Fact-checked by Grok 2 weeks ago

Single-photon emission computed tomography

Single-photon emission computed tomography (SPECT) is a imaging technique that uses gamma rays emitted by radioactive tracers to create three-dimensional images of the tracer distribution in the body, providing functional information about organ and rather than solely anatomical details. The technique was first demonstrated in 1963 by David E. Kuhl and Roy Q. Edwards, with commercial systems becoming widely available in the 1980s. The process begins with the intravenous injection of a , such as or bound to a biologically active , which accumulates in target tissues based on their metabolic activity or blood flow. After an uptake period of 15 to 90 minutes, a rotates around the patient, detecting single s through a lead to acquire multiple two-dimensional projection images from various angles. These projections are then processed using algorithms, such as filtered backprojection or iterative methods like maximum-likelihood expectation maximization (ML-EM), to generate cross-sectional slices that form the 3D image, accounting for factors like and scatter. SPECT is widely applied in clinical settings, particularly in for assessing myocardial in (with reported sensitivity of 82% and specificity of 76%), for diagnosing conditions like (sensitivity up to 92%) and , and for tumor localization and staging. It also aids in evaluating , , and confirmation. Hybrid SPECT/CT systems enhance diagnostic accuracy by overlaying functional data with anatomical images, improving localization precision. Key advantages of SPECT include its ability to quantify physiological processes with relatively low radiation doses compared to some alternatives (e.g., approximately 11.8 mSv for cardiac stress/rest protocols) and its cost-effectiveness using widely available radionuclides. However, it faces challenges such as lower spatial resolution (typically 8-12 mm) than positron emission tomography (PET) and susceptibility to artifacts from patient motion or attenuation. Ongoing advancements, including semiconductor detectors like cadmium zinc telluride for improved energy resolution (3-4% at 140 keV) and advanced collimators, continue to enhance image quality and clinical utility.

Introduction

Definition and fundamentals

Single-photon emission computed tomography (SPECT) is a imaging technique that utilizes gamma rays emitted from radioisotopes to generate three-dimensional, cross-sectional images depicting the distribution of radiotracers within the body. This method provides functional information about physiological processes, such as organ , metabolism, and receptor binding, rather than detailed anatomical structures. By administering a radiotracer labeled with a gamma-emitting , SPECT enables the of tracer uptake in specific tissues, offering insights into states like myocardial ischemia or neurological disorders. Unlike planar scintigraphy, which produces two-dimensional projections by capturing gamma rays from a single viewpoint, SPECT acquires multiple projections from various angles around the patient to enable of a three-dimensional volume. This multi-angle approach allows for improved localization and quantification of radiotracer activity, reducing superimposition artifacts inherent in planar imaging. In contrast to (PET), which relies on positron-emitting isotopes that annihilate to produce pairs of 511 keV photons detected in , SPECT detects individual gamma photons emitted directly by single-photon emitters, typically at lower energies around 140 keV. Common isotopes include (Tc-99m), (I-123), and thallium-201 (Tl-201), selected for their suitable half-lives and photon energies that facilitate detection while minimizing patient radiation dose. The basic process of SPECT begins with the intravenous injection of a radiotracer, which distributes according to its biodistribution properties and accumulates in target tissues. The radioisotope decays, emitting gamma rays isotropically from the site of accumulation. These photons are detected externally, and through rotational acquisition of projection data, a three-dimensional functional image is reconstructed to map the of the tracer. This functional assessment is particularly valuable for evaluating dynamic processes, such as blood flow or activity, where anatomical alone may be insufficient. A fundamental physical challenge in SPECT is attenuation, where photons are absorbed or scattered by intervening tissues, leading to reduced detection efficiency and distortions in the reconstructed image. The of detected photons follows an law, expressed conceptually as I = I_0 e^{-\mu x}, where I_0 is the initial , \mu is the linear dependent on tissue type and , and x is the path length through the attenuating medium. This varies with body depth and composition, necessitating corrections to achieve quantitative accuracy in tracer concentration estimates.

Historical development

The development of single-photon emission computed tomography (SPECT) traces its roots to advancements in imaging during the mid-20th century. The foundational technology emerged with the invention of the Anger camera in 1958 by Hal O. Anger, which revolutionized by enabling the detection of gamma rays from radioactive tracers using a scintillation crystal and photomultiplier tubes, laying the groundwork for tomographic applications. This device improved upon earlier rectilinear scanners, allowing for faster and more efficient planar imaging that would later support three-dimensional reconstruction. Key progress in occurred in the 1960s, with E. Kuhl and Q. Edwards demonstrating the first emission tomography system in 1963, using a focused and stationary detectors to produce cross-sectional images from emissions. Their work introduced the concept of computed tomography for single-photon emitters, initially applied to phantom studies and simple clinical cases. The introduction of (Tc-99m) as a versatile radiotracer around 1960, proposed by Powell Richards for medical use due to its ideal 140 keV gamma emission and short half-life, significantly enhanced SPECT's feasibility by improving image quality and reducing patient radiation dose compared to earlier isotopes like iodine-131. By the late 1970s, the first practical SPECT systems utilizing rotating cameras were developed, enabling clinical brain imaging studies for conditions such as and tumors, with prototypes like the University of Michigan's "Humongatron" in 1974 marking early human applications. Commercialization accelerated in the with the availability of multi-headed gamma cameras, such as those from Picker International by 1988, which reduced acquisition times and improved resolution for routine use, transitioning SPECT from research to widespread clinical practice. By the 1990s, SPECT had gained prominence in for , particularly with Tc-99m-based tracers like sestamibi, allowing non-invasive assessment of and becoming a standard diagnostic tool. The turn of the millennium brought hybrid imaging with the introduction of the first commercial SPECT/CT system, GE Healthcare's in 1999, which integrated computed tomography for attenuation correction and anatomical correlation, enhancing diagnostic accuracy. Detector technology evolved in the 2000s with the adoption of (CZT) semiconductors, replacing traditional (NaI) crystals to offer higher energy resolution (around 5%) and sensitivity, as seen in systems like GE's Discovery NM 530c introduced in 2009, further improving spatial resolution for cardiac and applications.

Physics and Instrumentation

Detection of gamma rays

In single-photon emission computed tomography (SPECT), gamma rays are produced through the isomeric transition of excited nuclei in radiotracers, such as (Tc-99m), which emits monoenergetic photons at 140 keV. These gamma rays are emitted isotropically, meaning they radiate uniformly in all directions from the decay site within the patient's body. As gamma rays traverse biological tissue, they interact via three primary mechanisms: the , , and . In the , dominant at lower energies, the is fully absorbed by ejecting an inner-shell from an atom, with the probability increasing with (Z) and decreasing with (E). , prevalent at intermediate energies like 140 keV, involves partial energy transfer to an outer-shell , resulting in a scattered of lower energy that degrades image quality by contributing to background noise. , relevant only above 1.022 MeV, converts the into an electron-positron pair near the and is negligible for typical SPECT energies. The overall probability of these interactions is quantified by the linear μ(E), which is energy-dependent and material-specific, governing the exponential reduction in photon intensity as I = I_0 e^{-μ(E) x}, where x is the path length through the attenuating medium. Upon exiting the patient, gamma rays are collimated to reach the detector, where unscattered or minimally scattered photons interact with a thallium-activated [NaI(Tl)] crystal, converting their energy into visible light photons. This scintillation light is then detected by an array of photomultiplier tubes (PMTs), which amplify the signal into an electrical pulse proportional to the incident energy. The position of interaction is determined from the relative outputs of the PMTs using Anger logic. Pulse height analysis processes these electrical pulses to discriminate events based on energy, accepting only those within a photopeak window (e.g., 126–154 keV for Tc-99m) to reject Compton-scattered photons with reduced energy. The energy resolution of NaI(Tl) crystals, defined as the full width at half maximum (FWHM) of the photopeak divided by the photopeak energy, is approximately ΔE/E ≈ 10% at 140 keV, enabling effective scatter rejection but limiting the distinction of closely spaced energies. To further mitigate scatter, basic correction employs the dual-energy window method, which acquires counts in a lower-energy scatter window (e.g., 110–140 keV) adjacent to the photopeak and subtracts an estimated scatter fraction from the primary window counts, assuming a linear relationship between scatter and primary events.

Gamma camera components and collimators

The gamma camera serves as the primary detection system in single-photon emission computed tomography (SPECT), comprising several integrated hardware elements that convert interactions into spatial and energy information. Central to this is the scintillation crystal, typically thallium-doped [NaI(Tl)], which is a large, flat disk approximately 40 cm in diameter and 9.5 mm thick to optimize detection of 140 keV photons from common isotopes like . When a interacts via photoelectric absorption or , the crystal emits visible light photons proportional to the incident energy, enabling subsequent signal amplification. The light output from the crystal is captured by an array of 30 to 100 photomultiplier tubes (s), arranged in a hexagonal pattern for uniform coverage and minimal . Each consists of a photocathode that converts light into photoelectrons, followed by a series of dynodes that multiply the electrons through secondary emission, producing an amplified electrical pulse with gains up to 10^6. The relative intensities of signals from multiple s allow localization of the interaction site via Anger logic, weighting contributions based on proximity to the event. These outputs, being low-amplitude pulses, are fed into preamplifiers to boost signal strength while preserving pulse shape and reducing noise pickup over cabling. The preamplified signals then pass to analog-to-digital converters (ADCs), which sample and quantize the voltages into digital values, typically at 10-12 bits , for computer-based processing of energy spectra and event positioning. Modern systems often integrate ADCs directly at the PMT bases to minimize signal degradation. Collimators are essential lead or tungsten structures mounted anterior to the crystal, designed to restrict gamma rays to specific directions and reject scattered photons, thereby defining spatial resolution. The parallel-hole collimator, the most widely used type in clinical SPECT, features thousands of parallel cylindrical or hexagonal holes that permit only near-perpendicular rays to reach the detector, yielding uniform but moderate resolution across the field of view. Alternative designs include pinhole collimators for high-magnification imaging of small structures, converging collimators that angle holes to focus on a central region for improved sensitivity in targeted areas, and fan-beam collimators optimized for linear organs like the heart or spine. These types involve inherent trade-offs, where enhanced resolution from finer apertures reduces sensitivity by limiting photon acceptance. For pinhole collimators, spatial resolution R in the object plane is approximated by R \approx d \times \frac{a + b}{a}, where d is the aperture diameter, a the source-to-aperture distance, and b the aperture-to-detector distance, highlighting the effect of distances on resolution. Key design parameters for collimators include hole diameter d (typically 1-3 mm for high ), length L (20-50 mm to reduce ), and septa thickness t (0.15-0.5 mm to absorb stray photons without excessive weight). These influence both and ; longer holes improve directionality but lower throughput. The geometric g for parallel-hole collimators, representing the of emitted gamma rays that traverse the holes, is approximated by g \approx \left( \frac{d}{d+t} \right)^2 \frac{d^2}{4 L^2}, assuming negligible . To accelerate SPECT acquisition, many systems incorporate multi-head gamma cameras with two or three detectors mounted on a rotating , allowing simultaneous projections from multiple angles and halving or thirding scan times relative to single-head setups. Dual-head cameras typically rotate 180 degrees per cycle, while triple-head systems cover 120 degrees, both orbiting the patient for full 360-degree sampling. configurations, often paired with multi-pinhole or coded-aperture collimators, avoid mechanical rotation by fixing multiple detectors around the subject, enabling continuous but requiring complex . Emerging SPECT detectors utilize (CZT) semiconductors for direct gamma-to-charge conversion, bypassing the step and light collection inefficiencies of NaI(Tl). CZT pixels, typically 2.5 mm in size and arranged in modules, provide superior energy resolution of approximately 5% at 140 keV—compared to 10% for NaI(Tl)—due to reduced statistical fluctuations and better charge collection, enhancing scatter discrimination and overall image contrast.

Radiopharmaceuticals

Types of radiotracers used in SPECT

Single-photon emission computed tomography (SPECT) relies on radiotracers that emit gamma rays for imaging, with selection primarily based on the radioisotope's physical properties and the tracer's biological targeting. The most commonly used radioisotopes in clinical SPECT are (Tc-99m), (I-123), thallium-201 (Tl-201), and (In-111). , the workhorse of SPECT due to its optimal characteristics, has a physical of 6 hours and emits gamma rays at 140 keV, allowing efficient detection with sodium iodide crystals while minimizing tissue penetration issues. features a 13-hour and 159 keV photons, suitable for and studies. Tl-201, with a 73-hour , emits lower-energy photons at 69-167 keV, often used in cardiac perfusion despite challenges from mercury x-rays. , possessing a 2.8-day and photons at 171 and 245 keV, is employed for and tumor imaging but requires careful collimation due to higher energy. Radiotracers are categorized by their functional roles, such as agents, receptor-binding agents, and agents. tracers like Tc-99m-sestamibi accumulate in myocardial tissue proportional to blood flow, enabling assessment of . Receptor-binding tracers, such as I-123-IBZM, target specific receptors like D2 in the for neurological evaluations. tracers, including Tc-99m-DTPA , are inhaled to map airflow, often paired with scans for ventilation- mismatch detection in . Production methods differ by isotope: Tc-99m is obtained via generator systems from molybdenum-99 (Mo-99) decay, providing on-site availability without cyclotrons. In contrast, I-123 is produced using cyclotron irradiation of xenon-124 or tellurium targets, necessitating specialized facilities. The decay of these isotopes follows the exponential law N(t) = N_0 e^{-\lambda t}, where N(t) is the number of undecayed nuclei at time t, N_0 is the initial number, and \lambda = \frac{\ln 2}{T_{1/2}} is the decay constant with T_{1/2} as the half-life; this governs tracer activity over the imaging window. Key selection criteria for SPECT radiotracers include photon energy compatibility with detector efficiency (ideally 100-200 keV for optimal collimation and ), half-life matching the biological uptake and duration (e.g., 4-24 hours to balance decay and distribution), and low to minimize patient risk. For instance, a typical Tc-99m-based SPECT scan delivers an effective dose of approximately 10 mSv, comparable to a few years of natural . Emerging SPECT tracers include gallium-67 (Ga-67), with a 3.26-day and emissions at 93-185 keV, which is gaining renewed interest for due to uptake in inflammatory sites, and 99mTc-p5+14 (AT-05), a pan-amyloid agent currently in phase 1 clinical trials as of 2025 for detecting various types of using SPECT/.

Tracer preparation, administration, and biodistribution

Radiotracers for SPECT imaging are prepared in dedicated hot laboratories, where sterile adheres to standards such as <825> to ensure aseptic conditions and prevent contamination. Preparation involves labeling the carrier molecule with a like (Tc-99m), followed by rigorous quality control measures, including assessment of radiochemical purity, which must exceed 95%, and labeling efficiency to confirm stable binding. These steps, performed prior to patient administration, verify the tracer's integrity and minimize risks from impurities or free . Administration of SPECT radiotracers typically occurs via intravenous injection, with doses ranging from 5 to 20 (185 to 740 MBq) for common Tc-99m-based agents, adjusted based on the specific tracer and clinical . For myocardial studies, stress and rest s may involve sequential injections, while patient preparation can include for certain tracers to optimize . Injection is performed slowly to reduce discomfort and ensure even distribution, with imaging timed to capture peak organ as detailed in acquisition parameters. Biodistribution refers to the migration, accumulation, and elimination of the radiotracer, which varies by agent but follows predictable patterns for effective SPECT visualization. For example, Tc-99m-methylene diphosphonate (MDP), a common tracer, exhibits approximately 50% uptake in the within 2 to 4 hours post-injection, proportional to osteoblastic activity. Clearance primarily occurs via the kidneys for hydrophilic tracers like MDP, with residual activity excreted in , while hepatobiliary routes dominate for lipophilic agents; time-activity curves generated from dynamic quantify these , showing initial vascular distribution followed by organ-specific accumulation and decay. Several factors influence tracer biodistribution, including patient physiology such as renal function, which can prolong clearance in impaired kidneys and alter uptake patterns. Motion artifacts from patient movement or respiratory effects may distort distribution uniformity, while attenuation from body tissues can reduce detected signal intensity in deeper organs. Handling radiotracers emphasizes the ALARA principle to minimize unnecessary to staff through time, distance, and shielding optimizations. Spill protocols classify incidents as minor (e.g., <100 mCi Tc-99m) or major, requiring immediate area evacuation, notification of the radiation safety officer, containment with absorbent materials, and post-cleanup surveys to ensure decontamination. Dosimetry calculations estimate organ absorbed doses using the formula D = \tilde{A} \times S, where D is the absorbed dose, \tilde{A} is the cumulated activity in the source organ, and S is the S-value representing mean dose per unit cumulated activity from the Medical Internal Radiation Dose (MIRD) committee methodology.

Image Acquisition

Scanning protocols and patient positioning

Scanning protocols for single-photon emission computed tomography (SPECT) typically involve a circular or non-circular orbit of the gamma camera detectors around the patient, with a full 360° rotation commonly used for most applications to acquire comprehensive data, although 180° orbits are preferred for cardiac imaging to reduce time and breast attenuation artifacts in women. The acquisition generally includes 64 to 128 projections, with 20 to 30 seconds per projection, resulting in a total scan time of 15 to 30 minutes depending on the radiotracer activity and clinical indication. Energy windows are set at 15% to 20% around the photopeak of the isotope, such as 140 keV for technetium-99m, to optimize count detection while minimizing scatter. Patient positioning is standardized to ensure reproducibility and minimize motion artifacts, with the supine position used for the majority of scans and arms elevated above the head for torso imaging to avoid attenuation from overlying tissues. Immobilization devices, such as straps or cushions, are employed to maintain stability, particularly for longer acquisitions, and for cardiac studies, electrocardiogram (ECG) gating synchronizes data collection to the cardiac cycle for functional assessment. Region-specific adjustments include prone or supine positioning for cardiac perfusion to address diaphragmatic attenuation, head holders or foam padding for brain imaging to prevent movement, and step-and-shoot modes for whole-body scans covering from skull base to mid-thigh. Image parameters are optimized for resolution and count statistics, using a 128×128 matrix for most applications to balance detail and acquisition time, with zoom factors applied to focus on smaller organs like the thyroid or brain. For pediatric patients, protocols incorporate reduced radiotracer doses scaled to body weight—often following the European Association of Nuclear Medicine (EANM) pediatric dosage card—to minimize radiation exposure, alongside shorter scan times and motion correction software to account for involuntary movements. These adaptations ensure diagnostic quality while adhering to the ALARA (as low as reasonably achievable) principle in younger populations.

Data collection parameters

In single-photon emission computed tomography (SPECT), projection data are acquired by rotating the gamma camera around the patient, typically in angular steps of 3° to 6° to ensure adequate sampling over 180° or 360° orbits, with 60 to 128 projections commonly used depending on the matrix size and resolution requirements. Binning of projection data targets sufficient statistical quality, typically 1 to 2 million counts in the target organ or region of interest per study, though higher total counts (e.g., ≥10 million detected photons) are recommended for applications like gated cardiac imaging to balance noise and acquisition time while accounting for temporal binning. Energy discrimination is critical during data collection, with the primary energy window set symmetrically around the photopeak (e.g., 15% to 20% width centered at 140 keV for ) to capture unscattered photons, while a lower scatter window (typically 10% to 15% below the photopeak) estimates Compton scatter contributions for subsequent correction. System acceptance criteria include minimal photopeak shift (typically within ± a few keV of the nominal energy) to maintain spectral integrity, verified through daily quality control. Acquisition modes vary by study type: list-mode records individual photon events with timestamps and coordinates for dynamic or gated analyses, enabling flexible post-processing, whereas static mode accumulates binned projections for perfusion or uptake studies. Orbit paths are generally circular for simplicity but can be elliptical to approximate the patient's contour and reduce attenuation variations, with continuous rotation preferred over step-and-shoot for faster acquisition in modern systems. Count statistics in SPECT follow a Poisson distribution, where the variance equals the mean number of counts (σ² = N), leading to signal-to-noise ratios that scale with the square root of total counts and necessitating optimized acquisition times (typically 15 to 30 minutes) to achieve clinically acceptable noise levels without excessive patient discomfort. To mitigate artifacts, pre-scan uniformity checks using high-count flood fields (e.g., 10 to 30 million counts) are performed daily to detect and correct detector inhomogeneities, while in whole-body imaging, precise bed movement control (e.g., via automated positioning) prevents misalignment and streak artifacts from projection inconsistencies.

Image Reconstruction

Mathematical foundations of reconstruction

The reconstruction of three-dimensional (3D) images in single-photon emission computed tomography (SPECT) involves inverting the projection data acquired from multiple angles to estimate the radionuclide activity distribution within the patient. This process is fundamentally an inverse problem, modeled as solving for the activity density function f(\mathbf{r}) from measured projections g(\theta, s), where \theta denotes the projection angle and s the radial distance. The mathematical foundations draw from integral geometry and statistical estimation, accounting for the physics of gamma-ray detection, including attenuation and collimation effects. Central to SPECT reconstruction is the Radon transform, which describes the projections as line integrals through the 2D activity distribution f(x, y) (extended to 3D via parallel slices or full 3D models). The forward projection is given by p(\theta, s) = \int_{-\infty}^{\infty} \int_{-\infty}^{\infty} f(x, y) \, \delta(x \cos \theta + y \sin \theta - s) \, dx \, dy, where \delta is the Dirac delta function, representing the integral along the line perpendicular to the direction \theta at offset s. This transform, originally formulated by Johann Radon in 1917, underpins the relationship between the object and its projections, enabling theoretical inversion for image recovery. In SPECT, the measured projections approximate this transform but are blurred by collimator geometry and degraded by photon attenuation and scatter. A foundational analytical method for inversion is filtered back-projection (FBP), which compensates for the blurring inherent in simple back-projection by applying a frequency-domain filter to the projections before summation. The back-projection operator smears each projection across the image plane, leading to a reconstructed image with resolution loss; FBP deconvolves this using a ramp filter H(\omega) = |\omega| in the Fourier domain, derived from the central slice theorem. The reconstructed activity at polar coordinates (r, \phi) is f(r, \phi) = \int_0^\pi p(\theta, r \cos(\theta - \phi)) * h(\theta) \, d\theta, where * denotes convolution with the filter kernel h(\theta), the inverse Fourier transform of the ramp filter. This approach yields exact reconstruction for noise-free parallel-beam data but amplifies high-frequency noise in SPECT projections, often requiring additional low-pass filtering (e.g., Butterworth) for practical use. FBP remains computationally efficient and is widely implemented in clinical systems despite its sensitivity to inconsistencies like attenuation. To address the Poisson noise statistics of photon-counting data and incorporate physical models, iterative methods such as expectation-maximization (EM) provide a statistical framework for reconstruction. The maximum-likelihood EM (MLEM) algorithm maximizes the likelihood of the observed projections under a Poisson model, iteratively updating the estimate of f via the system matrix A that models projection geometry, attenuation, and collimation. The update rule is f_j^{(k+1)} = f_j^{(k)} \frac{1}{n} \sum_{i=1}^n \frac{a_{ij} g_i}{\sum_{j'=1}^m a_{ij'} f_{j'}^{(k)}}, where k is the iteration, n the number of projections, and a_{ij} the probability of a photon from voxel j contributing to bin i. Introduced for emission tomography by Shepp and Vardi in 1982, MLEM converges monotonically to the maximum-likelihood solution, offering superior noise handling and quantitative accuracy compared to FBP, though at higher computational cost. The system matrix A explicitly models collimator response (via Monte Carlo or analytical kernels) and attenuation, enabling corrections during iteration. Attenuation in SPECT arises from photoelectric and Compton interactions in tissue, causing exponential decay of photon fluence along ray paths, which distorts projections and biases activity estimates toward superficial regions. The attenuated projection is modeled as g(s, \theta) = \int \int f(x, y) \exp\left( -\int_{(x,y)}^{detector} \mu(l) \, dl \right) \delta(x \cos \theta + y \sin \theta - s) \, dx \, dy, where \mu(l) is the linear attenuation coefficient along the path. The attenuation map \mu-map is typically derived from transmission scans (e.g., via gadolinium-153 sources) or hybrid CT imaging, allowing compensation in both FBP (via preprocessing) and iterative methods (via A). Without correction, quantitative errors can exceed 50% in deep structures. Fundamental resolution limits in SPECT stem from the collimator's point spread function (PSF), which governs the geometric blurring of projections. The collimator PSF, primarily from parallel-hole designs, results in a system spatial resolution characterized by the full-width at half-maximum (FWHM) of approximately 10-15 mm for typical clinical setups at 10-15 cm source-to-collimator distances. This limit arises from hole diameter, length, and septal thickness, degrading further with distance (linearly increasing FWHM) and photon energy, constraining the detection of sub-centimeter lesions despite intrinsic detector resolution of 3-4 mm.

Algorithms and attenuation correction

Image reconstruction in single-photon emission computed tomography (SPECT) relies on algorithms that invert the projection data to form volumetric images, with serving as a foundational analytical method. Variants of FBP incorporate pre-correction for attenuation by estimating a uniform linear attenuation coefficient, typically \mu = 0.15 \, \text{cm}^{-1} for water-equivalent tissue, as proposed in the seminal . This approach multiplies the projections by an exponential factor e^{\mu d/2} (where d is the distance through the attenuating medium) before filtering and back-projection, reducing artifacts from photon absorption but assuming homogeneous attenuation, which limits accuracy in heterogeneous anatomies. Iterative reconstruction algorithms, such as ordered subset expectation maximization (OSEM), have largely supplanted FBP due to their ability to model physical processes explicitly and converge to more accurate solutions with fewer iterations. OSEM accelerates the maximum likelihood expectation maximization (MLEM) by dividing projections into subsets and updating the image estimate sequentially, with the core update given by f^{k+1} = f^k \cdot \frac{\sum y_j / \sum (c_j \cdot f^k)}{\text{sensitivity}}, where f^k is the image estimate at iteration k, y_j are the measured projections, and c_j represents the system matrix elements. This method improves noise handling and lesion contrast compared to FBP, particularly when incorporating corrections for attenuation and scatter. Attenuation correction in SPECT addresses the exponential reduction in detected photons, with techniques evolving from approximate methods to patient-specific mapping. Transmission scanning using a gadolinium-153 (Gd-153) line source, which emits 97- and 103-keV photons suitable for mimicking Tc-99m attenuation, provides an empirical attenuation map by acquiring separate low-activity scans before or after emission imaging. This map is then used to compute path-length-dependent corrections during reconstruction. In hybrid SPECT/CT systems, computed tomography (CT) generates the attenuation map, which is scaled from Hounsfield units (HU, ranging 0-100 for soft tissue) to linear coefficients (0.1-0.2 cm^{-1} at 140 keV) via bilinear transformation, such as \mu = 0.15 \times (\text{HU} + 1000) / 1000 for soft tissue regions (with separate scaling for bone in full bilinear methods), enabling precise correction without additional radionuclide exposure. Scatter correction mitigates Compton scattering, which degrades spatial resolution and quantitative accuracy by adding low-energy events to the photopeak window. The triple-energy window (TEW) method estimates scatter fraction by placing narrow sub-windows adjacent to the primary photopeak (e.g., 20% width at 140 keV for ), with the scatter estimate S approximated as S = \bar{C}_{sc} \times (W_p / W_s), where \bar{C}_{sc} is the average counts in the sub-windows, W_p is the photopeak window width, and W_s the scatter window width; this is subtracted pixel-by-pixel from the projections. TEW is computationally efficient and effective for isotopes like or , improving contrast recovery by 10-20% in phantom studies without requiring Monte Carlo simulations. Resolution recovery enhances image sharpness by modeling the point spread function (PSF) of the collimator and detector within the reconstruction, particularly in OSEM iterations. The PSF, often depth-dependent and Gaussian-approximated, is incorporated into the system matrix c_j, compensating for blurring that limits SPECT resolution to 8-12 mm FWHM. Typical implementations use 10-20 OSEM iterations with 8-16 subsets to balance convergence and noise amplification, yielding 20-30% improvements in lesion detectability over uncorrected methods in clinical cardiac and oncology imaging.

Hybrid Systems

SPECT/CT integration

Single-photon emission computed tomography (SPECT) integrated with computed tomography (CT) in hybrid systems typically features co-registered low-dose CT scanners mounted on the same gantry as rotating SPECT detector heads, enabling sequential acquisition where CT imaging precedes or follows SPECT data collection to minimize patient repositioning. Most clinical systems employ sequential modes to accommodate the distinct hardware requirements of gamma detection and X-ray imaging, though some advanced designs, such as those with stationary detectors, support near-simultaneous acquisition for reduced scan times. This configuration was first commercialized in 1999 with the system, marking the advent of practical hybrid SPECT/CT platforms. The primary benefits of SPECT/CT integration stem from the CT component's ability to generate accurate attenuation and scatter maps, which compensate for photon absorption and Compton scattering in SPECT reconstructions, thereby enhancing quantitative accuracy and image contrast. Additionally, CT provides high-resolution anatomical detail that localizes functional abnormalities detected by SPECT, such as metabolically active hotspots, improving diagnostic confidence without relying on separate imaging sessions. For attenuation-only purposes, CT protocols often use low-dose settings of 80-140 kV and 10-50 mAs to balance radiation exposure with sufficient density mapping, while diagnostic modes employ higher parameters, such as 140 kV and up to 80 mA, for detailed structural evaluation. Registration challenges in SPECT/CT arise primarily from patient motion, including respiratory and involuntary movements, which can cause misalignment between sequentially acquired datasets, leading to artifacts in fused images. Software-based fusion algorithms, such as rigid or deformable registration techniques, mitigate these issues by aligning images post-acquisition, though residual errors may persist in areas prone to deformation like the abdomen. Clinically, SPECT/CT integration has significantly boosted specificity in oncological applications, for instance, by distinguishing malignant bone lesions from degenerative changes in 99mTc-MDP scans, achieving up to 92% definitive diagnoses compared to SPECT alone. In prostate cancer staging, SPECT/CT with PSMA tracers (including emerging 99mTc-labeled variants) enhances lesion localization and reduces equivocal findings; studies indicate management changes in approximately 15% of cases for 99mTc-PSMA, while across various tumors like thyroid (up to 25%) and neuroendocrine malignancies (around 14-30%), it influences therapeutic decisions in 14-30% of cases.

Emerging SPECT/MRI and other hybrids

The integration of single-photon emission computed tomography (SPECT) with magnetic resonance imaging (MRI) represents an emerging hybrid modality aimed at combining functional nuclear imaging with high-contrast anatomical detail, particularly for applications in neurology and oncology. Feasibility studies have highlighted significant challenges posed by the strong magnetic fields of MRI systems, which can distort the trajectories of photoelectrons in traditional photomultiplier tube (PMT)-based gamma detectors, leading to reduced spatial resolution and energy discrimination. To address this, prototype systems have employed shielded PMTs coupled with optical fibers or solid-state detectors such as cadmium zinc telluride (CZT) and silicon photomultipliers (SiPMs), which are less susceptible to magnetic interference and enable compact designs suitable for insertion into MRI bores. One notable prototype is the INSERT (Imaging System for Significant Tumor Response Evaluation in Neuro-oncology Trials) project, developed as the first clinical brain insert for simultaneous operation within a commercial 3T MRI scanner. This system utilizes a ring of 10 detector modules with CsI(Tl) scintillators and a multislit-slat collimator to achieve stationary acquisition without mechanical motion, demonstrating preclinical imaging of phantoms and small animals with resolutions around 8-10 mm. The advantages of SPECT/MRI hybrids include superior soft-tissue contrast from MRI, which enhances the localization of SPECT-detected radiotracer uptake in brain tumors and oncological lesions, while enabling multi-radionuclide imaging (e.g., with 99mTc and 111In) for improved dosimetry and treatment monitoring. Simultaneous acquisition further reduces total scan times, minimizes patient motion artifacts through MRI-based navigators, and facilitates real-time kinematic studies, offering potential benefits over sequential systems in dynamic processes like tumor response assessment. Beyond SPECT/MRI, other hybrid configurations include SPECT/PET combinations designed for comprehensive nuclear imaging by leveraging the higher sensitivity of PET with the broader isotope availability of SPECT. For instance, novel Compton imaging techniques allow simultaneous in vivo detection of PET (e.g., 18F) and SPECT (e.g., 99mTc) tracers in preclinical models, achieving resolutions around 4 mm FWHM for multi-tracer studies without physical detector modifications. In preclinical settings, optical/SPECT hybrids integrate bioluminescence or fluorescence tomography with gamma detection to provide molecular-level insights into disease progression, as exemplified by systems like the MILabs VECTor platform, which combines optical CT with SPECT for whole-body small-animal imaging of reporter gene expression and radiotracer biodistribution. Technical hurdles in these hybrids persist, including radiofrequency (RF) interference from MRI gradients that can induce noise in SPECT signals, as well as gradient-induced eddy currents causing mechanical vibrations in detector components. Attenuation correction remains complex, often relying on MRI-derived μ-maps to estimate photon scatter and absorption, though inaccuracies arise from differences in tissue segmentation between modalities. These issues necessitate advanced shielding with non-magnetic materials like tungsten and active cooling systems to maintain detector performance at low temperatures (e.g., 0°C). As of 2025, SPECT/MRI and related hybrids remain predominantly investigational, with limited clinical deployment confined to research prototypes like INSERT, which has enabled initial phantom and preclinical validations but no reported human studies, awaiting further engineering refinements and trials for regulatory approval and transition to routine clinical use.

Clinical Applications

Cardiovascular imaging

Single-photon emission computed tomography (SPECT) plays a central role in cardiovascular imaging by evaluating myocardial perfusion, ventricular function, and tissue viability, aiding in the diagnosis and management of coronary artery disease (CAD). In myocardial perfusion imaging (MPI), SPECT uses technetium-99m (Tc-99m)-labeled agents such as sestamibi or tetrofosmin to assess blood flow at rest and during stress, typically induced by exercise or pharmacologic agents like adenosine. Recent protocols also enable quantitative assessment of myocardial blood flow (MBF) using dynamic SPECT imaging, providing absolute flow values (typically 1-5 ml/min/g at rest) for improved detection of multivessel disease and prognosis. Protocols often follow a one-day stress-first approach, where stress imaging precedes rest imaging only if abnormalities are detected, minimizing radiation exposure while identifying perfusion defects. Reversible defects on stress-rest comparison indicate ischemia, distinguishing them from fixed defects suggestive of infarction. Gated SPECT enhances functional assessment by synchronizing image acquisition with the cardiac cycle, allowing calculation of left ventricular ejection fraction (LVEF) from end-diastolic and end-systolic volumes. Automated software, such as Quantitative Gated SPECT (QGS) or 4D-MSPECT, processes these data to derive LVEF with high reproducibility, correlating well with echocardiography. This technique provides insights into wall motion abnormalities and systolic function, offering prognostic value beyond perfusion alone; for instance, post-stress LVEF below 40% predicts higher cardiac event rates. For viability assessment, SPECT employs thallium-201 (Tl-201) in rest-redistribution protocols, where initial rest images are followed by redistribution imaging 3-4 hours later to detect improved uptake in hypoperfused but viable myocardium. Uptake greater than 50-60% of normal on redistribution images predicts functional recovery post-revascularization, unlike fixed defects indicating scar tissue. Unlike positron emission tomography (PET), which uses fluorodeoxyglucose (FDG) for metabolic viability, SPECT relies on perfusion-based tracers like Tl-201, though it may underestimate viability in severe ischemia without late imaging. Quantitative metrics in SPECT MPI standardize interpretation and risk stratification. The summed stress score (SSS) aggregates perfusion defects across a 17-segment model using a 5-point scale, with SSS ≥4 indicating abnormality and higher values correlating with extensive ischemia or infarction. Transient ischemic dilation (TID), measured as the ratio of stress to rest left ventricular volumes, exceeds 1.22 in abnormal cases, signaling severe multivessel disease even with mild perfusion defects. According to ACC/AHA guidelines, SPECT MPI is recommended for patients with intermediate pretest probability of CAD, demonstrating sensitivity of 85-92% and specificity of 67-85% for detecting significant stenosis (>50% luminal narrowing). Normal stress SPECT results predict a low annual risk (<1%) of cardiac death or myocardial infarction.

Neurological imaging

Single-photon emission computed tomography (SPECT) plays a crucial role in neurological imaging by assessing cerebral perfusion and neurotransmitter systems, providing functional insights into brain disorders. In perfusion imaging, tracers such as or are used to measure cerebral blood flow (CBF), enabling quantitative evaluation in units of ml/100g/min. For instance, normal CBF values typically range from 70 to 80 ml/100g/min in gray matter, with reductions indicating hypoperfusion in conditions like or . This technique relies on the first-pass extraction of the tracer, allowing for regional mapping of blood flow distribution across the brain. In evaluating the dopamine system, SPECT with iodine-123-ioflupane (I-123-FP-CIT), known as DaTSCAN, visualizes striatal dopamine transporter density, aiding in the diagnosis of Parkinson's disease and related disorders. A striatal binding ratio below approximately 2.0 (threshold varies by software and database) suggests dopaminergic deficit, while normal values are typically 4-6, with high specificity (up to 95%) for differentiating Parkinson's from essential tremor. The U.S. Food and Drug Administration (FDA) approved DaTSCAN in 2011 for detecting striatal dopamine transporter loss in patients with suspected parkinsonian syndromes. This tracer's uptake correlates with nigrostriatal pathway integrity, offering a non-invasive alternative to positron emission tomography (PET) for routine clinical use. For dementia assessment, SPECT perfusion imaging reveals characteristic patterns, such as temporal and parietal hypoperfusion in , which supports diagnosis with a sensitivity of 80-90% when combined with clinical criteria. In contrast, shows anterior hypoperfusion, helping to distinguish etiologies. These findings are based on standardized quantitative analysis, often using statistical parametric mapping to compare patient scans against normative databases. In epilepsy, SPECT identifies seizure foci through ictal-interictal mismatch imaging, where hyperperfusion during ictal phases (using or ) contrasts with interictal hypoperfusion, localizing the epileptogenic zone with accuracy up to 70-90% in . Protocols typically involve 360° orbital acquisition over 20-30 minutes, with attenuation correction essential for accurate quantification and to minimize artifacts from skull attenuation. Hybrid systems can enhance anatomical correlation in these studies, though core perfusion data remains independent of such integrations.

Oncological and other applications

In oncology, single-photon emission computed tomography (SPECT) plays a key role in tumor detection and staging using targeted radiotracers. For breast cancer, technetium-99m (Tc-99m)-sestamibi scintimammography demonstrates high sensitivity, particularly for palpable lesions, with reported values ranging from 85% to 90% when incorporating SPECT imaging to improve lesion localization and reduce false negatives. This tracer accumulates in mitochondria-rich cancer cells, aiding in the differentiation of malignant from benign lesions and assessing axillary lymph node involvement. In neuroendocrine tumors, indium-111 (In-111)-octreotide SPECT exploits somatostatin receptor expression on tumor cells, enabling detection of primary lesions and metastases with sensitivity up to 80-90% in gastroenteropancreatic cases, often enhanced by SPECT/CT for precise anatomical correlation. This approach supports staging and guides peptide receptor radionuclide therapy selection. Beyond oncology, SPECT is instrumental in imaging infections and inflammation, especially in challenging sites like bone. Gallium-67 (Ga-67) citrate scintigraphy identifies osteomyelitis through uptake in inflammatory cells, with SPECT/CT improving specificity by distinguishing infection from degenerative changes, achieving diagnostic accuracies of 85-95% in vertebral cases. Indium-111-labeled white blood cells (WBCs) provide higher specificity for acute infections, as they target activated leukocytes; dual-tracer protocols combining labeled WBCs with Tc-99m-sulfur colloid marrow imaging or Ga-67 subtraction enhance detection of osteomyelitis superimposed on prostheses, reducing equivocal findings by up to 30%. These methods are preferred over planar imaging alone for their three-dimensional resolution in complex anatomies. Bone scintigraphy with Tc-99m-methylene diphosphonate (MDP) is a cornerstone for detecting skeletal metastases, particularly in prostate and breast cancers, by visualizing osteoblastic activity. Whole-body SPECT/CT protocols increase sensitivity to 90-95% for identifying metastatic lesions compared to planar scans, allowing quantification of disease burden and differentiation from benign uptake patterns like fractures. This hybrid approach refines staging and monitors treatment response, with focal hot spots indicating active metastases in up to 70% of high-risk patients. For thyroid evaluation, iodine-123 (I-123) or iodine-131 (I-131) SPECT assesses nodules and quantifies uptake to guide management of hyperthyroidism or cancer. I-123 SPECT/CT provides superior image quality for nodule characterization, with uptake measurements correlating to functional status—hot nodules often show autonomous uptake exceeding 5%, while cold nodules raise suspicion for malignancy. Quantification via region-of-interest analysis on SPECT enables precise dosimetry for radioiodine therapy, improving outcomes in differentiated thyroid cancer by tailoring ablative doses. Other applications include sentinel lymph node biopsy in melanoma, where Tc-99m-labeled colloids with SPECT/CT localize draining nodes preoperatively, boosting detection rates to over 95% and reducing unnecessary dissections by identifying non-axillary drainage patterns. In hepatobiliary assessment, Tc-99m-mebrofenin SPECT evaluates regional liver function by measuring hepatocyte uptake and clearance, with quantitative metrics like uptake rate (e.g., >2.5%/min/m²) predicting post-resection outcomes and identifying at-risk segments in surgical planning. This non-invasive tool complements anatomical imaging for conditions like or tumors.

Advances and Limitations

Recent technological innovations

Recent advancements in detector technology for single-photon emission computed tomography (SPECT) have focused on cadmium-zinc-telluride (CZT) semiconductors, which offer direct conversion detection to minimize signal loss and noise compared to traditional detectors. The Discovery NM/ 670 CZT system, initially introduced in 2016, has undergone refinements in software and calibration protocols as of 2023, enabling higher spatial resolution below 6 mm (FWHM) for isotopes like . Similarly, the StarGuide system, a ring-configured CZT SPECT/ launched in 2021, features 12 pixelated detectors arranged in a 360° configuration, achieving enhanced sensitivity and resolution for whole-body imaging while reducing scan times by up to 50%. These developments have improved quantitative accuracy in clinical settings, particularly for low-dose protocols. Integration of (AI) and (ML) has revolutionized SPECT processing, with algorithms applied for denoising and resolution enhancement. Convolutional neural networks, for instance, have been employed to SPECT from low-count projections, demonstrating up to 20% improvement in (SNR) in 2024 phantom and clinical studies. GE HealthCare's Clarify DL, an AI-based tool cleared for SPECT/ in 2025, uses to enhance while shortening acquisition times by a factor of two without compromising diagnostic accuracy. Additionally, ML models for automated have emerged, analyzing artifacts in to ensure compliance with standards, as validated in 2024 multicenter trials. These techniques prioritize edge preservation and contrast recovery, addressing inherent limitations in SPECT . In theranostics, SPECT plays a pivotal role in monitoring targeted radionuclide therapies, with dual-isotope protocols enabling simultaneous of diagnostic and therapeutic agents. For prostate-specific membrane antigen (PSMA)-targeted therapy, post-treatment SPECT with lutetium-177 (Lu-177) has been refined using dual-isotope approaches to predict tumor response and , as shown in 2023 studies where clearance rates correlated with survival outcomes. The Aurora SPECT/ , granted FDA 510(k) clearance in May 2025, incorporates dual-head CZT detectors and AI-driven workflows to streamline theranostic , supporting quantitative tracking of Lu-177 uptake with reduced burden through faster scans and automated dose calculations. This features a 40 mm detector coverage and 128-slice integration, facilitating precise monitoring of therapy efficacy in applications. Complementing this, super-resolution algorithms based on have advanced, with 2025 reviews highlighting generative adversarial networks that upscale low-resolution SPECT images by fusing multi-view projections, achieving effective resolutions comparable to hybrid systems. The SPECT market reflects these innovations through steady growth and a shift toward theranostics, projected to reach approximately $6 billion globally by 2030, driven by increased adoption in precision oncology. 2024 reports indicate a surge in theranostic applications, with SPECT contributing to over 30% of procedures involving isotopes like Lu-177, supported by enhanced reconstruction for accurate . This expansion underscores SPECT's role in integrating diagnostics and therapy, with clinical uptake rising in and due to regulatory approvals for new agents.

Radiation safety, limitations, and quality control

Single-photon emission computed tomography (SPECT) involves exposure to from administered radiotracers, with typical effective doses ranging from 5 to 15 mSv per scan, depending on the protocol and radiopharmaceutical used, such as for . Radiation safety protocols adhere to the ALARA (As Low As Reasonably Achievable) principle, which emphasizes minimizing patient exposure through optimized imaging parameters, including reduced administered activity and shorter acquisition times where possible. Dose reduction strategies, such as the use of ordered subset expectation maximization (OSEM) algorithms, enable high-quality images at half the conventional dose by improving noise handling and contrast recovery. Despite these measures, SPECT has inherent limitations compared to (PET). Spatial resolution in clinical SPECT systems is typically 10-15 mm, limited primarily by design and scatter, whereas PET achieves 4-6 mm due to electronic collimation via coincidence detection. SPECT is particularly sensitive to patient motion and by body tissues, which can degrade image quality and introduce errors in localization. Additionally, absolute quantification of radiotracer activity concentration is challenging in SPECT because of variable , scatter, and efficiency, often requiring complex corrections that are more straightforward in PET. Common artifacts in SPECT include blurring or distortion from patient motion during acquisition and extracardiac uptake, such as subdiaphragmatic activity from bowel or liver, which can mimic or obscure cardiac defects. Mitigation involves motion correction algorithms, prone positioning for repeat imaging, and attenuation correction using hybrid SPECT/CT systems to normalize for tissue density. Quality control is essential to ensure system reliability and image accuracy. Daily uniformity tests, performed with a flood source, assess integral uniformity across the field of view, with acceptable limits under 4% per NEMA standards to detect detector defects early. Phantom scans using NEMA protocols evaluate spatial resolution, sensitivity, and uniformity, while acceptance testing per IAEA guidelines verifies overall system performance, including energy resolution and linearity, at installation and annually. Regulatory oversight includes FDA guidelines for premarket notifications of SPECT devices, mandating demonstrations of and , including limits and shielding . IEC standards, such as those for electrical , complement these by specifying criteria for gamma cameras to minimize unintended exposure. In contrast to , which often involves higher doses from emitters, SPECT's lower-energy photons allow for relatively reduced patient risk when optimized, though both modalities require vigilant dose monitoring.

References

  1. [1]
    SPECT Imaging - StatPearls - NCBI Bookshelf
    Oct 3, 2022 · Single-photon emission computed tomography (SPECT) is a nuclear imaging modality frequently used in diagnostic medicine.
  2. [2]
    Single Photon Emission Computed Tomography - NCBI - NIH
    The goal of SPECT is to determine accurately the three-dimensional radioactivity distribution resulting from the radiopharmaceutical uptake inside the patient ( ...Introduction · SPECT Instrumentation · SPECT Image Reconstruction
  3. [3]
    Attenuation correction in single-photon emission computed ... - NIH
    It can be said that the attenuation is the biggest problem with SPECT imaging. The aim of the imaging with the gamma camera is to obtain the location and ...
  4. [4]
    Nuclear Medicine Computed Tomography Physics - StatPearls - NCBI Bookshelf
    ### Summary of Historical Development of SPECT
  5. [5]
    Innovation in Cardiac Imaging - Sources of Medical Technology - NCBI
    The wide use of SPECT for brain imaging came about only with the availability of the Tc-based imaging agents. Cardiac imaging with SPECT began to be performed ...Overview Of Cardiac Imaging · The Innovation Process · Thallium Imaging
  6. [6]
    The origins of SPECT and SPECT/CT - PubMed
    Single photon emission computed tomography (SPECT) has a long history of development since its initial demonstration by Kuhl and Edwards in 1963.
  7. [7]
    Technetium-99m - StatPearls - NCBI Bookshelf
    Feb 29, 2024 · Technetium-99m is a widely used radioactive isotope in nuclear medicine, and adverse effects may occur following systemic administration.
  8. [8]
    [PDF] The early years of single photon emission computed tomography ...
    Jun 20, 2006 · The origin of SPECT can be found in pioneering experiments on emission tomography performed approximately 50 years ago. This historical review.
  9. [9]
    SPECT Research | The Science - Amen Clinics
    Since the 1970s, brain SPECT has been used to evaluate strokes, seizures, and brain tumors. In the 1980s, scientists were also using it to study Alzheimer's ...
  10. [10]
    SPECT/CT | Journal of Nuclear Medicine
    This technology translated into the first commercial SPECT/CT system, Hawkeye, which was introduced by GE Healthcare (8). Here, the modalities are combined ...
  11. [11]
    SPECT/CT: an update on technological developments and clinical ...
    ... NaI(Tl) crystals and PMTs are replaced with CZT detectors. Each of the CZT module covers an FOV of 3.96 × 3.96 cm2, and there are 130 CZT modules per camera ...
  12. [12]
    [PDF] Nuclear Medicine: Physics and Imaging Methods (SPECT and PET)
    • Detect regional variations of radioactivity as indication of presence or absence of specific physiologic function. • Detection by “gamma camera” or detector ...
  13. [13]
    [PDF] Guidelines for radioelement mapping using gamma ray ...
    The emission of particles and gamma rays in radioactive decay is proportional to the number of disintegrating atoms, and the standard deviation may be used ...
  14. [14]
    X- AND γ-RADIATION - NCBI - NIH
    The interaction of X- and γ-rays with matter is described by the photoelectric effect, Compton scattering, and pair production. Photoelectric absorption ...
  15. [15]
    Determination of the Attenuation Map in Emission Tomography
    The parameter μ is the linear attenuation coefficient, which represents the probability that the photon will undergo an interaction while passing through a ...<|control11|><|separator|>
  16. [16]
    SPECT detectors: the Anger Camera and beyond - PMC - NIH
    In photoelectric absorption, the gamma-ray photon excites a core electron of one of the atomic constituents of the detector material with the gamma-ray energy ...
  17. [17]
    [PDF] Imaging and detectors for medical physics Lecture 5: Gamma cameras
    Gamma camera energy resolution. • Energy resolution defined as FWHM of photopeak. → the narrower FWHM the better is the gamma camera at discriminating ...
  18. [18]
    Gamma Camera - an overview | ScienceDirect Topics
    The γ rays that pass through the collimator strike a scintillation crystal. This crystal, often made of sodium iodide with trace amounts of thallium, fluoresces ...
  19. [19]
    Nuclear Imaging—The Gamma Camera - Radiology Key
    May 16, 2021 · Modern scintillation cameras have an analog-to-digital converter (ADC) for the signal from the preamp following each PMT (Fig. 18-3). ADCs are ...
  20. [20]
    Review of SPECT collimator selection, optimization, and fabrication ...
    This paper reviews methods for production, sensitivity maximization, and task-based optimization of collimation for both clinical and preclinical imaging ...
  21. [21]
    Collimator - an overview | ScienceDirect Topics
    This hole radius is then used to calculate the geometrical efficiency of the collimator, G, in response to a uniform sheet distribution of activity, given by ...
  22. [22]
    SPECT imaging - Radiology Cafe
    Multiple head gamma camera. Dual head, large field of view camera; Housed on a gantry with slip ring technology that can rotate the cameras around the patient ...
  23. [23]
    A comparative study of NaI(Tl), CeBr 3 , and CZT for use in a real ...
    Jul 4, 2019 · We evaluated the performance of CeBr 3 - and CZT-based detectors and investigated a cost-effective improvement of a regular NaI(Tl)-based camera.
  24. [24]
    USP General Chapter <825> Impact on Nuclear Medicine ...
    Jun 1, 2020 · Before sterile radiopharmaceutical preparation in a hot lab, the nuclear medicine technologist must follow strict aseptic technique ...
  25. [25]
    Quality control on radiochemical purity in Technetium-99m ... - NIH
    The purpose of this study was to offer an example of evaluations of the ISO9001 certified internal quality assurance (QA) system of 99m Tc-radiopharmaceutical ...Missing: SPECT | Show results with:SPECT
  26. [26]
    [PDF] Quality Control of Compounded Radiopharmaceuticals
    Quality control procedures should always be performed following radiopharmaceutical preparation and prior to patient administration to ensure optimal ...Missing: SPECT | Show results with:SPECT
  27. [27]
    Procedure Guideline for Brain Perfusion SPECT Using 99m Tc ...
    Radiopharmaceutical injection: Unstabilized 99mTc-HMPAO: Inject tracer no sooner than 10 min before and no more than 30 min after reconstitution. For seizure ...
  28. [28]
    Bone scintigraphy | Radiology Reference Article - Radiopaedia.org
    Aug 21, 2025 · About 50% of the injected dose will be absorbed by the bones after 2 to 6 hours 2. The study has three phases that follow the intravenous tracer ...
  29. [29]
    Bone Scan - StatPearls - NCBI Bookshelf
    [2] Tc99m phosphonates localize to bone in proportion to osteoblastic activity as seen at sites of bony remodeling and, to a lesser extent, localizes in ...
  30. [30]
    Extraosseous Findings on Bone Scintigraphy Using Fusion SPECT ...
    The normal expected biodistribution of 99mTc-MDP depends on the interval between radiotracer administration and imaging. On late phase imaging obtained several ...
  31. [31]
    Nuclear Medicine Safety - StatPearls - NCBI Bookshelf
    Mar 14, 2024 · Major and minor spills​​ Spills of radiopharmaceuticals are not uncommon, and certain dose thresholds can determine how spills are managed. For ...
  32. [32]
    MIRD Pamphlet No. 21: A Generalized Schema for ...
    The MIRD schema has provided a broad framework for the assessment of absorbed dose to whole organs, tissue subregions, voxelized tissue structures, and ...
  33. [33]
    [PDF] Clinical Applications of SPECT/CT: New Hybrid Nuclear Medicine ...
    These include, in particular, protocols to perform low powered CT with the multi- detector scanners, e.g. when a CT of diagnostic quality is already available ...
  34. [34]
    EANM practice guideline for quantitative SPECT-CT - PMC - NIH
    Dec 5, 2022 · The aim of this document is to provide guidelines for nuclear medicine departments setting up and developing their quantitative SPECT-CT service.
  35. [35]
    [PDF] Safety Reports Series No.71
    This challenge is taken up here by adding paediatric radiology to the areas dealt with in recent IAEA publications. These are specifically Safety Reports.
  36. [36]
    None
    ### Summary of SPECT Data Collection Parameters from SNM Procedure Guideline for General Imaging V6.0
  37. [37]
    SNMMI/ASNC/SCCT Guideline for Cardiac SPECT/CT and PET/CT 1.0
    Aug 1, 2013 · These guidelines are an educational tool designed to assist practitioners in providing appropriate care for patients.
  38. [38]
    [PDF] IAEA Quality Control Atlas for Scintillation Camera Systems
    Numerical data include total acquired counts, average counts, standard deviation of count distribution, uniformity index and NEMA values. NEMA PARAMETERS ...
  39. [39]
    Analytic and Iterative Reconstruction Algorithms in SPECT*
    Coming back to our problem of image reconstruc- tion, a first solution to decrease the blur is to backproject the projection dataset (using the summation ...Missing: foundations | Show results with:foundations
  40. [40]
    The Radon Transformation and Its Application in Tomography
    Aug 6, 2025 · This paper summarizes the indispensable role of the radon transformation and gives a simple proof of the back-projection formula.
  41. [41]
    Filtering in SPECT Image Reconstruction - PMC - NIH
    The aim of this article is to describe the most commonly used filters in SPECT imaging by analytical techniques. These filters are applied in filtered back ...Missing: foundations | Show results with:foundations
  42. [42]
    https://www.researchgate.net/publication/351507860_The_Radon_Transformation_and_Its_Application_in_Tomography
  43. [43]
    Quantitative SPECT Imaging: - A Review and Recommendations by ...
    collimator PSF. The FWHM of the collimator PSF in creases approximately linearly with increasing distance from the collimator surface (i.e., the spatial ...
  44. [44]
    Compton Scatter Compensation Using the Triple-Energy Window ...
    Dec 1, 1993 · Compton Scatter Compensation Using the Triple-Energy Window Method for Single- and Dual-Isotope SPECT. Takashi Ichihara, Koichi Ogawa, ...Missing: original | Show results with:original
  45. [45]
    https://jnm.snmjournals.org/content/jnumed/36/8/1489.full.pdf
  46. [46]
    https://jnm.snmjournals.org/content/34/12/2216
  47. [47]
    Morphology supporting function: attenuation correction for SPECT ...
    Aug 1, 2025 · This review covers the basic physics underlying photon attenuation and scatter and summarizes technical considerations for multimodal imaging.Missing: mathematical | Show results with:mathematical
  48. [48]
    Development of clinical simultaneous SPECT/MRI - PMC
    Issues of SPECT/MRI compatibility are outlined and the clinical appeal of such a system is discussed, especially in the management of brain tumour treatment.
  49. [49]
    INSERT: A Novel Clinical Scanner for Simultaneous SPECT/MRI ...
    The INSERT is the first clinical SPECT prototype for simultaneous SPECT/MRI. Published in: 2017 IEEE Nuclear Science Symposium and Medical Imaging Conference ( ...
  50. [50]
    Simultaneous in vivo imaging with PET and SPECT tracers using a ...
    Sep 9, 2021 · We describe a novel method that provides simultaneous imaging with PET and SPECT nuclides by combining PET imaging and Compton imaging.
  51. [51]
    Hybrid Imaging: Instrumentation and Data Processing - Frontiers
    The main advantages of SPECT/CT include improved attenuation correction and accurate anatomical allocation of the SPECT/CT findings, both resulting in better ...<|control11|><|separator|>
  52. [52]
    [PDF] asnc imaging guidelines
    These patients should be considered for pharmacologic stress testing with myocardial perfusion imaging. Also, for a meaningful test evaluation, exercise should ...
  53. [53]
    Practical Considerations for 1-Day Stress-Only Myocardial Perfusion ...
    Jun 1, 2010 · Their report (1) states that stress imaging should be followed by rest imaging “only in patients with equivocal or clearly abnormal studies.” We ...
  54. [54]
    Overview of stress radionuclide myocardial perfusion imaging
    Mar 20, 2025 · INTRODUCTION. Radionuclide myocardial perfusion imaging (rMPI) enables evaluation of cardiac perfusion and function at rest and during ...
  55. [55]
    Automatic quantification of ejection fraction from gated myocardial ...
    We have developed a completely automatic algorithm to quantitatively measure left ventricular ejection fraction (LVEF) from gated 99mTc-sestamibi myocardial ...
  56. [56]
    Incremental Prognostic Value of Post-Stress Left Ventricular Ejection ...
    Post-stress EF and ESV by gated-SPECT have incremental prognostic values over prescan and perfusion information in predicting cardiac death.
  57. [57]
    Rest-redistribution thallium-201 SPECT to detect myocardial viability
    The aim of this study was to define the optimal criteria for detecting viable myocardium and predicting postrevascularization recovery with rest-redistribution ...
  58. [58]
    Rest-Redistribution Thallium-201 SPECT to Detect Myocardial Viability
    Thallium-201 uptake was defined as normal if the percentage was ^80% (4,6) and as severely reduced if the percentage was <50% (4,6). Significant reversibility ...
  59. [59]
    Comparison of Thallium-201 Resting Redistribution With ...
    Background 201Tl scintigraphy is useful for determination of viability in patients with coronary artery disease and depressed left ventricular function.
  60. [60]
    Quantifying Transient Ischemic Dilation Using Gated SPECT
    Dec 1, 2005 · The summed stress score (SSS) and summed rest score (SRS) were determined semiquantitatively on all patients using a 17-segment, 5-point scale ( ...
  61. [61]
    Transient ischemic dilation ratio of the left ventricle is a significant ...
    Summed stress scores (SSS) were obtained by summing the individual stress scores of the 20 segments. Only patients with MPS interpreted as normal with SSS ...Missing: metrics | Show results with:metrics
  62. [62]
    ACC/AHA/ASNC Guidelines: Cardiac Radionuclide Imaging
    Normal stress perfusion SPECT results are consistently predictive of a less than 1% annual risk of cardiac death or myocardial infarction.
  63. [63]
    Myocardial perfusion imaging in coronary artery disease
    A meta-analysis including 14 studies (840 patients) demonstrated a sensitivity of 0.92 (95% CI, 0.90–0.94) and specificity of 0.85 (95% CI, 0.79–0.90) for the ...<|control11|><|separator|>
  64. [64]
    Comparison of Planar and SPECT Scintimammography ... - PubMed
    Results: A sensitivity of 85% and specificity of 88% of planar scintimammography in diagnosis of primary breast lesions were achieved. The corresponding values ...
  65. [65]
    Single-photon-emission computed tomography (SPECT ... - PubMed
    Single-photon-emission computed tomography (SPECT) with technetium-99m sestamibi in the diagnosis of small breast cancer and axillary lymph node involvement.
  66. [66]
    Somatostatin receptor-based imaging and therapy of ...
    Mar 1, 2010 · Somatostatin receptor imaging (SRI) with [ 111 In-DTPA 0 ]octreotide has proven its role in the diagnosis and staging of gastroenteropancreatic neuroendocrine ...
  67. [67]
    Octreotide Scan - StatPearls - NCBI Bookshelf
    May 4, 2025 · An octreotide scan, also known as somatostatin receptor scintigraphy (SRS), is valuable for detecting carcinoid tumors and various neuroendocrine tumors (NETs).
  68. [68]
    SPECT/CT Using 67Ga and 111In-Labeled Leukocyte Scintigraphy ...
    The present study evaluated the role of SPECT/CT as an adjunct to 67Ga (GS) or 111In-labeled white blood cell (WBC) scintigraphy for diagnosis or localization ...
  69. [69]
    Role of nuclear medicine imaging in evaluation of orthopedic ... - NIH
    Radiolabeled WBC's and Gallium 67 scintigraphy can be helpful in evaluating response to therapy. Positive scintigraphic findings of infection should revert to ...
  70. [70]
    Diagnostic performance of whole-body SPECT/CT in bone ...
    Diagnostic performance of whole-body SPECT/CT in bone metastasis detection using 99mTc-labelled diphosphate: a systematic review and meta-analysis · Highlights.
  71. [71]
    Head-to-head comparison of 99m Tc-PSMA and 99m Tc-MDP ...
    Sep 26, 2022 · 99m Tc-PSMA SPECT/CT was superior to 99m Tc-MDP SPECT/CT in the detection of bone metastases in PCa, especially for small lesions and in patients with low PSA ...
  72. [72]
    Quantitative Iodine-123 single-photon emission computed ...
    Feb 20, 2023 · The percentage of thyroid uptake of the hot nodule found on the left lobe increased to 4.70%, whereas that of the right lobe decreased to 0.04% ...
  73. [73]
    Quantitative Iodine-123 single-photon emission computed ... - PubMed
    Feb 20, 2023 · A quantitative I-123 single-photon emission computed tomography (SPECT)/CT (5 mCi) was performed in one patient with unilateral AFTN and T3 thyrotoxicosis.
  74. [74]
    Effectiveness of SPECT/CT Imaging for Sentinel Node Biopsy ...
    Coregistered SPECT/CT can improve accuracy of sentinel node biopsy (SNB) for staging melanoma. This benefit has implications for pathology services and surgical ...
  75. [75]
    (99m)Tc-mebrofenin hepatobiliary scintigraphy with SPECT for the ...
    The aim of this study was to evaluate the additional value of (99m)Tc-mebrofenin SPECT for the measurement of segmental liver function and liver functional ...
  76. [76]
    Dynamic [99mTc]Tc-mebrofenin SPECT/CT in preoperative planning ...
    Dec 5, 2024 · Dynamic [99mTc]Tc-mebrofenin SPECT/CT is an essential tool for selecting patients at risk of clinically relevant PHLF after liver resection.
  77. [77]
    Discovery NM/CT 670 CZT - GE HealthCare
    With direct conversion detection, Discovery NM/CT 670 CZT has substantially improved system resolution by eliminating the signal loss and noise that comes with ...
  78. [78]
    New Generation SPECT Cameras Based on Cadmium-Zinc ... - NIH
    Oct 31, 2024 · With the success of CZT-based cardiac SPECT systems, a CZT-based camera for general purpose whole-body imaging has been developed. Discovery NM/ ...Missing: 2023 | Show results with:2023
  79. [79]
    First clinical experience of a ring‐configured cadmium zinc telluride ...
    Aug 17, 2023 · The Starguide SPECT-CT system is a 12-detector pixelated CZT camera with the detector arranged in a ring configuration. Each detector is 3.93 cm ...
  80. [80]
    360° CZT-SPECT/CT cameras: 99mTc- and 177Lu-phantom-based ...
    Oct 24, 2024 · In 2016, GEHC introduced the Discovery NM/CT 670, a general-purpose dual head digital SPECT system equipped with CZT flat panels (CZT-SPECT).
  81. [81]
    A review of state-of-the-art resolution improvement techniques ... - NIH
    Jan 30, 2025 · The present review provides an overview of state-of-the-art methods for improving spatial resolution in clinical and pre-clinical SPECT systems.Missing: PSF | Show results with:PSF
  82. [82]
    https://latam.gehealthcare.com/products/molecular-imaging/discovery-nm-ct-670-czt
  83. [83]
    Clinical performance of deep learning-enhanced ultrafast whole ...
    Sep 9, 2024 · The results of the present study validate the efficacy of deep learning methods in enhancing the quality of 2x-speed images, as demonstrated by ...
  84. [84]
    Artificial Intelligence for PET and SPECT Image Enhancement
    Nov 9, 2023 · This review article presents a comprehensive survey of state-of-the-art AI methods for PET and SPECT image enhancement and seeks to identify emerging trends in ...
  85. [85]
    Imaging DNA damage response by γH2AX in vivo predicts treatment ...
    Feb 21, 2023 · Dual isotope SPECT imaging can provide individualized tumor dose-responses that can be used to predict lutetium-177 treatment efficacy.
  86. [86]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC11782768/
  87. [87]
    https://www.gehealthcare.com/-/jssmedia/gehc/us/files/products/imaging/effortless-imaging/white-paper-clarify-dl-nuclear-medicine.pdf?rev=-1
  88. [88]
    A review of state-of-the-art resolution improvement techniques in ...
    Jan 30, 2025 · Single photon emission computed tomography (SPECT), as an advanced nuclear medicine imaging technique, can provide functional and physiological ...
  89. [89]
    SPECT and SPECT-CT Market Growth, Size & Share [2024-2030]
    SPECT and SPECT-CT Market is expected to grow rapidly at a 5.1% CAGR consequently, it will grow from its existing size of from $ 4.3 Billion in 2023 to $ 6.5 ...Competitive Landscape Of The... · Frequently Asked Questions · Key Benefits To StakeholdersMissing: theranostics | Show results with:theranostics
  90. [90]
    [PDF] Progress in SPECT and PET Reconstruction for Theranostics - arXiv
    This strategy relies on accurate image reconstruction of both pre-therapy and post- therapy images for patient selection and monitoring treatment. However, ...
  91. [91]
    https://www.gehealthcare.com/about/newsroom/press-releases/ge-healthcare-announces-fda-510k-clearance-for-aurora-a-new-dual-head-spectct-system-and-clarify-dl-its-ai-powered-deep-learning-image-reconstruction-technology
  92. [92]
    High Radiation Doses From SPECT Myocardial Perfusion Imaging ...
    Dec 18, 2018 · ... effective dose (ED) of ≤9 mSv (equivalent to 3 years of US ... In this case, the dose coefficients they used for Tc-99m sestamibi ...
  93. [93]
    [PDF] Estimating Patient Dose SPECT/PET (& all of NM) - AAPM
    AAPM 2012 Summer School on Medical Imaging using Ionizing Radiation. Effective Dose. Effective Dose is equivalent to the absorbed dose given to the whole body ...<|separator|>
  94. [94]
    An evaluation of half-dose imaging reconstructed with OSEM-3D
    Improved image quality and dose reduction in 99mTc-MDP bone SPECT using 3D ordered-subset expectation-maximization iterative reconstruction (OSEM) with resoluti ...
  95. [95]
    SPECT/CT and PET/CT, related radiopharmaceuticals, and areas of ...
    Typical values of PET resolution are around 5–7 mm while those of SPECT are around 10–14 mm (Lodge et al., 2005).
  96. [96]
    Absolute Quantification in Diagnostic SPECT/CT: The Phantom ...
    Dec 11, 2021 · Validation of the absolute activity concentration requires verification of the measured activity concentration. Except for the bladder ...
  97. [97]
    Artifacts and Pitfalls in Myocardial Perfusion Imaging
    Patient motion is a common source of artifact on MPI studies. A number of motion parameters can influence the likelihood and magnitude of artifact formation.
  98. [98]
    Impact of respiratory motion correction on SPECT myocardial ...
    A combination of motion correction with attenuation correction reduces artifacts in SPECT MPI. AC-SPECT images with and without motion correction should be ...Missing: extracardiac mitigation
  99. [99]
    Subdiaphragmatic activity-related artifacts in myocardial perfusion ...
    Based on our experience, some possible approaches to reducing artifacts include choosing stress testing with an exercise stress test, when possible, late ...Missing: motion | Show results with:motion
  100. [100]
    [PDF] Acceptance Testing and Annual Physics Survey Recommendations ...
    This report provides recommendations for acceptance testing and annual physics surveys for Gamma Camera, SPECT, and SPECT/CT systems.
  101. [101]
    Submission of Premarket Notifications for Emission Computed ... - FDA
    Mar 13, 2018 · Single Photon Emission Computed Tomography (SPECT) devices are intended to detect gamma radiation events and produce tomographic images that ...
  102. [102]
    Medical X-Ray Imaging Devices Conformance with IEC Standards
    Feb 21, 2023 · This guidance describes FDA's policy regarding the regulation of medical x-ray imaging equipment that is subject to the FD&C Act.Missing: SPECT system