Neuroinflammation in Schizophrenia-Related Psychosis: A PET Study

Subjects

On the basis of the following inclusion criteria, 10 patients were recruited from local psychiatric hospitals: fulfillment of DSM-IV criteria for the schizophrenia spectrum (295.xx and 298.xx) (9); psychosis, that is, a total score of 14 or higher on the positive scale of the positive and negative symptoms scale (PANSS) and at least a score of 5 on 1 item or a score of 4 on 2 items of the positive scale of the PANSS; age above 18 y; no use of benzodiazepines within 3 half-lives (on average, 1–2 wk) of the benzodiazepines before the start of the study; and the ability to provide written informed consent. Healthy volunteers, matched for age and sex, were recruited by advertisement and were included if they had no personal history of psychiatric disorders, no family history of psychiatric disorders in their first-degree relatives, and no presence of inflammation as measured by C-reactive protein (CRP) levels (i.e., CRP < 0.5 mg/L). The exclusion criteria for all subjects were concomitant or past severe medical conditions, substance abuse, the use of nonsteroidal antiinflammatory drugs or paracetamol, pregnancy, and the presence of irremovable magnetic materials in or on the body. Diagnoses were classified by an experienced psychiatrist using the Schedule for Clinical Assessment in Neuropsychiatry, version 2 (SCAN2; World Health Organization). Psychopathology in patients was assessed with the PANSS by trained psychiatric nurses.

Of the 20 included subjects, 3 patients and 2 healthy volunteers were excluded. One patient withdrew from the study after MRI was performed, so no ¹¹C-(R)-PK11195 PET scan was acquired. A second patient had too much head movement during the MRI scan, and consequently the MRI scan could not be used for normalization of the PET data. A third patient had enlarged ventricles within the physiologic range, which hampered normalization of the PET scan. For the 2 healthy volunteers, the PET scans were not obtained because the arterial catheter could not be placed. No healthy volunteers were excluded because of elevated CRP.

The study was approved by the medical ethical committee of the University Medical Center Groningen. All subjects provided written informed consent after receiving a complete description of the study.

Radiochemistry

¹¹C-(R)-PK11195 was labeled by trapping ¹¹C-methyl iodide in a solution of 1 mg of (R)-N-desmethyl-PK11195 and 10 mg of potassium hydroxide in 300 μL of dimethylsulfoxide. The reaction mixture was allowed to react for 1 min at 40°C, neutralized with 1 M HCl, and passed through a 45-μm Millex-HV filter (Millipore). The filtrate was purified by high-performance liquid chromatography (HPLC) using a μBondapak C18 column (7.8 × 300 mm) (Waters) with acetonitrile/25 mM NaH₂PO₄ (pH 3.5; 55/45) as the eluent (flow, 5 mL/min). To remove the organic solvents from the product, the collected HPLC fraction (retention time, 7 min) was diluted with 100 mL of water and passed through an Oasis HLB 30-mg (1 mL) cartridge. The cartridge was washed twice with 10 mL of water and subsequently eluted with 1 mL of ethanol and 8 mL of water. The product was sterilized by filtration over a 0.20-μm Millex-LG filter (Millipore). The product was obtained in a 36% ± 12% radiochemical yield (n = 16). Quality control was performed by HPLC, using a Novapak C18 column (150 × 3.9 mm) (Waters) with acetonitrile/25 mM NaH₂PO₄ (pH 3.5) (60/40) as the eluent at a flow of 1 mL/min. The radiochemical purity was always greater than 95%, and the specific activity was 89 ± 58 GBq/μmol. No differences were found between the injected dose in healthy volunteers (398 ± 38 MBq) and that in patients (398 ± 61) (P = 0.995). The injected mass was slightly higher in patients than in healthy volunteers (1.9 ± 1.5 vs. 0.7 ± 0.4 mg/L, P = 0.051) because of a lower specific activity in patients (56 ± 42 GBq/μmol vs. 112 ± 58 GBq/μmol, P = 0.053).

PET Protocol

A catheter was inserted in the radial artery after testing for collateral circulation with the Allen test and injection of 1% lidocaine (Fresenius Kabi Nederland BV) for local anesthesia. In the other arm, a catheter was inserted in the antebrachial vein. PET was performed with the ECAT EXACT HR+ camera (Siemens). Head movement was minimized with a head-restraining adhesive band, and a neuroshield was used to minimize the interference of radiation from the subject's body. A 60-min emission scan in 3-dimensional (3D) mode was obtained, starting simultaneously with the intravenous injection of ¹¹C-(R)-PK11195. The tracer was injected at a speed of 0.5 mL/s (total volume, 8.3 mL).

After radiotracer injection, arterial blood radioactivity was continuously monitored with an automated sampling system (Veenstra Instruments). Five extra blood samples were collected at 10, 20, 30, 45, and 60 min after ¹¹C-(R)-PK11195 injection to determine the amount of radioactivity in the blood and plasma, to calibrate the sampling system. The arterial blood samples that were collected at 20, 45, and 60 min after ¹¹C-(R)-PK11195 injection were also used for metabolite analysis. These blood samples were centrifuged at 3,000g for 3 min, and 1.5 mL of plasma were collected. Then 2 mL of acetonitrile (Rathburn Chemicals Ltd.) was added to the plasma to precipitate plasma proteins. The plasma samples were shaken on a vortex mixer for 30 s and centrifuged at 3,000g for 5 min. A volume of 1 mL of the supernatant was injected into an HPLC system, consisting of a 590 HPLC pump (Waters) and an Alltima 5-μm RP-C₁₈ column (inner diameter, 250 × 10.0 mm) (Alltech). The mobile phase consisted of a mixture of 69.5% acetonitrile (Rathburn Chemicals Ltd.), 30% water (Fresenius Kabi), and 0.5% triethylamine (Merck). The flow rate was set at 5.0 mL/min, and samples were collected at intervals of 30 s. The collected samples were counted for radioactivity using a γ-counter (LKB Wallac).

MRI

All subjects underwent MRI of the brain using a 3-T Intera MRI scanner (Philips). The following images were obtained in alignment with the anterior commissure–posterior commissure plane: transaxial 3D T1-weighted gradient-echo images (repetition time [RT], 25 ms; echo time [ET], 4.6 ms; field of view [FOV], 256 × 160 × 204 mm; matrix, 265 × 265; slice thickness, 2.0 mm; 160 slices; 1 average; α = 30°), 3D T1-weighted turbo gradient-echo images (RT, 7.5 ms; ET, 3.2 ms; FOV, 260 × 160 × 232.14 mm; matrix, 265 × 265; slice thickness, 1.0 mm; 160 slices; 1 average; α = 8°), dual-echo images (RT, 3,000 ms; ET, 26.7 and 120 ms; inversion time, 2,800 ms; FOV, 220 × 150 × 175.31 mm; matrix, 265 × 265; slice thickness, 3.0 mm; 50 slices; 1 average; α = 90°), and T2-weighted fluid-attenuated inversion recovery images (RT, 11,000 ms; ET, 100 ms; inversion time, 2,800 ms; FOV, 220 × 150 × 175.31 mm; matrix, 265 × 265; slice thickness, 3.0 mm; 50 slices; 2 averages; α = 90°). The 3D T1-weighted gradient-echo MR images were used to align to the PET image for normalization. The MR images of all subjects were visually examined for structural abnormalities and neuroinflammation by an experienced neuroradiologist.

Data Analysis

Attenuation correction was performed with the separate ellipse algorithm. Images were reconstructed by filtered backprojection in 21 successive frames of increasing duration (6 × 10 s, 2 × 30 s, 3 × 1 min, 2 × 2 min, 2 × 3 min, 3 × 5 min, and 3 × 10 min). The first 2 min of the PET scan were summed to create an image that resembled a perfusion image, which was used to align the MR image to the corresponding PET image using Statistical Parametric Mapping (SPM2) software (Wellcome Department of Imaging Neuroscience). The aligned MR image was normalized to the SPM2 MRI template. The normalization was then applied to each individual frame of the PET image. A limited number of brain regions of interest (ROIs) in the neuroinflammatory process were a priori selected for comparison between psychotic patients and healthy volunteers. ¹¹C-(R)-PK11195 time–activity curves of the frontal, occipital, temporal, and parietal lobes; basal ganglia; hippocampus; and cerebellum were created using an automated ROI tool. In addition, time–activity curves of the midbrain and brain stem were created using manually drawn ROIs. The time–activity curves were used for kinetic modeling using software developed in MATLAB 7.1 (The MathWorks). The individual delay was calculated to correct for the delay in radioactivity measurements in blood, caused by the distance between the subject and the automated sampling system. Two-tissue-compartment modeling (Fig. 1) was used to calculate the K₁–k₄ using the metabolite-corrected plasma curve as an input function, correction for the individual delay, and an individually fixed blood volume, which was the median of the blood volume of all areas determined using 2-tissue-compartment modeling with a free blood volume. The fixed instead of the free blood volume was chosen because it provides a more stable measurement of K₁–k₄. The binding potential was defined as k₃/k₄ and was calculated for each ROI individually.

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FIGURE 1. 

Two-tissue-compartment model to describe kinetics of ¹¹C-(R)-PK11195. Influx of ¹¹C-(R)-PK11195 from plasma (C_P) to brain tissue is described by K₁, and efflux of ¹¹C-(R)-PK11195 from brain tissue to plasma is described by k₂. In brain tissue, ¹¹C-(R)-PK11195 can be either free (C_F) or bound to peripheral benzodiazepine receptor (C_B). Binding to receptor is described by k₃, and because ¹¹C-(R)-PK11195 binds reversibly to PBR, it can return to free compartment, as described by k₄. Binding potential is defined as k₃/k₄.

Statistics

Statistical analysis was performed with SPSS 16.0 (SPSS Inc.). One-way ANOVA was used to determine group differences between the tracer and subject characteristics and whole-brain gray matter binding potential. Statistical analysis on the binding potentials in the examined brain regions was performed using a multivariate general linear model, with the whole-brain gray matter binding potential as a covariate to correct for global ¹¹C-(R)-PK11195 uptake. To correct for multiple comparisons, the P value threshold was defined according to Bonferroni. Therefore, 0.05 was divided by the number of brain regions (n = 10), resulting in a significance threshold of 0.005. Correlations between the score on the positive scale of the PANSS and binding potentials were assessed with the Pearson product moment correlation coefficient (r) and were assumed to be significant when P was less than 0.05.

Subjects

Subject characteristics are displayed in Table 1. The diagnostic SCAN interview confirmed that all patients fit within the DSM-IV criteria of schizophrenia-spectrum disorders. Five patients were diagnosed as having schizophrenia of the paranoid type and 2 patients as having a brief psychotic disorder not otherwise specified. Six patients were scanned within 2 mo after onset of a psychotic episode, and 1 patient was chronically symptomatic. The number of lifetime psychotic episodes ranged from 1 to 4. The average score was 20 ± 3 on the positive scale of the PANSS, 17 ± 5 on the negative scale, and 37 ± 7 on the global scale. No significant differences in age were found between patients (31 ± 7) and healthy volunteers (27 ± 6) (P = 0.124).

¹¹C-(R)-PK11195 PET

A strong significantly higher ¹¹C-(R)-PK11195 binding potential was found in the hippocampus of patients than in healthy volunteers (2.07 ± 0.42 vs. 1.37 ± 0.30; P = 0.004) (Table 2). The whole-brain gray matter (Fig. 2) and white matter binding potential of ¹¹C-(R)-PK11195 were, respectively, 30% higher (1.99 ± 0.64 vs. 1.54 ± 0.41; P = 0.122) and 20% higher (2.18 ± 0.70 vs. 1.73 ± 0.51; P = 0.180) in patients than in healthy volunteers, but this difference did not reach statistical significance. A nonsignificant focal increase of ¹¹C-(R)-PK11195 binding potential was found in the midbrain (2.63 ± 0.40 vs. 1.68 ± 0.60; P = 0.014), basal ganglia (1.82 ± 0.59 vs. 1.39 ± 0.28; P = 0.017), pons (2.85 ± 1.42 vs. 1.54 ± 0.32; P = 0.027), and cerebellum (1.45 ± 0.48 vs. 1.11 ± 0.22; P = 0.040) of patients when compared with healthy volunteers. No statistically significant differences were found in the influx of ¹¹C-(R)-PK11195 (K₁) in any of the examined brain areas between patients and healthy volunteers. A significantly higher efflux (k₂) of ¹¹C-(R)-PK11195 was found in all examined brain areas in patients than in healthy volunteers (P < 0.005).

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FIGURE 2. 

Binding potential of ¹¹C-(R)-PK11195 in whole-brain gray matter. Each dot represents an individual subject, and horizontal lines represent mean values.

No correlations were found between the total score on the positive, negative, and global scales of the PANSS with both the whole-brain gray matter and hippocampal binding potential. Age, the total number of psychotic episodes, the onset of the first psychotic episode, and the duration of the psychotic episodes were not correlated to the ¹¹C-(R)-PK11195 binding potential.

MRI

Visual examination of the MRI scans by an experienced neuroradiologist did not show any gross structural abnormalities in either patients or controls. In particular, no white matter lesions, indicative of neuroinflammation, were found.