NICU (hours) 90.59±40.43 79.48±48.37 1.041 0.302
Glasgow Coma Score (GCS), Intracranial Pressure (ICP), Neurosurgical Intensive Care Unit (NICU).
Table 2
Comparison of intracranial pressure-related parameter and coagulation parameters
between the two groups.
Variable Good prognosis
group (n=42)
(x±sd)
Poor prognosis
group (n=28)
(x±sd)
t/χ2 values p
ICP (mmHg) 14.00±5.70 26.25±13.49 5.239 ≤0.001
CPP (mmHg) 81.18±6.94 48.98±19.95 9.650 ≤0.001
PbtO2 (mmHg) 9.17±5.62 19.31±9.58 5.580 ≤0.001
Hemodynamics
(cm/s)
Vs 84.75±13.24 75.24±11.30 3.117 0.003
Vd 57.86±7.50 46.53±4.75 7.092 ≤0.001
Vm 53.44±6.61 46.38±8.85 3.818 ≤0.001
PT (s) 13.27±2.89 15.47±3.10 3.031 0.003
APTT (s) 30.52±3.63 37.93±5.54 6.769 ≤0.001
TT (s) 17.30±3.18 19.29±3.98 2.318 0.023
PLT (109/L) 148.62±45.69 119.41±30.28 2.972 0.004
Fib (g/L) 2.51±0.35 2.12±0.15 6.399 ≤0.001
Intracranial pressure (ICP), cerebral perfusion pressure (CPP), partial pressure of oxygen in brain tissue (PbtO2), systolic
blood flow velocity (Vs), end-diastolic blood flow velocity (Vd), mean blood flow velocity (Vm), prothrombin time (PT),
activated partial thromboplastin time (aPTT), prothrombin time (TT), seconds (s), platelets (PLT), fibrinogen (Fib).
Factors affecting the prognosis of patients with traumatic brain injuries 21
Vol. 65(1): 16 - 26, 2024
Predicting the prognosis of patients
with closed craniocerebral trauma has been
the focus of the medical community. Under-
standing the prognostic influencing factors
and effective predictive indicators can help
doctors better assess patients’ conditions
and predict their future development trends
and provide an important basis for clinical
decision-making to take timely intervention
measures to improve patient prognosis.
TBI is frequent in the neurosurgical
emergency setting, with a mortality rate
of 30%-50% for severe TBI, resulting in dis-
ability or other types of complications. For
TBI, a hard blow to the head could cause
an intracranial hematoma, cerebral edema,
brain herniation due to brain tissue disloca-
tion, and elevated ICP (ICP >20 mm Hg for
more than 15 min within one hour of the
blow), which threaten the life and health of
the patient 11,12. Due to an increase in deadly
traffic accidents, falls on construction sites,
and collisions, the incidence of TBI is show-
ing an increasing trend 13. For the current
treatment options of TBI, decompressive
craniectomy and cerebrospinal fluid drain-
age, nutritional support, and ICP monitor-
ing can significantly reduce the length of
Table 3
Correlation analysis of intracranial pressure-related parameters, coagulation and poor prognosis.
Variable ICP CPP PbtO2Vs Vd Vm PT APTT TT PLT Fib
r 0.394 -0.746 0.502 -0.349 -0.703 -0.388 0.316 0.638 0.257 -0.355 -0.559
p 0.001 ≤0.001 ≤0.001 0.003 ≤0.001 0.001 0.008 ≤0.001 0.032 0.003 ≤0.001
Intracranial pressure (ICP), cerebral perfusion pressure (CPP), partial pressure of oxygen in brain tissue (PbtO2),
systolic blood flow velocity (Vs), end-diastolic blood flow velocity (Vd), mean blood flow velocity (Vm), prothrombin
time (PT), activated partial thromboplastin time (aPTT), prothrombin time (TT), platelets (PLT), fibrinogen (Fib),
r (Pearson correlation coefficient).
Table 4
Factors influencing the prognosis of patients with TBI.
Variable B S.E. Wald p Exp (B) 95% EXP (B) Confidence interval
lower limit upper limit
ICP 0.121 0.032 14.458 ≤0.001 1.129 1.060 1.201
CPP -0.204 0.051 16.078 ≤0.001 0.815 0.738 0.901
PbtO2 0.169 0.043 15.266 ≤0.001 1.184 1.088 1.289
Vs -0.065 0.024 7.511 0.006 0.937 0.894 0.982
Vd -0.286 0.068 17.716 ≤0.001 -798 0.657 0.858
Vm -0.124 0.039 10.168 0.001 0.883 0.818 0.953
PT 0.250 0.091 7.499 0.006 1.284 1.074 1.535
APTT 0.358 0.084 18.367 ≤0.001 1.431 1.215 1.686
TT 0.163 0.074 4.805 0.028 1.177 1.017 1.361
PLT -0.018 0.007 7.422 0.006 0.982 0.969 0.995
Fib -4.780 1.213 15.533 0.000 0.0080 0.001 0.090
B>1 is a risk factor and B<1 is a protective factor.
Intracranial pressure (ICP), cerebral perfusion pressure (CPP), partial pressure of oxygen in brain tissue (PbtO2),
systolic blood flow velocity (Vs), end-diastolic blood flow velocity (Vd), mean blood flow velocity (Vm), prothrombin
time (PT), activated partial thromboplastin time (aPTT), prothrombin time (TT), platelets (PLT), fibrinogen (Fib).
22 Shen et al.
Investigación Clínica 65(1): 2024
Table 5
Analysis of the predictive value of intracranial pressure-related parameters and coagulation
for poor prognosis.
Variable AUC Jorden
index
Sensitivity Specificity Standard
Error
Asymptotic 95%
confidence interval
p lower
limit
upper
limit
ICP 0.732 0.547 0.976 0.571 0.069 0.001 0.598 0.867
CPP 0.940 -0.834 0.905 0.071 0.036 ≤0.001 0.869 1.000
PbtO20.796 0.523 0.952 0.571 0.055 ≤0.001 0.687 0.905
Vs 0.706 -0.416 0.452 0.036 0.062 0.004 0.585 0.827
Vd 0.914 0.095 0.893 0.893 0.037 ≤0.001 0.841 0.987
Vm 0.729 -0.488 0.952 0.464 0.064 0.001 0.604 0.854
PT 0.686 0.345 0.881 0.464 0.065 0.009 0.559 0.814
APTT 0.876 0.679 0.929 0.750 0.049 ≤0.001 0.779 0.973
TT 0.651 0.310 0.881 0.429 0.069 0.033 0.516 0.787
PLT 0.709 -0.464 0.500 0.036 0.063 0.003 0.586 0.833
Fib 0.866 0.691 0.929 0.762 0.047 ≤0.001 0.775 0.958
Area under the curve (AUC) Intracranial pressure (ICP), cerebral perfusion pressure (CPP), partial pressure of
oxygen in brain tissue (PbtO2), systolic blood flow velocity (Vs), end-diastolic blood flow velocity (Vd), mean blood
flow velocity (Vm), prothrombin time (PT), activated partial thromboplastin time (aPTT), prothrombin time (TT),
platelets (PLT), fibrinogen (Fib).
Fig. 1. ROC analysis of the predictive value of intracranial pressure and coagulation function on adverse prognosis.
Intracranial pressure (ICP), cerebral perfusion pressure (CPP), partial pressure of oxygen in brain tissue (PbtO2),
systolic blood flow velocity (Vs), end-diastolic blood flow velocity (Vd), mean blood flow velocity (Vm), prothrombin
time (PT), activated partial thromboplastin time (aPTT), prothrombin time (TT), platelets (PLT), fibrinogen (Fib).
Factors affecting the prognosis of patients with traumatic brain injuries 23
Vol. 65(1): 16 - 26, 2024
hospitalization and mortality of patients,
indicating that there is a close link between
the quality of prognosis and ICP levels 14.
In a study by Pan et al. 15 on factors
affecting the prognosis of TBI patients,
patients with favorable outcomes had sig-
nificantly lower average ICP and pressure
reactivity index (PRx) and exhibited signifi-
cantly higher CPP compared with patients
with unfavorable outcomes. ICP is the pres-
sure exerted by fluids such as cerebrospinal
fluid (CSF) inside the skull and on the brain
tissue. When an external blow to the crani-
um triggers cerebral edema, there is an in-
crease in CSF as well as the volume of brain
tissue. Other space-occupying lesions, such
as hematomas, may also occur, causing ob-
struction of the CSF circulation and increas-
ing the CSF pressure and ICP in the cranial
cavity 16,17. In this study, we enrolled patients
with TBI during the same period and found
that the ICP and PbtO2 levels within 24 h
after surgery in patients with good progno-
sis were significantly lower while CPP was
significantly higher than those in the poor
prognosis group, which is consistent with
the findings of other scholars mentioned
above 16,17.
Meanwhile, this study analyzed hemo-
dynamic indices and found that all cerebral
hemodynamics in the poor prognosis group
were lower than those in the good prognosis
group. The results of the correlation analysis
showed a significant negative relationship
between CPP, Vs, Vd, Vm, PLT, and Fib and
poor prognosis (r= -0.746, -0.349, -0.703,
-0.388, -0.355, -0.559, p <0.05). This implies
an association between decreased cerebral
perfusion pressure, venous suction velocity,
velocity of arterial drainage, brain parenchy-
mal volume, PLT count, and Fib and a poor
outcome. Lower cerebral perfusion pressure,
venous suction velocity, arterial drainage ve-
locity, brain parenchyma volume, PLT count,
and Fib may cause brain tissue hypoxia, in-
sufficient perfusion, and impaired coagula-
tion, affecting the patient’s recovery.
In the ROC diagnostic curve, ICP, CPP,
PbtO2, Vs, Vd, Vm, APTT, PLT, and Fib all had
high diagnostic values for poor prognosis.
Vs, Vd, and Vm were all independent protec-
tive factors for the prognosis of TBI patients.
The reason may be that the cerebral vascu-
lar has regulatory functions. When cranial
injury occurs, ICP is elevated, disturbing
brain tissue blood oxygen levels producing a
large amount of hemoglobin, 5-hydroxytryp-
tamine, and angiotensin. The cerebral vascu-
lar regulatory center alleviates blood oxygen
deficiency by regulating ICP, thus repairing
damaged brain nerves and protecting the in-
tracranial microcirculatory balance.
Brain tissue is the organ with the high-
est level of prothrombin kinase. Under the
influence of cranial damage and ICP, coagu-
lation dysfunction of brain tissue also affects
intracranial blood-oxygen balance, which af-
fects the outcome and prognosis of TBI. In
terms of the development pathway of coagu-
lation dysfunction in TBI, when the cranial
brain is damaged, and the blood-brain bar-
rier is impaired, the extrinsic coagulation
mechanism is activated by stress, and a large
amount of thrombin is released from brain
tissue into the blood circulation, resulting in
a local hypercoagulable state in the cranial
brain 18. In the good prognosis Group, PT,
APTT, and TT levels were significantly lower,
while PLT levels were higher than those in the
poor prognosis group, and all factors were
independent influencing factors for poor
prognosis. This suggests that with impaired
coagulation mechanisms, platelet levels may
decrease rapidly. Platelets play a crucial role
in blood coagulation and can accumulate on
damaged blood vessel walls to form a throm-
bus for hemostasis. If platelet numbers are
reduced or their function is abnormal, it
may lead to decreased coagulability, increas-
ing the risk of bleeding. Brain tissue is very
important for adequate blood oxygen supply,
and the decline of platelets may lead to un-
balanced cerebrovascular regulation, further
affecting the blood oxygen level of brain tis-
24 Shen et al.
Investigación Clínica 65(1): 2024
sue and impairing brain function 19,20. This is
probably because TBI causes local tissue dam-
age and bleeding, releasing a large number of
tissue factors and cytokines that activate the
coagulation system. However, when the injury
is too severe or lasts too long, the coagulation
function may be inhibited, and the platelet
aggregation and blood coagulation capacity
may be reduced. This leads to a decrease in
the platelet levels. Second, TBI may lead to
the rupture and bleeding of the capillaries
in the brain tissue. Platelets accumulate at
vascular damage and seal the ruptured capil-
laries by forming platelet primary hemostatic
plugs to prevent further bleeding. Therefore,
when thrombocytopenia occurs, it may in-
dicate damage to platelet consumption and
further bleeding. In addition, platelets re-
lease secretions such as serotonin, dopamine,
and angiotensin, which are involved in vas-
cular regulation and hemodynamic balance
in the lining of blood vessels. When platelet
levels decrease, this cerebrovascular regula-
tion mechanism may be affected, leading to
abnormal blood oxygen levels in brain tissue,
further impairing cerebrovascular regulation.
Therefore, the decrease in platelet levels may
be one of the manifestations of impaired co-
agulation mechanisms and abnormal cere-
brovascular regulation in patients with TBI.
These changes may impact the prognosis of
patients with TBI, and further studies can ex-
plore these associations and determine their
predictive value for the prognosis of patients
with TBI. However, this study only analyzed
the correlation between intracranial pressure-
related parameters, coagulation indexes, and
prognosis without correlating intracranial
pressure with coagulation indexes, and fur-
ther exploration is still needed to determine
their relationship.
In conclusion, intracranial pressure-re-
lated parameters and coagulation indicators
are all related to the prognosis of patients
with TBI, and the prognostic quality and sur-
vival of patients can be improved by regulat-
ing intracranial pressure and improving co-
agulation function.
ACKNOWLEDGMENTS
None.
Data Availability
Due to the nature of this research, par-
ticipants did not agree for their data to be
shared publicly, so supporting data is un-
available.
Conflicts of interest
The authors declare that they have no
competing interests.
Funding
No funds, grants, or other support was
received.
Author’s ORCID numbers
• Linna Shen (LS):
0009-0005-5283-3121
• Haibin Lu (HL):
0009-0008-3272-4595
• Shuibo Yang (SY):
0009-0008-1897-4213
• Feixiong Chen (FC):
0009-0004-5243-7236
Participation in development and writing
of the paper
Concept and design: LS and FC. Acqui-
sition of data, literature review, and refine-
ment of manuscript: All authors. Analysis
and interpretation of data: HL and SY. Man-
uscript writing: LS. Review of final manu-
script: FC.
Factors affecting the prognosis of patients with traumatic brain injuries 25
Vol. 65(1): 16 - 26, 2024
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