Production of inflammatory cytokines, cortisol, and Aβ1-40 in elderly oral cancer patients with postoperative delirium.

AIM: Pathophysiological disorders after surgery might be related to postoperative delirium (POD). This study was designed to elucidate the pathogenesis of POD in elderly oral cancer patients by determining the perioperative kinetics of inflammatory cytokines, cortisol, and amyloid β1-40 (Aβ1-40).
METHODS: A total of 257 elderly oral cancer patients who underwent tumor resection surgery were selected. Venous blood was collected prior to surgery (T0), at the end of surgery (T1), and at 12 hours after surgery (T2). During the first three postoperative days, patients were examined using the confusion assessment method twice a day (8 am and 8 pm). Mini-Mental State Examination scores were recorded at T0 and on postoperative days 1, 3, and 7. Ultimately, 56 patients suffering from POD made up the POD group, and 56 patients randomly selected from a cohort of patients without POD were allocated to the no POD (NPOD) group. Subsequently, interleukin-6, C-reactive protein, procalcitonin, cortisol, and Aβ1-40 in plasma from the two groups were measured.
RESULTS: The two groups displayed comparable basic characteristics. There were no differences in all tested biomarkers between the two groups at T0. However, after surgery, the biomarker levels displayed distinct patterns between the two groups. The peak levels of all biomarkers were higher in the POD group than in the NPOD group. Conversely, the Mini-Mental State Examination scores after surgery were lower in the POD group than in the no POD group.
CONCLUSION: The boost of inflammatory cytokines, cortisol, and Aβ1-40 after surgery might be involved in POD onset among elderly oral cancer patients. POD was accompanied by progressive cognitive deficiency.

Introduction

Acute attack, illness fluctuation, attention deficit, confusion, and disturbance of consciousness are core features of postoperative delirium (POD).1 Elderly patients with preoperative cognitive impairment, dementia, anxiety, and depression are more prone to POD.2 Elderly oral cancer patients who undergo tumor resection combined with free flap surgery experience a prolonged operation time, severe trauma, long-term artificial airway placement, and postoperative restraint due to the need for a flap. These predisposing factors lead to a high incidence of POD in elderly oral cancer patients.3,4 The negative consequences of POD include an increased burden of care, a prolonged hospital stay, an elevated rate of mortality during hospitalization, and long-term cognitive impairment or even permanent dementia.5 Excessive inflammatory responses induced by surgery may lead to impaired mental status post-operatively.6 However, the pathophysiological mechanisms underlying POD remain to be elucidated. Recent emerging hypotheses include “neuroinflammatory”, “neuronal aging”, and “neuroendocrine”.7 This study was designed to elucidate the pathogenesis of POD by observing the kinetics of inflammation, stress, and dementia markers in elderly oral cancer patients with POD.

Methods

Patients and setting

A total of 257 elderly oral cancer patients who underwent tumor resection together with free flap surgery under general anesthesia in the past several months were selected. The inclusion criteria were as follows: American Society of Anesthesiologists physical status I–III; age ≥65 years and ≤80 years; and duration of postoperative stay in the surgical intensive care unit ≥3 days. The exclusion criteria were Mini-Mental State Examination (MMSE) score <24 or dementia of various etiologies; history of central nervous system (CNS) or mental illness; current use of sedatives or antidepressants; history of neurosurgery; history of endocrine and metabolic disorders; history of inflammatory disease; recent use of glu-cocorticoids, cytokines, or anti-cytokine therapy; complications of secondary surgery or severe infections (we used the presence of more than two systemic inflammatory response syndrome criteria as a marker of inflammation);8 unwilling to complete the experimental procedures or language barriers to participation; severe hearing or visual impairment; illiteracy; and alcohol or drug dependence. This study was approved by the Ethics Committee of Shanghai Ninth People’s Hospital affiliated to Shanghai Jiao Tong University School of Medicine (Shanghai, People’s Republic of China), and written informed consent was provided by all patients.

Before surgery, the patients were interviewed and assessed. The demographic data and the patients’ medical histories were recorded and MMSE and Charlson’s Comorbidity Index were conducted.

Anesthesia, surgery, and postoperative pain treatment

No patients received medication prior to surgery. Systolic blood pressure, diastolic blood pressure, pulse oxygen saturation, electrocardiogram, stroke volume variation, bispectral index, and end-tidal CO2 were continuously monitored during the perioperative period. Anesthesia was induced with midazolam, sufentanil, propofol, and vecuronium. Anesthesia was maintained via inhalation of 1%–3% isoflurane, continuous intravenous infusion of propofol, and intermittent infusion of sufentanil and vecuronium to maintain analgesic and muscle relaxant effects. During surgery, the respiratory parameters of the anesthesia machine were modulated to maintain an end-tidal CO2 between 30 and 40 mmHg, and the depth of anesthesia was adjusted to maintain the bispectral index value within the range of 40–60. Intraoperative blood pressure fluctuations were maintained within ±30% of the baseline values, and the heart rate was sustained at 50–100 beats/min. All patients underwent tracheotomy after the operation, followed by transport to the surgical intensive care unit. After surgery, all patients were continuously administered analgesia via a pump in the same manner. Moreover, identical treatments, such as anti-infection practices, phlegm elimination, and detumescence, were provided to all patients. All included patients did not receive sedatives after surgery.

Blood sample collection and sample bank establishment

Venous blood was drawn through a femoral vein catheter prior to surgery (T0), at the end of surgery (T1), and 12 hours after surgery (T2). Blood samples were stored in anticoagulant tubes and immediately centrifuged at 4°C for 10 minutes (3,000 rpm). Then, the plasma samples were frozen in a −80°C refrigerator (Sanyo, Osaka, Japan) until analysis.

POD assessment and group allocation

During the first 3 days after surgery, patients were assessed by an expert in psychology using the confusion assessment method twice a day (8 am and 8 pm). The confusion assessment method was used to assess delirium; this instrument contains four items: 1) acute change or fluctuating course of mental status; 2) inattention; 3) altered level of consciousness; and 4) disorganized thinking. A positive delirium diagnosis requires the presence of items 1) and 2) as well as either item 3) or 4).9

The confusion assessment method is a simple and rapid method for evaluating the state of consciousness according to the Diagnostic and Statistical Manual of Mental Disorders Fourth Edition.

In total, 257 patients were included in the study. Among this cohort, 56 patients exhibited POD and were allocated to the POD group. An additional 56 patients were randomly selected from the cohort of patients without POD and were allocated to the no POD (NPOD) group. Moreover, the MMSE scores of the two groups were recorded at T0 and on postoperative days 1, 3, and 7 by the same doctor in the morning.

Blood tests

The levels of interleukin (IL)-6, C-reactive protein (CRP), procalcitonin (PCT), cortisol, and amyloid β1-40 (Aβ1-40) in plasma from the two groups were determined. The IL-6 levels were measured via enzyme-linked immunosorbent assay (R&D Systems, Inc., Minneapolis, MN, USA). PCT was measured via an immunometric assay using time-resolved amplified cryptate emission technology (PCT-sensitive Kryptor kit; Brahms, Middletown, VA, USA). Analyses of the CRP and cortisol levels were performed using the VITROS 5600 analyzer (Johnson and Johnson, New Bruns-wick, NJ, USA). The Aβ1-40 concentrations were measured via enzyme-linked immunosorbent assay (Sigma-Aldrich Co., St Louis, MO, USA). Enzyme-linked immunosorbent assay was carried out with a standard protocol and adopted chro-mogenic reporters in a quantitative format to measure β-Aβ-specific activity. We employed the Shanghai Zhili Biological Technology Company (Shanghai, People’s Republic of China) to build up reaction standard curves. The protein level was determined while comparing the optical density value of samples and the standard curve. All procedures were performed according to the manufacturer’s instructions.

Statistical analysis

Descriptive results of continuous variables are expressed as mean ± standard deviation. Categorical data are expressed as counts. The Kolmogorov–Smirnov test was used to test for normality. If continuous variables were not normally distributed, the Mann–Whitney U-test was used. Otherwise, Student’s t-test was applied (eg, age, education, operation duration, anesthesia duration, volume of infusion). Quantitative data (eg, IL-6, CRP, PCT, cortisol, Aβ1-40) between groups were analyzed by the Student’s t-test and intra group numerical data were analyzed by repeat ed measures analysis of variance. Enumeration data (eg, female, American Society of Anesthesiologists grade, flap reconstruction) were ana-lyzed by chi-squared test. A P-value <0.05 was considered significant. SPSS 16.0 (SPSS Inc., Chicago, IL, USA) was used for statistical analysis.

Results

Demographic data for the patients are shown in Table 1. The incidence of POD in elderly oral cancer patients undergoing tumor resection combined with free flap surgery was 21.8% (56/257). There were no significant differences in age, sex, weight, education level, American Society of Anesthesiologists grade, or other basic characteristics between the POD and NPOD groups (P>0.05).

Table 1

Demographic characteristics of the POD and NPOD groups

Characteristic	POD (n=56)	NPOD (n=56)	P-value
Age (years)	73.2±6.5	72.7±8.3	0.72
Female	29	33	0.57
Weight (kg)	60±15	63±16	0.31
Education (years)	8.2±2.3	8.5±2.8	0.54
ASA grade (I/II/III)	9/41/5	15/36/6	0.40
MMSE score at T0	27.91±1.53	28.13±1.62	0.46
Charlson’s Comorbidity Index at T0	1.5±0.7	1.7±0.8	0.16
Flap reconstruction			0.36
Forearm	25	24
Anterolateral thigh	20	15
Peroneal muscles	11	17
Operation duration (min)	481±102	470±108	0.58
Anesthesia duration (min)	515±97	506±104	0.64
Blood loss (mL)	802±211	785±203	0.66
RBC transfusion (units)	2.6±1.8	2.1±1.9	0.16
FFP transfusion (units)	2.2±1.6	1.8±1.5	0.18
Volume of infusion (mL)	3,612.0±613.9	3,498.5±656.5	0.35

Note: Data are shown as mean ± SD or numbers.

Abbreviations: ASA, American Society of Anesthesiologists; FFP, fresh frozen plasma; MMSE, Mini-Mental State Examination; NPOD, no POD; POD, postoperative delirium; RBC, red blood cells; SD, standard deviation; min, minutes; T0, prior to surgery.

A total of 257 patients were included in this study and completed all observations. Among these, 56 patients exhibited POD. Specifically, 31 POD cases began on postoperative day 1, 19 on postoperative day 2, and six on postoperative day 3. As shown in Figure 1, the added morbidity of POD on postoperative day 3 was lower than that on postoperative days 1 (P<0.01) and 2 (P=0.01). As shown in Figure 2, among the 56 patients with POD, 38 patients were diagnosed with hyperactive delirium, seven with hypoactive delirium, and eleven with mixed delirium.

Figure 1

The added morbidity of postoperative delirium (POD) days 1–3.

Note: The added morbidity of POD on postoperative day 3 was lower than that on postoperative days 1 (P<0.01) and 2 (P=0.01).

Figure 2

The type of postoperative delirium (POD).

Notes: Among the 56 patients with POD, 38 patients were diagnosed with hyperactive delirium, seven with hypoactive delirium, and eleven with mixed delirium.

As shown in Figure 3, there were no significant differences in the IL-6 levels between the two groups before surgery (T0) (P=0.60). At the end of surgery (T1) and 12 hours after surgery (T2), the IL-6 levels were higher in the POD than that in NPOD group (158.7±9.5 vs 97.9±10.3 pg/L at T1, 77.9±5.6 vs 57.1±4.6 pg/L at T2, P<0.01). At T1 and T2, the levels of IL-6 in each group were higher than those in the corresponding group at T0 (P<0.05).

Figure 3

Concentration of interleukin (IL)-6 between the NPOD and POD groups.

Notes: There were no significant differences in the IL-6 levels between the two groups prior to surgery (T0) (P=0.60). At the end of surgery (T1) and 12 h after surgery (T2), the IL-6 levels were higher in the POD than that in NPOD group (P<0.01). At T1 and T2, the levels of IL-6 in each group were higher than those in the corresponding group at T0 (P<0.05).

Abbreviations: NPOD, no POD; POD, postoperative delirium; h, hours.

As shown in Figure 4, there were no significant differences in the CRP levels between the two groups before surgery (T0) (P=0.55) and at the end of surgery (T1) (P=0.50). Furthermore, the CRP levels in each group at T1 were not different from those in the corresponding group at T0 (P>0.05). However, 12 hours after surgery (T2), the CRP levels were higher in the POD than that in NPOD group (98.8±25.3 vs 55.2±21.8 mg/L, P<0.01). At T2, the levels of CRP in each group were higher than those in the corresponding group at T0 (P<0.05).

Figure 4

Concentration of CRP between the NPOD and POD groups.

Notes: There were no significant differences in the CRP levels between the two groups prior to surgery (T0) (P=0.55) and at the end of surgery (T1) (P=0.50). Furthermore, the CRP levels in each group at T1 were not different from those in the corresponding group at T0 (P>0.05). However, 12 h after surgery (T2), the CRP levels were higher in the POD than that in NPOD group (P<0.01). At T2, the levels of CRP in each group were higher than those in the corresponding group at T0 (P<0.05).

Abbreviations: CRP, C-reactive protein; NPOD, no POD; POD, postoperative delirium; h, hours.

As shown in Figure 5, there were no significant differences in the PCT levels between the two groups before surgery (T0) (P=0.14). At the end of surgery (T1) and 12 hours after surgery (T2), the PCT levels were higher in the POD than that in NPOD group (0.22±0.05 vs 0.20±0.04 ng/mL at T1, P=0.02; 0.27±0.06 vs 0.22±0.05 ng/mL at T2, P<0.01). At T1 and T2, the levels of PCT in each group were higher than those in the corresponding group at T0 (P<0.05).

Figure 5

Concentration of PCT between the NPOD and POD groups.

Notes: There were no significant differences in the PCT levels between the two groups prior to surgery (T0) (P=0.14). At the end of surgery (T1) and 12 h after surgery (T2), the PCT levels were higher in the POD than that in NPOD group (P=0.02 and P<0.01). At T1 and T2, the levels of PCT in each group were higher than those in the corresponding group at T0 (P<0.05).

Abbreviations: NPOD, no POD; POD, postoperative delirium; PCT, procalcitonin; h, hours.

As shown in Figure 6, there were no significant differences in the cortisol levels between the two groups before surgery (T0) (P=0.15). At the end of surgery (T1) and 12 hours after surgery (T2), the cortisol levels were higher in the POD than that in NPOD group (878.9±153.8 vs 749.1±241.9 nmmol/mL at T1, 736.8±147.8 vs 441.9±82.2 nmmol/mL at T2, P<0.01). At T1 and T2, the levels of cortisol in each group were higher than those in the corresponding group at T0 (P<0.05).

Figure 6

Concentration of cortisol between the NPOD and POD groups.

Notes: There were no significant differences in the cortisol levels between the two groups prior to surgery (T0) (P=0.15). At the end of surgery (T1) and 12 h after surgery (T2), the cortisol levels were higher in the POD than that in NPOD group (P<0.01). At T1 and T2, the levels of cortisol in each group were higher than those in the corresponding group at T0 (P<0.05).

Abbreviations: NPOD, no POD; POD, postoperative delirium; h, hours.

As shown in Figure 7, there were no significant differences in the Aβ1-40 levels between the two groups before surgery (T0) (P=0.17) and at the end of surgery (T1) (P=0.12). Furthermore, the Aβ1-40 levels in each group at T1 were not different from those in the corresponding group at T0 (P>0.05). However, 12 hours after surgery (T2), the Aβ1-40 levels were higher in the POD than that in NPOD group (132.1±35.7 vs 85.2±15.6 ng/L, P<0.01). At T2, the levels of Aβ1-40 in each group were higher than those in the corresponding group at T0 (P<0.05).

Figure 7

Concentration of Aβ1-40 between the NPOD and POD groups.

Notes: There were no significant differences in the Aβ1-40 levels between the two groups prior to surgery (T0) (P=0.17) and at the end of surgery (T1) (P=0.12). Furthermore, the Aβ1-40 levels in each group at T1 were not different from those in the corresponding group at T0 (P>0.05). However, 12 h after surgery (T2), the Aβ1-40 levels were higher in the POD than that in NPOD group (P<0.01). At T2, the levels of Aβ1-40 in each group were higher than those in the corresponding group at T0 (P<0.05).

Abbreviations: Aβ1-40, amyloid β1-40; NPOD, no POD; POD, postoperative delirium; h, hours.

As shown in Figure 8, no difference in the MMSE score at T0 was found between the two groups (P=0.46), but the MMSE scores after surgery were lower in the POD than in NPOD group (16.25±3.63 vs 23.53±2.85 on postoperative day 1, 22.01±2.19 vs 25.61±2.67 on postoperative day 2, 25.31±2.75 vs 27.11±2.01 on postoperative day 3, P<0.01).

Figure 8

MMSE scores of the NPOD and POD groups during the perioperative period.

Note: No differences in the MMSE scores were found between the two groups at T0 (P=0.46), but the MMSE scores after surgery were lower in the POD than that in NPOD group (P<0.01).

Abbreviations: MMSE, Mini-Mental State Examination; NPOD, no POD; POD, postoperative delirium; T0, prior to surgery.

Discussion

In our study, the incidence of POD among elderly oral cancer patients was 20.7%. This value was similar to the result reported by Shiiba et al.10 Besides, POD primarily occurred during the period of 24–72 hours after surgery, and most cases were hyperactivity delirium.

The results of this study also suggested that there were no baseline differences in the levels of IL-6, CRP, PCT, cortisol, and Aβ1-40 between the two groups. However, the levels of IL-6, PCT, and cortisol appeared to increase during the early postoperative period, whereas the CRP and Aβ1-40 levels began to rise later. The peak levels of all tested markers were higher in the POD than that in NPOD group. Furthermore, the POD group exhibited more intense inflammation and stress responses than NPOD group. Surgical trauma can lead to activation of the immune system and hyperactivity of the hypothalamic–pituitary–adrenal axis, leading to aberrancies in the levels of acetylcholine, norepi-nephrine, 5-hydroxytryptamine, and other neurotransmitters in the CNS. These aberrancies might ultimately result in brain dysfunction after surgery. Beloosesky et al found that the serum levels of IL-6, IL-8, IL-10, and CRP in elderly hip fracture patients drastically increased early after fracture and then decreased up to 30 days after surgery, and these changes were related to impaired mental status.6

Peripheral inflammatory cytokines released as a result of surgery could enter the CNS through transporters to cross the blood–brain barrier; these cytokines could subsequently activate microglia to produce an inflammatory response. Inflammatory cytokines could interfere with the connection and transmission functions of synapses. Intracerebroven-tricular injection of IL-6 not only caused a significant inflammatory response by glial cells but also led to reduced dendritic arborization, decreased cholinergic innervation in the hippocampus, enhanced long-term potentiation of synaptic transmission, increased complement protein synthesis, hampered behavioral performance, and significantly impaired learning and memory functions.11 This study found that the peak levels of IL-6 were higher in the POD than in NPOD group. This observation indicates that there was more intense and prolonged CNS inflammation, which could lead to neurological dysfunction, in the POD compared to NPOD group.

Neuroendocrine cells or macrophages in the liver, lung, spleen, and kidney can generate PCT upon stimulation by bacterial endotoxins, tumor necrosis factor-α, IL-6, IL-2, or other factors. Tumor necrosis factor-α and IL-6 regulate PCT production. CRP appears in serum during the acute phase of infection, tissue injury, ischemia, malignant tumor growth, and other disorders; therefore, this marker has poor specificity. Elevated CRP levels are associated with the prevalence of dementia among the very old.12 The dynamics of IL-6, CRP, and PCT levels observed in this study were analogous to an inflammatory response. After healthy volunteers received an injection of endotoxin, the CRP levels exceeded the normal values 8–12 hours later and remained high at 24–72 hours after injection; the PCT concentrations began to rise after 4 hours and were sustained at a high level at 8–24 hours after injection; and the tumor necrosis factor-α and IL-6 levels peaked at 2–3 hours but became undetectable beyond 24 hours after injection.13 Our study found that the PCT concentrations were ~0.1 ng/mL before surgery and gradually increased after surgery, peaking at ~0.5 ng/mL. This value reflected only localized bacterial infection after surgery.14 The peak levels of PCT and CRP were higher in the POD than in NPOD group, which indicated more intense and persistent inflammation in the POD group.

Aβ1-40 and Aβ1-42 are major forms of β-amyloid protein. When the generation or aggregation of β-amyloid protein increases excessively, amyloid plaques are formed and deposited between neurons. This event causes neuronal loss, which is an important pathophysiological process in the pathogenesis of Alzheimer’s disease (AD). At present, several studies suggest that surgery under general anesthesia is associated with AD or POD.15,16 Xie et al found that a clinically relevant concentration of isoflurane induced neuronal apoptosis and increased β-amyloid protein production in a human neuroglioma cell line.17,18 Moreover, the plasma Aβ1-40 levels showed a significant association with poor neuropsychological performance in the aged.19 Our study revealed that the Aβ1-40 concentrations were increased 12 hours after surgery and that the Aβ1-40 levels were higher in the POD than in NPOD group. The boost of Aβ1-40 after surgery might facilitate the development of POD.

Postoperative neurological disorders include POD and postoperative cognitive dysfunction. POD is generally believed to have an acute onset within 3 days after surgery. Some patients with POD recover their impaired cognitive function during hospitalization, but others continue to experience impaired cognitive performance for an extended period after surgery.20–22 Nevertheless, postoperative cognitive dysfunction typically occurs during the period of 3–7 days after surgery. Our results suggested that those elderly oral cancer patients with POD would suffer more serious and prolonged cognitive deficiency.

Conclusion

In summary, the elevation of the levels of inflammatory cytokines, cortisol, and Aβ1-40 after surgery under general anesthesia might be involved in the onset of POD among elderly oral cancer patients. Early POD might subsequently induce more severe cognitive deficiency. These results may have implications for the prevention and treatment of POD.