Objective To evaluate the diagnostic value of cerebrospinal lactate for the diagnosis of bacterial meningitis in patients post-neurosurgical operation (PNBM) with blood-contaminated cerebrospinal fluid (CSF). Methods A prospective observational study was conducted. 101 patients underwent neurosurgical operation and clinically suspected PNBM admitted to neurosurgical intensive care unit (NSICU) of the First Affiliated Hospital of Sun Yat-sen University from October 2015 to December 2016 were enrolled. Based on red blood cell quantitative test in CSF, the patients were divided into blood-contaminated and non blood-contaminated CSF groups. According to the PNBM diagnostic criteria of 2008 Centers for Disease Control and Prevention/National Healthcare Safety Network (CDC/NHSN), all patients were divided into PNBM group and non-PNBM group. The biochemical indexes levels in CSF were compared among the groups. Receiver operating characteristic (ROC) curve analysis was used to evaluate the diagnostic power of CSF lactate for PNBM in blood-contaminated patients.Results A total of 101 suspected PNBM patients were enrolled. In 77 blood-contaminated CSF patients, 39 patients were diagnosed as PNBM (account for 50.6%); in 24 non-blood-contaminated patients, 12 patients were diagnosed as PNBM (account for 50.0%). ① In non-PNBM patients, the lactate level in blood-contaminated CSF was significantly higher than that of non-blood-contaminated CSF (mmol/L: 3.5±1.3 vs. 2.3±1.1,P < 0.01). In PNBM patients, there was no significant difference in lactate level between blood-contaminated CSF and non blood-contaminated CSF (mmol/L: 6.8±2.1 vs. 6.9±2.5,P > 0.05). ② In both blood-contaminated and non blood-contaminated CSF, white blood cell (WBC), protein and lactate levels in PNBM group were significantly higher than those in non-PNBM group [WBC (×106/L): 660.0 (67.5, 1105.0) vs. 41.0 (15.0, 142.5) in blood-contaminated CSF,168.0 (86.5, 269.5) vs. 34.5 (7.0, 83.5) in non-blood-contaminated CSF; protein (mg/L): 4757.8 (2995.2, 10219.8) vs. 1292.8 (924.2, 1936.2) in blood-contaminated CSF, 39247.3 (14900.6, 62552.2) vs. 1441.6 (977.3, 2963.9) in non blood-contaminated CSF; lactate (mmol/L): 6.8±2.1 vs. 3.5±1.3 in blood-contaminated CSF, 6.9±2.5 vs. 2.3±1.1 in non blood-contaminated CSF, allP < 0.05], and glucose and CSF glucose/blood glucose ratio in PNBM group were significantly lower than those in non-PNBM group [glucose (mmol/L): 2.5±1.2 vs. 4.4±1.6 in blood-contaminated CSF, 1.9±1.4 vs. 3.4±0.9 in non blood-contaminated CSF; CSF glucose/blood glucose ratio: 0.28±0.15 vs. 0.46±0.16 in blood-contaminated CSF, 0.24±0.16 vs. 0.45±0.11 in non blood-contaminated CSF, allP < 0.01]. ③ It was shown by ROC curve analysis that CSF lactate level was a good diagnostic parameter for PNBM both in blood-contaminated and non blood-contaminated CSF, and the area under ROC curve (AUC) was 0.91 and 0.97, respectively. When the cutoff value of lactate in non blood-contaminated CSF was 3.35 mmol/L, the sensitivity was 100%, and the specificity was 91.7%. When the cutoff value of lactate in blood-contaminated CSF was 4.15 mmol/L, the sensitivity was 92.3%, and the specificity was 71.1%, and the combination of CSF lactate and glucose achieved better diagnostic specificity (AUC = 0.96, sensitivity was 97.4%, specificity was 84.2%).Conclusions Blood in CSF led to the elevation of CSF lactate as compared with that in non-blood-contaminated CSF of patients with PNBM. CSF lactate was still a good diagnostic parameter for PNBM both in blood-contaminated patients, and the combination of CSF lactate and glucose achieved better diagnostic specificity.

Objective To investigate the predictive value of metabolic syndrome in patients with acute coronary syndrome (ACS) after percutaneous coronary intervention (PCI).Methods A total of 660 patients with ACS admited to cardiovascular department,first affiliated hospital of zhengzhou university were enrolled in this study from January 2009 to June 2010.The enrollment criteria were:the stenosis degree were above 75％ in at least one coronary artery by coronary angiography and successful PCI procedure.Exculsion criteria were:liver and renal insufficiency,malignancies and valvular heart diseases.The relevant clinical data and labtory examination were recorded after admission. The patients were followed up by outpatients interview or telephone from March to June 2011 and adverse cardiovascular events were recorded.The patients were divided into MS and non-MS groups,and basic clinical data were compared between two groups.The proportion difference between two groups were tested by chi square. Multivariate logistic regression was established to analyze the factors related to progonosis.The survival ratio was estimated using the Kaplan-Meier method.Statistical significance was established at a P value of less than 0.05.Results ①A total of 606 (91.7％) patients successfully accepted follow-up.Mean follow-up time were ( 14.3 ±1.7 ) months.95 patients experienced adverse cardiovascular events ( 15.7％ ).②There were 393 patients (64.96％ ) satisfied the definition of metabolic syndrome.The patients in MS group were with higher BMI,SBP,DBP,blood glucose and disordered lipid (all P ＜ 0.05 ),with less fale patients (P =0.016),less current somking (P =0.008 ) and with higher platelet (P =0.037 ). The incidence of adverse cardiovascular events in two groups were 17.81％ and 11.79％ ( P ＞ 0.05 ). ③ Multivarite logistic regression revealed that the predictors of adverse cardiovascular events were age [ OR =2.628,95％ confidence interval (CI) 1.395 ～ 4.954,P =0.003 ],New York Heart Association (NYHA) ≥ 3 grade ( OR =2.310,95％ CI 1.095 ～4.870,P =0.028) and left ventricular ejection fraction (LVEF) ( OR =4.328,95％ CI 1.955 ～9.580,P ＜ 0.001 ).However,MS was not related with prognosis ( OR =1.170,95％ CI 0.583 ～ 2.345,P =0.659 ).④The cumulative survival rates of no adverse cardiovascular events in the two groups were no significant difference ( P ＞ 0.05 ).Conclusions MS is a risk factor with coronary heart disease.Howerer,it has no relationship with adverse cardiovascular events in patients with ACS after PCI.

Objective:To explore the effect of de-escalation thinking in the triage of critically ill children in the Department of Pediatrics.Methods:From January 2018 to January 2020, we selected a total of 486 critically ill pediatric patients admitted to Zhumadian Central Hospital in Henan Province. According to the random number table, the children were simply randomly divided into control group and observation group, each with 243 cases. Control group carried out traditional routine triage, and observation group conducted de-escalation thinking for pre-examination and triage. We observed the differences in the triage accuracy, satisfaction of the children and their parents and the quality of the triage between the two groups of children.Results:The scores of the disease classification and triage accuracy, total satisfaction, service attitude, treatment timeliness, health guidance as well as safety of children in observation group were higher than those in control group, and the differences were all statistically significant ( P<0.05) . Conclusions:De-escalation thinking has a high accuracy rate in the triage of critically ill children in the Department of Pediatrics, which can improve the treatment effect, reduce the adverse results of the rescue, and improve the satisfaction of the children and their family members.

Objective: To evaluate trough serum vancomycin concentrations and identify their influencing factors in critically ill neurosurgical patients. Methods: A retrospective study was conducted. Adult patients who received vancomycin with at least one appropriate monitoring of trough serum vancomycin concentration and admitted to neurosurgical intensive care unit (ICU) of the First Affiliated Hospital of Sun Yat-sen University from November 2017 to July 2019 were enrolled. General information including gender, age, comorbidities, etc., trough serum vancomycin concentrations, vancomycin dosage, duration of vancomycin therapy, urine output, serum creatinine (SCr), concurrent medications (including mannitol, diuretic, vasopressors, non-steroidal anti-inflammatory drugs, polymyxin, aminoglycosides and contrast medium, etc.) were collected for analysis. Trough serum vancomycin concentrations were evaluated and their influencing factors were analyzed by multiple linear regression method. Results: In total, 81 trough serum vancomycin concentration data sets obtained from 28 patients were evaluated. ① The initial daily dose of vancomycin was 2.00 (2.00, 2.00) g/d. After 4-6 doses, the trough serum vancomycin concentration obtained from initial blood draw was 10.99 (6.98, 16.25) mg/L, of which only 17.9% (5/28) achieving targeted concentrations (15-20 mg/L), 71.4% (20/28) subtherapeutic level and 10.7% (3/28) supratherapeutic level. ② The duration of vancomycin therapy was 8.0 (6.0, 15.0) days. With average daily dose of 2.00 (1.75, 3.00) g/d, targeted trough vancomycin concentrations were achieved in only 30.9% (25/81) of all cases, subtherapeutic concentrations in 49.4% (40/81) and supratherapeutic concentrations in 19.7% (16/81). ③ There were significant differences in age, comorbidities, vancomycin dosage, diuretics use and mannitol dosage, etc. among different vancomycin concentration groups. Multiple linear regression analysis suggested that the trough serum vancomycin concentration increased by 0.14 mg/L [95% confidence interval (95%CI) was 0.06-0.22] for every 1 year increase in age, increased by 7.22 mg/L (95%CI was 2.08-12.36) in patients with multiple comorbidities (concomitant hypertension, diabetes and coronary heart disease) compared with those without comorbidities, increased by 2.78 mg/L (95%CI was 0.20-5.35) in patients treated with diuretics compared with those without diuretics. The effect of other variables was not statistically significant. It suggested that age, multiple comorbidities (concomitant hypertension, diabetes and coronary heart disease), and diuretic usage affected trough serum vancomycin concentrations. Conclusions Targeted trough serum vancomycin level is not often achieved in neurosurgical ICU patients following standard dosing. Younger patients are associated with lower trough serum vancomycin concentrations, while diuretic usage, combined with multiple comorbidities are associated with higher trough serum vancomycin concentrations.

Objective:To investigate the correlations between cerebral β-amyloid (Aβ) deposition assessed by 18F-florbetapir (AV45) PET imaging and clinical cognitive symptoms in patients with subtle cognitive decline (SCD) and mild cognitive impairment (MCI). Methods:Data of twenty-four patients (11 males, 13 females, age: (63.2±7.6) years) diagnosed as SCD ( n=15) or MCI ( n=9) from December 2018 to March 2019 in Shanghai Jiao Tong University Affiliated Sixth People′s Hospital were collected prospectively. All patients underwent 18F-AV45 PET imaging, brain MRI T 1 scan and Mini-Mental State Examination (MMSE) within two weeks. 18F-AV45 PET images were analyzed visually (positive, mild positive, negative). After being pretreated according to the MRI, 18F-AV45 PET images were analyzed semi-quantitatively by calculating the standardized uptake value ratio (SUVR) of Aβ deposition in 8 regions of interest (ROIs; frontal lobe, lateral parietal lobe, lateral temporal lobe, medial temporal lobe, occipital lobe, basal ganglia, posterior cingulate and precuneus), with cerebellar gray matter as the reference. Partial correlation coefficients between regional SUVRs and MMSE score were calculated. Results:18F-AV45 PET imaging showed that 16 patients with positive results and 8 patients with mild positive results. MMSE score of 24 patients was 28.2±2.0, and the SUVR was 0.93-1.87. Correlation analysis revealed that Aβ deposition in frontal cortex ( r=-0.432), posterior cingulate lobe ( r=-0.434) and precuneus ( r=-0.418) was negatively correlated with MMSE score (all P<0.05); and no significant correlations between SUVR and MMSE in other brain regions were found ( r values: from -0.412 to -0.110, all P>0.05). Conclusion:18F-AV45 PET imaging can noninvasively detect brain Aβ deposition in patients, and can effectively reflect the clinical cognitive status of patients with SCD and MCI to a certain extent.

OBJECTIVE: To study the influential factor of hyperlactatemia after the brain tumor craniotomy. METHODS: Patients who underwent selective brain tumor (including glioma, meningioma and acoustic schwannoma) craniotomyin the neurosurgery intensive care unit (NSICU) of the First Affiliated Hospital, Sun Yat-sen University from December 1st 2018 to May 20th 2019 were enrolled. The incidence of hyperlactatemia after the brain tumor craniotomy was investigated. Univariate and multivariate linear regression analysis were performed to identify the association of initial artery lactate with the operation duration, the intraoperative blood loss, the total intraoperative fluid infusion, intraoperative ringer lactate fluid infusion, intraoperative urine volume, intraoperative fluid balance, the total intraoperative corticosteroids dosage and the tumor type. Pearson method was used to analyze the correlation between lactate in arterial blood and independent related factors. RESULTS: A total of 148 patients were enrolled including 45 patients (30.41%) with glioma, 64 patients (43.24%) with meningioma, and 39 patients (26.35%) with acoustic schwannoma. The initial lactate level in arterial blood increased significantly in 148 patients, with a median of 4.80 (3.68, 5.90) mmol/L. Among them, 78 patients (52.70%) had mild elevation of lactate in arterial blood (2 mmol/L < lactate ≤ 5 mmol/L), 61 patients (41.22%) had significant elevation of lactate in arterial blood (5 mmol/L < lactate ≤ 10 mmol/L), and 2 patients (1.35%) had serious elevation of artery lactate (> 10 mmol/L). And only 7 patients (4.73%) had normal level of lactate in arterial blood (≤ 2 mmol/L). Univariate analysis showed that initial postoperative artery lactate was positively correlated with the operation duration [β = 0.556, 95% confidence interval (95%CI) was 0.257-0.855, P < 0.001] and the total intraoperative corticosteroids dosage (β = 0.477, 95%CI was 0.174-0.779, P = 0.002). There was no significant correlation between the initial postoperative artery lactate and tumor types, the intraoperative blood loss, the total fluid infusion, the ringer lactate fluid infusion, urine volume, and the fluid balance. Further multivariate linear regression analysis showed that the operation duration (β = 0.499, 95%CI was 0.204-0.795, P = 0.001) and the total intraoperative corticosteroids dosage (β = 0.407, 95%CI was 0.111-0.703, P = 0.008) were independent risk factors affecting the initial postoperative artery lactate. The correlation analysis showed that there was a significant positive correlation between lactate in arterial blood and operation time and total hormone dosage during operation (r₁ = 0.289, r₂ = 0.248, both P < 0.01). CONCLUSIONS Initial artery lactate after brain tumor craniotomy is associated with surgery duration and exogenous administration of corticosteroids.
Adrenal Cortex Hormones/therapeutic use* ; Arteries ; Brain Neoplasms ; Craniotomy ; Humans ; Retrospective Studies

OBJECTIVE: To evaluate cerebrospinal fluid (CSF) vancomycin concentrations and identify factors influencing CSF vancomycin concentrations in critically ill neurosurgical patients. METHODS: A retrospective study was conducted. Adult patients who received vancomycin treatment and CSF vancomycin concentrations monitoring admitted to neurosurgical intensive care unit (ICU) of the First Affiliated Hospital of Sun Yat-sen University from January 2016 to June 2019 were enrolled. General information, vancomycin dosing regimens, CSF vancomycin concentrations, CSF drainage methods and volume of the previous day, and concurrent medications, etc. were collected for analysis. CSF vancomycin concentrations of patients with definite or indefinite central nervous system (CNS) infection, different vancomycin dosing regimens and their influencing factors were analyzed. RESULTS: A total of 22 patients were included. 168 CSF specimens were collected for culture, 20 specimens of which were culture positive, with a positive rate of 11.9%. Sixty cases of CSF vancomycin concentration were obtained. Among the 22 patients, 7 patients (31.8%) were diagnosed with proven CNS infection, 11 patients (50.0%) clinically diagnosed, 2 patients (9.1%) diagnosed with uncertain CNS infection, and 2 patients (9.1%) diagnosed without CNS infection. Intravenous (IV) administration of vancomycin alone was used in 15 cases (25.0%), intrathecal injection in 17 cases (28.3%), IV+intrathecal injection in 23 cases (38.3%), and IV+intraventricular administration in 5 cases (8.3%). The CSF vancomycin concentrations ranged from < 0.24 to > 100 mg/L, with an average level of 14.40 (4.79, 42.34) mg/L. (1) Administration methods of vancomycin affected CSF vancomycin concentrations. The CSF vancomycin concentration with intrathecal injection or intraventricular administration was higher than that of IV administration alone [mg/L: 25.91 (11.28, 58.17) vs. 2.71 (0.54, 5.33), U = 42.000, P < 0.01]. (2) When vancomycin was administered by IV treatment alone, CSF vancomycin concentrations were low in both groups with definite CNS infection (proven+probable) and indefinite CNS infection (possible+non-infection), the CSF vancomycin concentrations of which were 4.14 (1.40, 6.36) mg/L and 1.27 (0.24, 3.33) mg/L respectively, with no significant difference (U = 11.000, P = 0.086). (3) CSF vancomycin concentrations rose with the increased dose of vancomycin delivered by intrathecal injection or intraventricular administration. According to the dose of vancomycin administered locally on the day before therapeutic drug monitoring (TDM), cases were divided into the following groups: 0-15 mg group (n = 22), 20-35 mg group (n = 33), and 40-50 mg group (n = 5), the CSF vancomycin concentrations of which were 4.14 (1.09, 8.45), 30.52 (14.31, 59.61) and 59.43 (25.51, 92.45) mg/L respectively, with significant difference (H = 33.399, P < 0.01). Moreover, the cases of CSF vancomycin concentration of ≥ 10 mg/L accounted for 18.2%, 84.8% and 100% of these three groups, respectively. CSF vancomycin concentrations mostly reached target level when dose of vancomycin administered locally were 20 mg/L or more. CONCLUSIONS It is difficult to reach target CSF vancomycin concentration for critically ill neurosurgical patients with or without CNS infection by IV treatment. Local administration is an effective treatment regimen to increase CSF vancomycin concentration.
Adult ; Anti-Bacterial Agents/cerebrospinal fluid* ; Drug Monitoring ; Humans ; Intensive Care Units ; Retrospective Studies ; Vancomycin/cerebrospinal fluid*

OBJECTIVE: To evaluate trough serum vancomycin concentrations and identify their influencing factors in critically ill neurosurgical patients. METHODS: A retrospective study was conducted. Adult patients who received vancomycin with at least one appropriate monitoring of trough serum vancomycin concentration and admitted to neurosurgical intensive care unit (ICU) of the First Affiliated Hospital of Sun Yat-sen University from November 2017 to July 2019 were enrolled. General information including gender, age, comorbidities, etc., trough serum vancomycin concentrations, vancomycin dosage, duration of vancomycin therapy, urine output, serum creatinine (SCr), concurrent medications (including mannitol,diuretic, vasopressors, non-steroidal anti-inflammatory drugs, polymyxin, aminoglycosides and contrast medium, etc.) were collected for analysis. Trough serum vancomycin concentrations were evaluated and their influencing factors were analyzed by multiple linear regression method. RESULTS: In total, 81 trough serum vancomycin concentration data sets obtained from 28 patients were evaluated. (1) The initial daily dose of vancomycin was 2.00 (2.00, 2.00) g/d. After 4-6 doses, the trough serum vancomycin concentration obtained from initial blood draw was 10.99 (6.98, 16.25) mg/L, of which only 17.9% (5/28) achieving targeted concentrations (15-20 mg/L), 71.4% (20/28) subtherapeutic level and 10.7% (3/28) supratherapeutic level. (2) The duration of vancomycin therapy was 8.0 (6.0, 15.0) days. With average daily dose of 2.00 (1.75, 3.00) g/d, targeted trough vancomycin concentrations were achieved in only 30.9% (25/81) of all cases, subtherapeutic concentrations in 49.4% (40/81) and supratherapeutic concentrations in 19.7% (16/81). (3) There were significant differences in age, comorbidities, vancomycin dosage, diuretics use and mannitol dosage, etc. among different vancomycin concentration groups. Multiple linear regression analysis suggested that the trough serum vancomycin concentration increased by 0.14 mg/L [95% confidence interval (95%CI) was 0.06-0.22] for every 1 year increase in age, increased by 7.22 mg/L (95%CI was 2.08-12.36) in patients with multiple comorbidities (concomitant hypertension, diabetes and coronary heart disease) compared with those without comorbidities, increased by 2.78 mg/L (95%CI was 0.20-5.35) in patients treated with diuretics compared with those without diuretics. The effect of other variables was not statistically significant. It suggested that age, multiple comorbidities (concomitant hypertension, diabetes and coronary heart disease), and diuretic usage affected trough serum vancomycin concentrations. CONCLUSIONS Targeted trough serum vancomycin level is not often achieved in neurosurgical ICU patients following standard dosing. Younger patients are associated with lower trough serum vancomycin concentrations, while diuretic usage, combined with multiple comorbidities are associated with higher trough serum vancomycin concentrations.
Adult ; Anti-Bacterial Agents/blood* ; Critical Illness ; Humans ; Intensive Care Units ; Retrospective Studies ; Vancomycin/blood*

Objective: To study the influential factor of hyperlactatemia after the brain tumor craniotomy. Methods: Patients who underwent selective brain tumor (including glioma, meningioma and acoustic schwannoma) craniotomyin the neurosurgery intensive care unit (NSICU) of the First Affiliated Hospital, Sun Yat-sen University from December 1st 2018 to May 20th 2019 were enrolled. The incidence of hyperlactatemia after the brain tumor craniotomy was investigated. Univariate and multivariate linear regression analysis were performed to identify the association of initial artery lactate with the operation duration, the intraoperative blood loss, the total intraoperative fluid infusion, intraoperative ringer lactate fluid infusion, intraoperative urine volume, intraoperative fluid balance, the total intraoperative corticosteroids dosage and the tumor type. Pearson method was used to analyze the correlation between lactate in arterial blood and independent related factors. Results: A total of 148 patients were enrolled including 45 patients (30.41%) with glioma, 64 patients (43.24%) with meningioma, and 39 patients (26.35%) with acoustic schwannoma. The initial lactate level in arterial blood increased significantly in 148 patients, with a median of 4.80 (3.68, 5.90) mmol/L. Among them, 78 patients (52.70%) had mild elevation of lactate in arterial blood (2 mmol/L < lactate ≤ 5 mmol/L), 61 patients (41.22%) had significant elevation of lactate in arterial blood (5 mmol/L < lactate ≤ 10 mmol/L), and 2 patients (1.35%) had serious elevation of artery lactate (> 10 mmol/L). And only 7 patients (4.73%) had normal level of lactate in arterial blood (≤ 2 mmol/L). Univariate analysis showed that initial postoperative artery lactate was positively correlated with the operation duration [β = 0.556, 95% confidence interval (95%CI) was 0.257-0.855, P < 0.001] and the total intraoperative corticosteroids dosage (β = 0.477, 95%CI was 0.174-0.779, P = 0.002). There was no significant correlation between the initial postoperative artery lactate and tumor types, the intraoperative blood loss, the total fluid infusion, the ringer lactate fluid infusion, urine volume, and the fluid balance. Further multivariate linear regression analysis showed that the operation duration (β = 0.499, 95%CI was 0.204-0.795, P = 0.001) and the total intraoperative corticosteroids dosage (β = 0.407, 95%CI was 0.111-0.703, P = 0.008) were independent risk factors affecting the initial postoperative artery lactate. The correlation analysis showed that there was a significant positive correlation between lactate in arterial blood and operation time and total hormone dosage during operation (r₁ = 0.289, r₂ = 0.248, both P < 0.01). Conclusion Initial artery lactate after brain tumor craniotomy is associated with surgery duration and exogenous administration of corticosteroids.

Objective: To evaluate cerebrospinal fluid (CSF) vancomycin concentrations and identify factors influencing CSF vancomycin concentrations in critically ill neurosurgical patients. Methods: A retrospective study was conducted. Adult patients who received vancomycin treatment and CSF vancomycin concentrations monitoring admitted to neurosurgical intensive care unit (ICU) of the First Affiliated Hospital of Sun Yat-sen University from January 2016 to June 2019 were enrolled. General information, vancomycin dosing regimens, CSF vancomycin concentrations, CSF drainage methods and volume of the previous day, and concurrent medications, etc. were collected for analysis. CSF vancomycin concentrations of patients with definite or indefinite central nervous system (CNS) infection, different vancomycin dosing regimens and their influencing factors were analyzed. Results: A total of 22 patients were included. 168 CSF specimens were collected for culture, 20 specimens of which were culture positive, with a positive rate of 11.9%. Sixty cases of CSF vancomycin concentration were obtained. Among the 22 patients, 7 patients (31.8%) were diagnosed with proven CNS infection, 11 patients (50.0%) clinically diagnosed, 2 patients (9.1%) diagnosed with uncertain CNS infection, and 2 patients (9.1%) diagnosed without CNS infection. Intravenous (IV) administration of vancomycin alone was used in 15 cases (25.0%), intrathecal injection in 17 cases (28.3%), IV+intrathecal injection in 23 cases (38.3%), and IV+intraventricular administration in 5 cases (8.3%). The CSF vancomycin concentrations ranged from < 0.24 to > 100 mg/L, with an average level of 14.40 (4.79, 42.34) mg/L.①Administration methods of vancomycin affected CSF vancomycin concentrations. The CSF vancomycin concentration with intrathecal injection or intraventricular administration was higher than that of IV administration alone [mg/L: 25.91 (11.28, 58.17) vs. 2.71 (0.54, 5.33), U = 42.000, P < 0.01].②When vancomycin was administered by IV treatment alone, CSF vancomycin concentrations were low in both groups with definite CNS infection (proven+probable) and indefinite CNS infection (possible+non-infection), the CSF vancomycin concentrations of which were 4.14 (1.40, 6.36) mg/L and 1.27 (0.24, 3.33) mg/L respectively, with no significant difference (U = 11.000, P = 0.086).③CSF vancomycin concentrations rose with the increased dose of vancomycin delivered by intrathecal injection or intraventricular administration. According to the dose of vancomycin administered locally on the day before therapeutic drug monitoring (TDM), cases were divided into the following groups: 0-15 mg group (n = 22), 20-35 mg group (n = 33), and 40-50 mg group (n = 5), the CSF vancomycin concentrations of which were 4.14 (1.09, 8.45), 30.52 (14.31, 59.61) and 59.43 (25.51, 92.45) mg/L respectively, with significant difference (H = 33.399, P < 0.01). Moreover, the cases of CSF vancomycin concentration of≥10 mg/L accounted for 18.2%, 84.8% and 100% of these three groups, respectively. CSF vancomycin concentrations mostly reached target level when dose of vancomycin administered locally were 20 mg/L or more. Conclusions It is difficult to reach target CSF vancomycin concentration for critically ill neurosurgical patients with or without CNS infection by IV treatment. Local administration is an effective treatment regimen to increase CSF vancomycin concentration.