Procedures for scans

Three live, adult males (WEN, OLY and FLP) and one post mortem, adult male (MAY) bottlenose dolphins (Tursiops truncatus Montagu) were used in this study (Table 1). This study includes two MRIs (WEN and MAY), three SPECT scans (2 WEN and 1 FLP), and four PET scans (2 WEN and 2 OLY).

Prior to this study the animals were trained to slide out of the water onto a padded transport mat (Fig. 1). Functional scans (SPECT and PET) were either baseline (no diazepam prior to ligand injection) or diazepam test scan. For scans under the influence of diazepam, the animal was given 0.55-0.60 mg kg^-1 in a fish 1 h prior to their removal from the water. Taking a lead from Mukhametov's observation that diazepam could produce unihemispheric slow waves (Mukhametov, 1987), we determined that this amount of diazepam was just over the threshold dosage for producing signs of unihemispheric EEG slow waves in our dolphins (Fig. 2). In a separate preliminary study, the dosage was as determined by EEG telemetry (D70-EEE, Transoma Medical, Aden Hills, MN, USA) from needle electrodes (25-gauge Neuroline, Ambu, Denmark) placed to the skull - two electrodes over each hemisphere while the dolphin was resting quietly, without external stimulation and with negligible movement, in our veterinary clinic (Ridgway, 2002). There was an interval of at least 2 weeks between each diazepam dose to minimize the animal's potential for developing a tolerance to diazepam.

Each scan procedure began with the dolphin voluntarily sliding onto the transport mat (Fig. 1). After a short ride to the dolphin veterinary clinic, the animal was injected with the ligand [^99mTc-bicisate for SPECT, ¹⁸F-2-fluoro-2-deoxyglucose (FDG) for PET] into the central circulation through the common brachiocephalic vein (Fig. 3) under ultrasound guidance. After injection of the ligand, the dolphin was kept in a darkened area and had movement or stimulation minimized during the ligand brain uptake period. The animal, with trainers and attending veterinarian, was then transported by covered truck to the nearby imaging facility where the scan was begun within 2 h after ligand injection.

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Fig. 2.

Unihemispheric slow waves appearing on the left brain hemisphere EEG 1 h after a dose of 0.55 mg kg^-1 of diazepam. ECG, electrocardiogram.

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Fig. 3.

(A) Ultrasound of the vetrum of the dolphin's neck showing the common brachiocephalic vein (outlined by arrows) where the ligand was injected (in the past this vein was sometimes called innominate). (B) Illustration from a dissection showing the anatomy of the area.

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Fig. 4.

MRI scan of dolphin WEN with a 0.5 T AIRIS II open scanner. The animal rests on a thin rubber pad. The forward half of the body rests on the scanner while the rear body rests on a special table constructed for dolphin scans. Attendants stabilize the animal and keep it wet while the trainer is stationed in front of the dolphin. A standard human back coil is placed around the dolphin's head immediately behind the blowhole to cover the area of the brain.

Since the tables used by the various scanners were not built to take the mass of a dolphin (180-230 kg), a special table was constructed to fit over the human table and hold all of the dolphin's mass as the animal was placed in the scanner. All of the animals were trained to remain still while out of the water. An animal trainer was present during the scans, stationed just in front of the animal (Fig. 4). The animal was kept moist during the scans by sponging its skin with water. The scanners were protected from the water by placing thin plastic sheeting under the dolphin. Respiration, body temperature (via rectal thermometer), and electrocardiogram were monitored during the procedure. Dolphins returned to their enclosures within 4 h of being removed from the water for the procedure (Fig. 1).

SPECT scans

Dolphins WEN and FLP were scanned using a SPECT scanner (ADAC Forte SPECT camera, Milpitas, CA, USA) following an administration of 50 mCi (1850 MBq) of ^99mTc-bicisate (Neurolite®), a radiopharmaceutical used to map blood flow and to diagnose vascular abnormalities of the brain (Itoh et al., 2001; Laliberte et al., 2004; Kusaka et al., 2005). More details on the scan procedure are published elsewhere (Houser et al., 2004). In the control (non-diazepam) scan, the dolphin was not given diazepam until 20 min after the Neurolite® injection so that the animal was not under the influence of the diazepam during the radiopharmaceutical uptake period. In the test scan, the diazepam was given 1 h before the injection of Neurolite® so that the animal would be under the influence of diazepam while the Neurolite® was being taken up by the brain. Blood analysis showed significant levels of circulating diazepam 1 h after oral administration (data not shown).

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Fig. 5.

(A) Time-of-flight magnetic resonance image (MRI) from dolphin WEN demonstrating anterior blood flow through arteries of the brain outlined by the box. (B) Fused MRI and SPECT images from co-registered scans made in the same dolphin. The colored region corresponds to a reduction in blood flow; the color bar indicates the relative degree of blood flow reduction with red indicating maximum reductions in blood flow. The yellow arrow indicates the central venous sinus. The red arrows indicate the homolog cerebral artery on the right side of the brain that does not show blood flow reduction. Registration, image analysis and fusion were performed with ANALYZE.

PET scans

The same non-diazepam/diazepam protocol was followed when dolphins WEN and OLY were administered 20 mCi (740 MBq) of ¹⁸F-2-fluoro-2-deoxyglucose (FDG). FDG is an analog of glucose and is often used in PET imaging to estimate glucose uptake by the brain. FDG was given ∼2 h prior to each of four scans (one with and one without prior diazepam each for WEN and OLY) to map relative metabolic activity within the brain. As in the SPECT procedure, the animal was kept in a quiet, darkened room for 20 min after injection of the ligand. The dolphin was then transported, as outlined above, to the facility where the PET scans were conducted. Images were acquired on a Seimens HR+ PET scanner (Knoxville, TN, USA) with the dolphin on the same specially engineered table as used in the SPECT scan. A 5-min transmission scan was first acquired for attenuation correction. The emission scan consisted of eight frames of 4 min acquisitions to allow for repetition in case of any subject movement. This resulted in a total scan time of approximately 37 min. The scan images were converted from the ECAT7.2 format to DICOM 3.0 for further processing (see also Houser et al., 2004).

MRI scan

The first MRI scan ever done on a live dolphin was accomplished with the dolphin WEN (Figs 4, 5). The dolphin had been exposed to the recorded sounds of the MRI scanner over 10 training periods during the month before the actual scan. The dolphin received oral diazepam (0.55 mg kg^-1 body mass) 2 h before the scan. MRI data were collected on a Hitachi Airis II, 0.5 Tesla (T) scanner. A T2 weighted pulse sequence was used to acquire image data in the axial plane. Data were acquired with a slice thickness of 8 mm, a slice interval of 9 mm, and FOV of 280. The repetition rate (TR) was set to 5700 ms, echo time (TE) set to 125 ms, and flip angle set to 90°. A total of 20 slices were acquired with a scan time of approximately 3.5 min. These scan slices were then used for registration of the SPECT and PET scans.

When a dolphin (MAY), not associated with this project, died of natural causes, the animal was perfused immediately after death with 4% paraformaledhyde in buffered ringer's solution. After fixing in situ, this brain was removed from the skull and scanned on a 3 T scanner for finer anatomical detail. Based on cranial volume measurements, the brain of MAY was of similar size to both WEN and OLY. We were not able to MRI scan subject OLY and thus registered some of the OLY scans to sections of this well-fixed post mortem brain. Some scans obtained from WEN were also registered to the MAY scans to show more anatomical details than were available in the 0.5 T scans of WEN.

Image analysis

The Subtraction Ictal SPECT co-registered to MRI algorithm, or SISCOM, was used to analyze variations in ^99mTc-bicisate distribution and FDG uptake as a function of diazepam induced unihemispheric sleep. The SISCOM procedure capitalizes on seizure-related transient increases in regional blood flow to isolate the anatomy of the brain involved in the seizure. The algorithm is amenable to other methods of assessing variation in brain function using similar isotopic methods. In this study, SISCOM was employed to isolate focal regions of the brain that demonstrated reduced blood flow or reduced metabolism following induction of unihemispheric sleep.

Data acquired from all of the imaging modalities were processed using Analyze 5.0/6.0, created by the Biomedical Imaging Resource of the Mayo Clinic (Robb, 1999). All data were converted to AVW format (native Analyze format) and volumes made cubic (equivalent voxel dimensions) through the use of linear interpolation. Test data were co-registered to the control data from the same respective scan type and animal using the normalized mutual information (NMI) voxel matching algorithm. The control volume and transformed test volume were then segmented for creation of binary masks. Using the `Morphology' module of Analyze, thresholds were applied to the volumes so that isotope activity within the brain was isolated from surrounding tissues. The volumes were then segmented and exported as a binary volume. Holes within the binary volumes were filled utilizing a 2D processing algorithm applied in the transverse, coronal and sagittal planes, and then once again in the transverse plane. The resultant control and treatment binary volumes were then multiplied together to form a binary mask common to the two volumes.

Binary masks common to the SPECT volume were multiplied by the control and co-registered test volumes, respectively, to generate masked control and co-registered treatment volumes. The information in these volumes corresponded only to combined estimates of voxels within the brain. The mean value of all non-zero voxels was determined for the masked control and masked co-registered treatment volume and mean values were subsequently used to normalize the respective volumes to a normalized mean of 100. The normalized co-registered treatment volume was then subtracted from the normalized control volume, resulting in a mean voxel value near zero, and the standard deviation of voxel values within the subtraction volume was calculated.

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Fig. 6.

Four planes from a control FDG PET scan of dolphin WEN registered to a 0.5 T scan of the same animal. No diazepam was given before the ligand injection. (A) left sagittal section (B) right sagittal section showing the vertex of the skull (V) and the planes of the axial section (Ax) and coronal section (Cx). (C) The coronal section showing the left nasal cavity (Ln), the right nasal cavity (Rn), and the planes of the axial section (Ax), left sagittal section (Lx), and the right sagittal section (Rx). (D) Axial section. The color bar indicates relative degree of glucose metabolism with red indicating maximum.

Voxels corresponding to the brain were segmented from the MRI volume and the volume passed through an inhomogeneity filter. The control volume was then co-registered to the segmented MRI volume utilizing the `Surface Matching' algorithm within Analyze. The registration was fine-tuned through manual controls and the resultant transform matrix was applied to the control volume, co-registered treatment volume, and subtraction volume. Once co-registered to the MRI volume, each of the SPECT and PET volumes were color-mapped to an 8-bit color scale and fused to the MRI to permit the overall pattern of blood flow or metabolic activity to be observed, as well as activity of focal regions within the brain to be isolated.

Local reductions in blood flow following diazepam treatment were visualized by fusing to the MRI only those voxels within the subtraction SPECT volume with values more than two standard deviations below the mean value of the subtraction volume. Similarly, local reductions in metabolism were visualized by fusing to the MRI only those voxels within the subtraction PET volume with values more than two standard deviations below the mean value of the subtraction volume. For both the PET and SPECT scans, values more than two standard deviations below the mean corresponded to a greater than 95% reduction in isotope distribution and activity, relative to the control. Thus, the anatomy to which these voxels are mapped correspond to regions of reduced blood flow (SPECT) and regions of reduced glucose uptake (PET).

Functional SPECT scans

Processing of SPECT images revealed an area of reduced blood flow around a major artery in the left hemisphere (Fig. 5). The light area at the center of the square on the left shows the left middle spinal meningeal artery, a major supply to the left brain (Fig. 5A). On Fig. 5B are overlaid regions of decreased blood flow from two previous SPECT scans imaged with 50 mCi (1850 MBq) of technetium (Tc-99m) biscisate (Neurolite®). One SPECT scan was under the influence of 0.55 mg kg^-1 of diazepam while the other was not. The colored areas show regions of a least two standard deviations of reduction in blood flow.

Functional PET scans

Pet images from dolphin WEN are shown in Figs 6 and 7. Four sample frames, left and right sagittal, coronal and axial from Dolphin WEN without diazepam treatment are shown in Fig. 6. In Fig. 7 are different coronal, axial and sagittal sections showing the reduction in glucose consumption in the diazepam scan in specific areas. In these scan comparisons from Dolphin WEN, areas of metabolic reduction were most pronounced in the right hemisphere and especially in the right posterior cortex (Fig. 7N,O), right insular cortex (Fig. 7B,M), cerebellum (Fig. 7B,C,G,N,O), and notably in the right locus coeruleus (Fig. 7F). However, some areas of marked metabolic reduction appeared in the left cortex, especially in frontal areas (Fig. 7A,E).

Fig. 8 shows raw scan sections from Dolphin OLY as seen with the program PET VIEWER® (©Tim Van den Wyngaert). Four scan sections in the left column (Fig. 8A-D) were taken without prior diazepam (control scan) while the four scan sections in the center column (Fig. 8E-H) were taken with the dolphin under the influence of 0.60 mg kg^-1 of diazepam. Sections from the diazepam scan (center column) show greater asymmetry than sections from the control scan (left column). Some selected sections (Fig. 8J-L) registered to the 3 T MRIs of Dolphin MAY and sliced on the oblique (I) to show the hippocampus (section K), reveal metabolic reduction (compared to control scan) on the left side. There is discernable metabolic reduction in the left hippocampus.