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Myocardial perfusion imaging

Myocardial perfusion imaging (MPI) is a noninvasive nuclear medicine technique that assesses blood flow to the heart muscle by tracking the distribution of injected radioactive tracers, enabling the detection of perfusion defects indicative of coronary artery disease (CAD). Performed under rest and stress conditions—either through physical exercise or pharmacologic agents—the procedure compares myocardial uptake of tracers like technetium-99m sestamibi or thallium-201 to identify areas of ischemia or infarction. Widely utilized since the 1980s, MPI provides critical diagnostic and prognostic information for patients with suspected or known CAD, a leading cause of morbidity and mortality worldwide. The primary modalities of MPI include (SPECT), which uses gamma cameras to generate three-dimensional images of tracer distribution and has demonstrated a of 86% and specificity of 74% for detecting CAD. (PET), employing tracers such as or ammonia-13, offers higher resolution with a of 92.6%, allowing quantification of absolute myocardial blood flow and coronary flow reserve. Nonnuclear alternatives, such as cardiac magnetic resonance (CMR) imaging with contrast, provide radiation-free perfusion assessment with a of 89% and specificity of 76%, while myocardial contrast echocardiography uses microbubble agents for real-time evaluation. These techniques are typically conducted in a clinical setting, with protocols varying from one-day (stress followed by rest) to two-day imaging to minimize patient . MPI plays a pivotal role in cardiovascular care by aiding risk stratification, guiding revascularization decisions, and evaluating post-intervention outcomes, such as after angioplasty or bypass surgery. Quantitative scoring systems, including the Summed Stress Score derived from 17-segment polar maps in SPECT, help predict adverse cardiac events, with scores below 4 indicating low risk and above 13 signaling high risk. Despite its efficacy, limitations include radiation exposure in nuclear methods and contraindications like severe asthma for pharmacologic stress agents, underscoring the need for tailored patient selection. Advances in hybrid imaging, combining MPI with computed tomography for anatomical correlation, continue to enhance diagnostic accuracy and clinical utility.

Overview

Definition and purpose

Myocardial imaging (MPI) is a non-invasive technique that employs radiotracers to evaluate blood flow to the myocardium, typically assessed under conditions of and to identify regional abnormalities. This method relies on the physiological principle that myocardial mirrors coronary blood flow, which dynamically adjusts to match the heart muscle's oxygen demand during varying workloads. By visualizing tracer distribution, MPI distinguishes between normal and defects caused by ischemia or . The primary purpose of MPI is to detect myocardial ischemia, , and tissue viability, facilitating the differentiation of obstructive from non-obstructive etiologies of cardiac symptoms such as microvascular dysfunction or non-ischemic cardiomyopathies. It plays a crucial role in guiding decisions by identifying reversible perfusion defects that indicate potentially salvageable myocardium amenable to interventions like or . Additionally, MPI supports risk stratification in patients with known or suspected , helping to predict adverse outcomes and inform therapeutic strategies. Key benefits of MPI include its high sensitivity for identifying multivessel coronary disease, where extensive perfusion abnormalities correlate with elevated annual event rates of up to 7% for hard cardiac events in abnormal scans. The technique also enables simultaneous assessment of myocardial function through integrated , providing a comprehensive evaluation of both and contractile performance to enhance diagnostic accuracy. This dual capability improves prognostic value, with normal MPI results conferring a low annual hard event rate of approximately 0.7%, supporting in low-risk patients.

Basic principles

Myocardial is regulated to ensure that coronary blood matches the metabolic demands of the myocardium, primarily through autoregulation, which maintains relatively constant blood over a wide range of pressures, typically between 60 and 120 mmHg. This process involves myogenic responses in vascular , where arterioles constrict or dilate in response to changes in transmural pressure, as well as local metabolic factors such as and that adjust to oxygen consumption. In normal conditions, the myocardium extracts 70-80% of the oxygen delivered by coronary blood at rest, with predominantly occurring during in the left ventricle due to systolic compression. Ischemia arises from a mismatch between oxygen , often due to reduced coronary blood below approximately 8-10 µl/g per beat, leading to functional and metabolic consequences in the affected . Tracer kinetics in myocardial perfusion imaging rely on the principle that radiotracer uptake in the myocardium is proportional to regional blood flow, allowing visualization of distribution. During the first-pass , the tracer is delivered via the bloodstream and extracted by myocardial cells, with extraction fractions varying by tracer type—approaching 100% for freely diffusible agents like oxygen-15 , but lower (around 65-85% at rest) for cationic tracers like or , which decline nonlinearly at higher flows. Following initial uptake, a redistribution may occur in certain tracers, where unbound or slowly cleared portions equilibrate between ischemic and normally perfused regions over time, reflecting differences in flow rather than permanent tissue damage. Stress imaging contrasts with rest imaging to detect flow-limiting coronary stenoses by inducing hyperemia, which simulates the increased myocardial oxygen demand during exercise and amplifies disparities in regional . Pharmacological agents like or dipyridamole cause maximal , increasing coronary blood flow 3-4 times above baseline in normal vessels, while stenotic areas exhibit limited reserve due to autoregulatory failure, resulting in relative defects. This approach unmasks hemodynamically significant stenoses (e.g., >50% luminal narrowing) that may not impair rest flow but restrict hyperemic response, enabling identification of ischemia-prone territories. Detection in myocardial perfusion imaging involves capturing emissions from single-photon emitters or positron annihilations from PET tracers to reconstruct tomographic images of tracer distribution, forming maps that highlight regional flow heterogeneity. In (SPECT), collimated gamma cameras detect photons emitted directly from the tracer decay, while (PET) utilizes paired 511 keV photons from positron-electron , providing higher sensitivity and quantitative accuracy for flow assessment. These maps depict the myocardium in transaxial, sagittal, or polar formats, where normal appears uniform and defects indicate potential ischemia.

Radiopharmaceuticals

Thallium-201

Thallium-201 (^{201}Tl) is a monovalent cation radiotracer that serves as a analog, facilitating its transport across cell membranes via the sodium- pump in myocardial cells. Produced by bombardment of thallium-203, it has a physical of approximately 73 hours and decays by , emitting primarily low-energy mercury X-rays at 69-83 keV (along with minor gamma emissions at 135 keV and 167 keV), which are suitable for SPECT imaging but contribute to challenges in photon detection. In myocardial perfusion imaging, ^{201}Tl demonstrates high first-pass extraction by viable myocytes, with an extraction fraction of about 88% at rest, reflecting both blood flow and cellular integrity. Following intravenous administration, uptake occurs rapidly within 5-15 minutes, proportional to regional . A key feature is its redistribution property, where the tracer slowly washes out from normal myocardium but persists longer in ischemic or infarcted regions, allowing delayed imaging at 3-4 hours post-injection to assess myocardial viability without a separate rest injection. This redistribution enables differentiation between reversible ischemia and fixed defects, enhancing the tracer's utility in viability studies. The typical administered dose for stress-redistribution protocols is 3-4 (111-148 MBq) intravenously at peak stress, with imaging commencing 10-15 minutes post-injection for stress views and 3-4 hours later for redistribution views. Advantages of ^{201}Tl include the ability to perform rest-stress studies with a single injection, simplifying logistics and reducing the need for multiple doses, while its redistribution phenomenon provides valuable insights into tissue viability. However, ^{201}Tl has notable limitations, including a higher effective dose of 20-30 mSv for a standard stress-redistribution protocol, primarily due to its long and the need for higher administered activities to compensate for low abundance. Imaging quality is suboptimal compared to higher-energy tracers, as the low-energy are more susceptible to scatter and soft-tissue in the chest, potentially degrading and increasing artifacts. These factors have led to decreased usage in favor of agents, though ^{201}Tl remains relevant for specific viability assessments.

Technetium-99m-based agents

(Tc-99m)-based agents are widely used radiotracers in (SPECT) myocardial perfusion imaging due to their favorable physical properties and clinical utility. The primary agents include Tc-99m sestamibi, a lipophilic cationic complex formed by technetium binding to six methoxyisobutylisonitrile ligands, and Tc-99m tetrofosmin, a cationic diphosphine complex with two ethoxyethyl groups. These tracers accumulate in viable myocardial cells proportional to , enabling detection of defects. Tc-99m has a physical half-life of 6 hours and emits gamma rays at 140 keV, which allows for high-quality with standard gamma cameras while minimizing tissue and scatter. Both agents exhibit high first-pass myocardial fractions of 60-80% under normal flow conditions, with sestamibi at approximately 65% and tetrofosmin at 54%. Unlike thallium-201, they show minimal redistribution after uptake, resulting in stable myocardial retention that permits delayed without significant changes in defect appearance. This fixed uptake reflects at the time of injection rather than ongoing redistribution. The advantages of Tc-99m-based agents include superior image quality compared to thallium-201, attributed to the higher and lower scatter, which enhances resolution in SPECT studies. They deliver a lower effective dose of 10-12 mSv for a typical rest-stress protocol, with sestamibi at 11.3 mSv and tetrofosmin at 9.3 mSv. Separate rest and stress injections are feasible, often in a same-day format, improving logistical efficiency. Additionally, their prolonged myocardial retention supports gated SPECT acquisition for simultaneous assessment of left ventricular function, such as . Limitations include the lack of redistribution, which precludes their use for viability assessment in a single injection; separate tracers like FDG are required for that purpose in . Sestamibi, in particular, has higher hepatobiliary uptake and slower hepatic clearance, which can interfere with early imaging of the inferior wall. Tetrofosmin offers faster liver clearance, mitigating this issue somewhat. Typical dosing ranges from 10-30 (370-1110 MBq) per injection, with lower doses (10-15 ) for and higher (25-30 ) for to optimize count statistics against background activity. Imaging is performed 30-60 minutes post-injection to allow clearance from non-target tissues.

Positron emission tomography tracers

Positron emission tomography (PET) tracers for myocardial perfusion imaging are positron-emitting radiopharmaceuticals that enable high-resolution assessment of myocardial blood flow through coincidence detection of photons. These tracers allow for absolute quantification of in units of mL/min/g, providing superior diagnostic accuracy compared to relative methods. Key tracers include , , and oxygen-15 water, each with distinct methods, , and clinical utility. Rubidium-82 (^{82}Rb) is a potassium analog produced via a strontium-82/rubidium-82 generator, eliminating the need for an on-site and facilitating routine clinical use. It has a short physical of 1.25 minutes and an extraction fraction of approximately 65% into myocardial cells, which decreases with increasing blood flow, potentially underestimating hyperemic flow. Typical dosing is 50 mCi (1850 MBq) at rest and , with rapid uptake and washout enabling sequential rest-stress imaging in under 90 minutes. ^{82}Rb's positron range of 8.6 mm contributes to slightly reduced image resolution compared to other PET tracers, but overall PET spatial resolution remains 4-6 mm, superior to SPECT. Nitrogen-13 ammonia (^{13}N-NH_3) is a cyclotron-produced tracer with a of 9.96 minutes and a myocardial fraction of about 80%. It is fixed in the myocardium via synthesis, providing high-quality images with a range of 2.53 mm for excellent . Dosing is typically 20 mCi (740 MBq) per injection, and its longer compared to ^{82}Rb allows for more flexible imaging protocols, including feasibility with exercise . Validation studies confirm its accuracy for quantitative myocardial blood flow (MBF) and coronary flow reserve (CFR) measurements. Oxygen-15 water (^{15}O-H_2O) serves as the reference standard for MBF quantification due to its 100% fraction and diffusible nature, freely crossing the myocardial without flow-dependent limitations. With a of 2.06 minutes, it requires an on-site for production and dosing of 24-30 mCi (900-1100 MBq). However, its poor myocardial-to-background contrast necessitates advanced image processing for visualization, limiting its routine clinical adoption despite ideal for absolute assessment in mL/min/g. A more recent addition is flurpiridaz F-18 (^{18}F-flurpiridaz), approved by the FDA in October 2024 as the first new perfusion tracer in nearly three decades. Produced via using , it has a physical of 110 minutes, enabling centralized production and distribution to remote sites without on-site cyclotrons. It exhibits a high first-pass myocardial extraction fraction of approximately 94%, largely independent of flow rates, with a short range of 0.64 mm for superior . Typical dosing is 4-10 mCi (148-370 MBq) per injection, supporting both pharmacologic and exercise stress protocols due to its longer . As of 2025, ^{18}F-flurpiridaz offers enhanced diagnostic accuracy for detection, with improved defect contrast and quantification of MBF and CFR, potentially increasing access to MPI. These tracers enable PET's advantages, including attenuation correction for accurate quantification and reduced artifacts in obese patients, but share limitations such as short half-lives (except for generator-based ^{82}Rb and ^{18}F-flurpiridaz) leading to high operational costs and the need for specialized facilities. correction is essential to mitigate soft-tissue effects, and while ^{82}Rb avoids dependency, the others incur higher expenses due to production requirements.

Imaging Modalities

Single-photon emission computed tomography

(SPECT) is the most widely used imaging modality for myocardial perfusion imaging (MPI), providing three-dimensional assessment of myocardial flow through the detection of gamma rays emitted by radiotracers. In this technique, a equipped with collimators rotates around the patient to acquire projections from multiple angles, enabling of perfusion distribution. The system typically employs a sodium iodide crystal detector or advanced cadmium-zinc-telluride (CZT) detectors to convert gamma photons into electrical signals, with parallel-hole collimators directing photons to form images while rejecting scattered . Acquisition involves rotating the camera over a 180° to 360° arc around the patient's chest, capturing 60 to 128 projections per study to facilitate filtered back-projection or algorithms for 3D images. in SPECT MPI ranges from 10 to 15 mm, influenced by design and detector type, while is enhanced in modern CZT systems to allow shorter scan times and lower radiation doses. However, attenuation artifacts commonly arise from diaphragmatic or breast tissue, which can mimic defects, and motion artifacts may degrade quality if patient movement occurs during acquisition. Standard protocols for SPECT MPI include rest-stress imaging sequences, often using technetium-99m-based agents for one-day studies or thallium-201 for redistribution imaging, with electrocardiogram (ECG) gating to assess left ventricular and wall motion alongside perfusion. These protocols emphasize weight-based dosing and supine or prone positioning to minimize artifacts, following guidelines that prioritize diagnostic accuracy and radiation safety. SPECT MPI offers advantages such as widespread availability in clinical settings, cost-effectiveness relative to other modalities, and the ability to integrate perfusion data with functional parameters like ventricular volumes. Its established role in detecting stems from decades of validation in large-scale studies. Limitations include its semi-quantitative nature, which relies on relative uptake patterns rather than absolute flow measurements, and susceptibility to and motion issues that require correction techniques like SPECT/CT hybrid systems. Additionally, is lower than that of , potentially limiting detection of small perfusion defects.

Positron emission tomography

Positron emission tomography (PET) plays a pivotal role in myocardial perfusion imaging (MPI) by providing high-resolution, quantitative assessment of myocardial blood (MBF), enabling the evaluation of both epicardial and microvascular dysfunction. Unlike relative perfusion methods, PET measures absolute MBF in ml/min/g, offering superior diagnostic accuracy for detecting ischemia, particularly in complex cases. This quantitative capability stems from dynamic imaging protocols that capture tracer , allowing calculation of myocardial flow reserve (MFR) as the ratio of to MBF. The technical principles of PET in MPI rely on a ring of detectors, typically using scintillation crystals such as lutetium oxyorthosilicate (LSO) or bismuth germanate (BGO), that surround the patient to detect pairs of 511 keV gamma photons emitted during positron-electron annihilation. When a positron-emitting radiotracer decays, the positron travels a short distance (on the order of millimeters) before annihilating with an electron, producing two photons emitted approximately 180 degrees apart; these are detected in coincidence to localize the annihilation event. Image reconstruction employs iterative algorithms, such as ordered subset expectation maximization (OSEM), often combined with filtered back-projection, to generate tomographic images from the projection data. Attenuation correction is integral, typically achieved using integrated low-dose computed tomography (CT) in hybrid PET/CT systems, which maps tissue density to correct for photon absorption and improves image accuracy without significant additional radiation exposure. PET achieves a spatial resolution of 4-6 mm full width at half maximum (FWHM), which is substantially better than single-photon emission computed tomography (SPECT) and allows for clearer delineation of defects. This resolution, combined with high , enables precise quantification of absolute MBF through dynamic acquisition of tracer uptake and washout curves, analyzed via kinetic models such as the single-tissue compartment model for tracers like or ammonia. These models account for tracer delivery, extraction, and retention, yielding MBF values typically ranging from 0.6-1.3 ml/min/g at rest and higher under stress, with normal MFR exceeding 2.0. Standard protocols for PET MPI involve a rest-stress sequence, often performed in a single session using hybrid scanners. Dynamic imaging begins with tracer injection, capturing serial frames (e.g., 14 × 5-second frames initially) to model first-pass and retention for MBF calculation, followed by static images for relative . Stress is induced pharmacologically with agents like or , and MFR is computed to evaluate coronary vasodilator capacity. The CT component facilitates attenuation correction and, if needed, coronary calcium scoring or integration, completing the study in approximately 30-60 minutes. Key advantages of PET over other modalities include its ability to detect balanced ischemia in multivessel disease, where relative uptake appears uniform but absolute MBF is reduced globally. It also excels in assessing microvascular disease by identifying impaired MFR without obstructive epicardial stenoses, providing prognostic insights in patients with or . Modern PET systems deliver lower effective radiation doses, often under 5 mSv for a complete study, compared to SPECT protocols exceeding 10 mSv. Despite these benefits, PET MPI faces limitations, including restricted availability due to the need for on-site cyclotrons or generators for short-lived tracers, resulting in fewer centers offering the service compared to SPECT. Additionally, the higher upfront and operational costs of scanners and hybrid systems make it less accessible, though its diagnostic precision can justify use in high-risk populations.

Hybrid imaging techniques

Hybrid imaging techniques integrate with (SPECT) or (PET) to combine functional myocardial data with anatomical information, enhancing the accuracy of myocardial perfusion imaging (MPI). These systems, such as SPECT/CT and , utilize low-dose CT scans primarily for attenuation correction, which compensates for photon absorption by tissues like the chest wall or , thereby minimizing false-positive defects. Additionally, the CT component allows for coronary calcium (CAC) scoring, which quantifies calcified plaques as a marker of , providing complementary risk assessment without requiring separate imaging sessions. In SPECT/CT systems, the low-dose CT facilitates attenuation correction that reduces artifacts, improving image quality and diagnostic confidence, particularly in challenging cases involving breast or diaphragmatic attenuation. This hybrid approach also enables CAC scoring from the same CT acquisition, which has been shown to enhance the detection of obstructive (CAD) by identifying subclinical in patients with normal results. For PET/CT, the CT not only provides precise attenuation correction but also supports image fusion with (CTA), allowing simultaneous evaluation of defects and coronary anatomy in a single session. This integration improves specificity by differentiating true ischemic defects from attenuation artifacts, with studies demonstrating superior diagnostic performance compared to non-corrected . Emerging applications include for automated analysis of hybrid images to predict outcomes, as well as advanced detectors enabling faster scans and better quantification as of 2025. The primary advantages of these hybrid techniques include increased specificity for CAD detection—often by clarifying equivocal findings—and the convenience of one-stop that streamlines workflow and reduces burden. For instance, incorporating CAC scoring into MPI s has been associated with improved prognostic , where patients with zero CAC scores exhibit very low rates of significant ischemia or adverse events (e.g., 0.25-0.5% requiring ). However, limitations persist, such as the added radiation dose from (typically 1-5 mSv, depending on ), higher equipment costs, and operational complexity requiring specialized training to avoid issues like SPECT-CT misregistration. Clinically, hybrid imaging is particularly valuable for resolving equivocal SPECT results, where fusion can confirm or rule out true defects, and for pre-revascularization planning by combining and anatomical data to guide interventions. Guidelines recommend their use in upgraded labs to optimize patient-centered protocols, though adoption may be limited by reimbursement challenges in some settings. Overall, these techniques represent a significant advancement in MPI by bridging functional and structural assessments for more precise CAD management.

Procedure

Patient preparation and protocols

Patient screening is essential prior to myocardial perfusion imaging (MPI) to identify contraindications and ensure safety. General absolute contraindications to stress testing include recent acute myocardial infarction within 48 hours and unstable angina. For vasodilator pharmacological stress agents, absolute contraindications include bronchospastic lung disease with active wheezing, second- or third-degree atrioventricular (AV) block without a pacemaker, and systolic blood pressure below 90 mmHg; relative contraindications include severe aortic stenosis, profound bradycardia, and severe hypertension exceeding 200/110 mmHg. For dobutamine stress, absolute contraindications additionally include severe aortic stenosis and high-degree AV block without a pacemaker. Patients should also be screened for pregnancy, as MPI involves ionizing radiation that poses risks to the fetus, and lactation, requiring temporary interruption of breastfeeding. Informed consent must be obtained, detailing the procedure's purpose, potential adverse effects such as radiation exposure, and rare allergic reactions to radiopharmaceuticals or stress agents. Preparation instructions aim to optimize image quality and minimize risks. Patients are typically required to fast for at least 3 hours before the procedure, though a light may be permitted for afternoon appointments, with only intake allowed thereafter. Caffeine-containing substances, including , , , and certain medications, must be withheld for at least 12 hours to avoid interference with vasodilator stress agents. Beta-blockers, , and nitrates should be discontinued 24-48 hours in advance if feasible and per referring guidance, to prevent blunting of the stress response. For insulin-dependent diabetics, morning scheduling is preferred, with adjustments to insulin dosing coordinated with the healthcare team. Patients are advised to wear comfortable clothing and avoid jewelry or metal objects that could interfere with . Post-tracer injection, is encouraged by drinking plenty of fluids to facilitate excretion of the . Standardized protocols for MPI include one-day and two-day approaches, selected based on patient factors, facility resources, and tracer half-life. The one-day protocol typically involves a low-dose rest study followed by a high-dose stress study later the same day, using technetium-99m agents with a 3:1 dose ratio (e.g., 8-12 mCi rest and 24-36 mCi stress) to minimize patient inconvenience while allowing sufficient decay between acquisitions. In contrast, the two-day protocol separates rest and stress imaging on consecutive days, often with equal doses (e.g., 18-30 mCi each for larger patients), which reduces overlap and improves count statistics but requires two visits. Prone imaging may be incorporated as an adjunct to supine views to reduce artifacts from diaphragmatic attenuation, particularly in women or patients with breast tissue overlap. For patients unable to exercise, pharmacological stress options such as , , or dipyridamole are employed to induce myocardial hyperemia, with these methods briefly referenced here as they integrate into the overall protocol. These protocols are tailored to the imaging modality, with (SPECT) commonly using the above schemes and (PET) favoring one-day formats due to shorter-lived tracers.

Stress induction methods

Stress induction in myocardial perfusion imaging (MPI) simulates physiological conditions to unmask coronary perfusion defects by increasing myocardial oxygen or enhancing blood flow heterogeneity. Two primary approaches are employed: exercise-based stress, which directly elevates and workload, and pharmacological stress, which uses agents to induce or inotropic effects. The choice between these methods depends on patient factors, with exercise preferred when feasible for its additional prognostic insights from functional capacity assessment. Exercise stress typically involves treadmill walking using the or bicycle ergometry, with incremental increases in speed, incline, or resistance to achieve at least 85% of the age-predicted maximum (calculated as 220 minus age). Continuous electrocardiographic (ECG) monitoring, measurements every 1-3 minutes, and symptom assessment guide the test, which is symptom-limited and terminated upon reaching target , exhaustion, or adverse signs such as severe or significant ST-segment depression. This method provides valuable prognostic data, including exercise duration and metabolic equivalents (METs), which correlate with cardiovascular risk beyond perfusion findings alone. Exercise is contraindicated in patients with , recent , severe , or mobility limitations, occurring in approximately 30-50% of referrals for MPI. Pharmacological stress is indicated for patients unable to achieve adequate exercise, such as those with orthopedic issues, , or , comprising about 30-40% of MPI studies. Vasodilators like (infused at 140 μg/kg/min for 4-6 minutes), (400 μg bolus), or dipyridamole (0.56 mg/kg over 4 minutes) selectively dilate coronary resistance vessels, increasing myocardial blood flow 3- to 4-fold in normal arteries while stenotic regions show relative hypoperfusion. These agents act via stimulation, with peak effects occurring within 2-3 minutes, and are often combined with low-level exercise to mitigate side effects and improve image quality. , an inotropic agent (escalated from 5-40 μg/kg/min), serves as an alternative for patients with contraindications to vasodilators, such as severe , by raising and contractility to mimic exercise without primary vasodilation. Contraindications include second- or third-degree atrioventricular block, systolic below 90 mmHg, or recent intake, which antagonizes effects. Safety protocols are standardized across methods, with continuous ECG, , and symptom monitoring to detect ischemia, arrhythmias, or . Serious adverse events are (less than 1 per 1,000 tests for exercise and 1 per 10,000 for pharmacological), but include or prolonged with dipyridamole. Reversal agents such as (for vasodilators) or beta-blockers (for ) are immediately available, and patients are observed for 30-60 minutes post-stress. Overall, both approaches demonstrate comparable diagnostic accuracy for detection, though exercise yields superior prognostic stratification in capable patients.

Image acquisition and processing

Image acquisition in myocardial perfusion imaging typically occurs after the administration of radiotracers during rest and phases, with protocols tailored to the imaging modality. For (SPECT), acquisition durations range from 15 to 20 minutes per phase using conventional gamma cameras, while cadmium-zinc-telluride (CZT) systems can reduce this to 2 to 14 minutes, often standardized at 10 to 15 minutes with lower radiotracer activity. Patients are positioned as standard, though two-position imaging—combining supine with prone or upright—is recommended for acquisitions to mitigate artifacts, particularly in the absence of correction techniques. Electrocardiogram (ECG) gating is mandatory when feasible to enable assessment of left ventricular function, utilizing 8 to 16 frames per R-R interval with a 20% beat-length acceptance window to ensure reliable measurements. In (PET), acquisitions are shorter, often 3 to 6 minutes per static phase for tracers like , with dynamic imaging extending to 10 minutes or more for blood flow quantification; positioning with arms extended is standard to optimize field-of-view coverage. Processing begins with raw projection data reconstruction to generate tomographic images. In SPECT, iterative reconstruction methods, such as ordered subset expectation maximization (OSEM), are preferred over filtered back-projection due to superior noise handling and resolution recovery, incorporating depth-dependent resolution modeling to enhance image quality. correction is essential and routinely applied using low-dose computed (CT) scans (delivering <20 mGy·cm dose-length product) or radionuclide transmission scans, performed in shallow breathing over 10 to 30 seconds for CT or 3 to 5 minutes for sources, to normalize photon and reduce artifacts. For PET, similar (e.g., OSEM with 2 iterations and 21 subsets) is standard, with CT-based correction mandatory to account for 511 keV photons, ensuring accurate quantification. Quality control measures are integral to both modalities to ensure diagnostic reliability. In SPECT, cine review of raw projections assesses for patient motion or breathing artifacts, with count statistics targeting >1,000,000 counts per left ventricle; motion correction software, leveraging list-mode data on CZT systems, applies realignment when displacement exceeds . Low-pass filtering, such as Butterworth with a 0.4 to 0.45 Nyquist cutoff, reduces noise while preserving . PET processing includes daily NEMA NU 2-2012 compliance testing for and , with software realignment for misregistration between and data. Final outputs are standardized for clinical review, facilitating perfusion pattern evaluation. Reconstructed datasets yield short-axis slices from to , complemented by long-axis views, reformatted at 6 to 8 mm intervals. Polar (bullseye) maps are generated by reorienting the left ventricle into a , displaying relative tracer uptake in a 17-segment model for quantitative comparison against normal databases. These displays are analogous in , with polar maps essential for myocardial blood flow assessment.

Clinical Applications

Detection and assessment of coronary artery disease

Myocardial perfusion imaging (MPI) plays a central role in the noninvasive diagnosis of (CAD) by assessing myocardial blood flow under and rest conditions, enabling the identification of perfusion defects indicative of obstructive stenoses. For detecting hemodynamically significant CAD, typically defined as ≥50% luminal stenosis on invasive , SPECT-based MPI demonstrates a pooled of 88% (95% CI: 86-90%) and specificity of 76% (95% CI: 72-79%), based on a of 108 studies involving 11,212 patients. PET-based MPI shows higher performance, with pooled of 93% (95% CI: 88-96%) and specificity of 81% (95% CI: 67-90%) across 4 studies involving 650 patients in the same . These metrics highlight MPI's utility as a gatekeeper test to identify patients warranting further invasive evaluation. A key strength of MPI lies in its ability to differentiate reversible perfusion defects, which represent inducible ischemia due to demand-supply mismatch in stenotic vessels, from fixed defects signifying or scar tissue with persistent hypoperfusion. Reversible defects normalize or improve on rest imaging compared to stress, correlating with viable myocardium at risk, whereas fixed defects persist across both phases and indicate nonviable tissue. This distinction guides therapeutic decisions, such as for ischemia versus medical optimization for infarct-related changes. MPI also facilitates localization of CAD by mapping perfusion defects to specific coronary arterial territories: anterior and septal defects typically implicate the left anterior descending () artery, lateral defects suggest the left circumflex () artery, and inferior defects point to the (). Standardized 17-segment models align myocardial regions with these vascular distributions, allowing for targeted assessment of multivessel disease patterns. This aids in predicting the hemodynamic impact of individual stenoses. In the context of CAD assessment, the extent of ischemia on MPI provides prognostic insights, with moderate to severe ischemia involving >10% of the left ventricular myocardium associated with elevated risk of major adverse cardiac events, including and cardiac death. For instance, patients with ≥10% ischemic myocardium exhibit significantly higher 1-year rates compared to those with lesser involvement. This threshold helps stratify urgency within initial CAD evaluation. Large randomized trials underscore MPI's value in guiding CAD management. The COURAGE trial demonstrated that PCI added to optimal medical therapy reduced ischemia on serial MPI compared to medical therapy alone in stable CAD patients, though overall outcomes were similar. Similarly, the ISCHEMIA trial enrolled patients with moderate-to-severe ischemia on MPI (among other tests) and showed that an initial invasive strategy did not reduce events compared to , affirming MPI's role in identifying ischemia warranting optimized therapy. These findings support MPI as a tool for evidence-based CAD detection and localization.

Risk stratification and prognosis

Myocardial perfusion imaging (MPI) plays a crucial role in risk stratification by quantifying the extent and severity of ischemia, enabling clinicians to categorize patients into low, , or high risk for major adverse cardiac events (MACE) such as cardiac death or . The total perfusion defect size, often expressed as the percentage of ischemic myocardium or through the summed difference score (), serves as a primary metric; for instance, an SDS greater than 13 or ischemia involving more than 10% of the left ventricle identifies high-risk patients with an annual hard event rate exceeding 3%. Transient ischemic dilation (TID), calculated as the ratio of to left ventricular volumes, further refines prognostication; a TID ratio greater than 1.22 is indicative of multivessel and independently predicts adverse outcomes, even in scans with otherwise perfusion. Risk categories derived from MPI are well-established: patients with normal exhibit low risk, with an annualized rate below 1%, while those with moderate defects (e.g., 5-10% ischemia) fall into intermediate risk (1-3% annual events), and extensive ischemia or TID elevates patients to high risk (>3% annual events). These categories are enhanced by integrating MPI findings with left ventricular (LVEF); for example, an LVEF below 40% combined with abnormal doubles the event rate compared to isolated defects. Meta-analyses of over 20,000 patients confirm that such combined assessments provide incremental prognostic value, outperforming clinical risk scores alone. Prognostic insights from MPI directly guide therapeutic decisions, particularly . In patients with ischemia exceeding 10% of the myocardium, early —such as or coronary artery bypass grafting—has been shown to improve survival compared to medical therapy alone, based on large cohort studies and randomized trial subgroups. This threshold is supported by (PET) MPI data, where even 5-10% ischemia identifies a survival benefit from intervention. Furthermore, meta-analyses demonstrate MPI's superiority over stress for , with hazard ratios for up to 2.5 times higher accuracy in risk prediction due to MPI's ability to detect silent ischemia and quantify extent.

Special populations and alternative uses

Myocardial perfusion imaging (MPI) requires specific adjustments in women due to breast tissue attenuation, which can create false-positive inferior or anterior wall defects mimicking ischemia. Techniques such as prone positioning during acquisition significantly reduce these artifacts and improve interpretive accuracy in affected cases. Attenuation correction software or transmission scanning further enhances specificity in this population. In patients with diabetes, MPI is particularly valuable for detecting microvascular dysfunction, where epicardial coronary artery disease may be absent but small-vessel impairment leads to reduced coronary flow reserve. Studies show that diabetic individuals exhibit higher rates of abnormal perfusion despite revascularization, with event rates up to 8.6% compared to 4.5% in non-diabetics, emphasizing the need for quantitative flow assessments. Post-revascularization, MPI assesses graft patency by evaluating stress-induced perfusion in bypassed territories, with patent grafts typically showing normalized flow distribution. However, accuracy can be limited in obesity due to increased soft-tissue attenuation, necessitating higher radiotracer doses or advanced correction methods to mitigate suboptimal image quality. Alternative applications of MPI extend beyond routine evaluation. Combined with 18F-fluorodeoxyglucose (FDG) , it identifies viable but hibernating myocardium in ischemic , where mismatched perfusion-metabolism patterns predict functional recovery after , with viability present in up to 40% of dysfunctional segments. In , MPI differentiates ischemic from non-ischemic etiologies by quantifying perfusion defects and viability, guiding therapy in patients with reduced . For cardiac transplant surveillance, quantitative MPI measures myocardial flow reserve to detect allograft vasculopathy or rejection, with reduced reserve (<2.0) indicating early graft dysfunction. Patients with left bundle branch block face challenges from septal perfusion artifacts, best addressed by vasodilator stress protocols rather than exercise to maintain diagnostic reliability. Emerging uses include assessment of microvascular angina, where PET-based coronary flow reserve quantification (<2.0) confirms diagnosis in patients with non-obstructive coronaries and persistent symptoms. Additionally, serial MPI monitors chemotherapy-induced cardiotoxicity, detecting subclinical perfusion abnormalities from anthracyclines or HER2-targeted agents before overt left ventricular dysfunction develops.

Interpretation and Analysis

Qualitative assessment

Qualitative assessment of (MPI) relies on expert visual interpretation of perfusion patterns to identify and characterize myocardial defects, distinguishing between normal myocardium and areas affected by ischemia or infarction. In normal studies, the left ventricular (LV) myocardium exhibits homogeneous and symmetric radiotracer uptake across all walls during both rest and stress phases, with no regional variations in intensity. Reversible defects, indicative of ischemia, appear as regions of reduced or absent uptake primarily during stress imaging that partially or fully normalize at rest, reflecting inducible perfusion abnormalities due to . Fixed defects, suggesting scar tissue from prior infarction, show persistent hypoperfusion in the same regions at both stress and rest, without improvement. To standardize evaluation, interpreters use the American Society of Nuclear Cardiology (ASNC) 17-segment model, which divides the LV into 16 myocardial segments (basal, mid, and apical levels across six walls) plus the apex, allowing precise localization of defects relative to coronary artery territories. Each segment is scored on a 0-4 scale for perfusion severity: 0 for normal uptake, 1 for mildly reduced, 2 for moderately reduced, 3 for severely reduced, and 4 for absent uptake, with adjustments for potential attenuation but no negative scores permitted. These scores enable assessment of defect extent (number of affected segments) and severity (average score), facilitating communication of findings and correlation with clinical outcomes. Gated SPECT review complements perfusion analysis by evaluating regional wall motion and thickening, which aids in confirming ischemia. Abnormal wall motion or reduced systolic thickening in segments with reversible perfusion defects during stress supports an ischemic etiology, while preserved motion in fixed defects may indicate attenuation artifacts rather than true scar. Interpretation requires trained nuclear cardiologists or radiologists, with consensus reading by multiple experts recommended for equivocal cases to enhance reproducibility and accuracy, as interobserver variability can affect diagnostic confidence.

Quantitative methods

Quantitative methods in myocardial perfusion imaging (MPI) involve software-based numerical analysis to provide objective evaluation of myocardial perfusion, complementing qualitative visual assessments by offering reproducible metrics for defect extent, severity, and flow dynamics. These techniques typically begin with the generation of polar maps, also known as bull's-eye plots, which represent the left ventricular myocardium in a standardized two-dimensional format by discretizing three-dimensional uptake data into polar coordinates. This allows for pixel-by-pixel comparison of patient data against gender-, age-, and protocol-specific normal databases derived from low-risk individuals without coronary artery disease. A core aspect of quantification is the assessment of relative percentage uptake, where patient myocardial counts are normalized to the maximum uptake within the left ventricle and compared to the normal database mean, often using standard deviations (SD) below the mean to define abnormality. For instance, regions exhibiting uptake less than 60% of maximum are frequently classified as severely abnormal, indicating significant hypoperfusion, while milder defects may fall between 60% and 80% of maximum. Total perfusion deficit (TPD), calculated as the percentage of the myocardium below a predefined threshold (typically 2.5 SD below normal), quantifies the overall extent and severity of defects in both stress and rest images; a TPD greater than 5% is generally considered abnormal. Additionally, myocardial flow reserve (MFR), defined as the ratio of stress to rest myocardial blood flow (MFR = \frac{\text{stress flow}}{\text{rest flow}}), provides a functional measure of coronary vasoreactivity, with values below 2.0 indicating impaired reserve and suggestive of ischemia, particularly in cases of microvascular dysfunction or multivessel disease. These methods offer key advantages, including high reproducibility due to automated algorithms that minimize inter-observer variability, often achieving variability below 10% for TPD measurements, and enhanced detection of subtle or balanced perfusion defects that may be overlooked visually, such as global reductions without focal disparities. Recent advances as of 2025 incorporate artificial intelligence, such as deep learning models, to automate perfusion scoring and further improve diagnostic accuracy and reproducibility in quantitative MPI analysis. Uptake heterogeneity metrics, such as regional variance or entropy derived from polar map pixel distributions, further quantify non-uniform perfusion patterns, aiding in the identification of diffuse ischemia or microvascular abnormalities. Commercially available software like the Cedars-Sinai Quantitative Perfusion SPECT (QPS) and Quantitative Gated SPECT (QGS) packages automate these analyses, generating normalized polar maps, TPD values, and heterogeneity indices for clinical interpretation. PET-based MPI enhances these quantifications with absolute flow measurements in ml/min/g, improving accuracy for MFR assessment.

Artifacts and limitations

Myocardial perfusion imaging (MPI) is susceptible to various artifacts that can mimic or obscure true perfusion defects, potentially leading to misinterpretation. Attenuation artifacts, caused by soft-tissue absorption of gamma rays, are among the most common, particularly from breast tissue in women affecting the anterior wall or diaphragm impacting the inferior wall. These can result in apparent fixed or reversible defects that do not reflect actual ischemia. Motion artifacts arise from patient movement during acquisition, causing misalignment between projections and blurring of myocardial contours, which may simulate perfusion abnormalities especially in stress images. Gastrointestinal uptake of radiotracers, such as technetium-99m agents, occurs in 10–50% of cases due to hepatobiliary excretion and splanchnic blood flow, leading to intense activity in the liver, stomach, or bowel that overlaps with the inferior myocardial wall and creates false-positive defects. Several limitations further constrain the diagnostic utility of MPI. False-positive results are more frequent in low-risk populations due to these artifacts and balanced ischemia, reducing specificity. The technique cannot directly visualize coronary anatomy, relying instead on functional assessment of perfusion, which limits its role in anatomical evaluation. Accuracy is reduced in single-vessel disease, where subtle defects may be missed, particularly in the left circumflex territory. MPI is operator-dependent, with variations in protocol execution and interpretation affecting reproducibility. Additionally, it is not suitable for acute myocardial infarction, as ongoing infarction alters tracer uptake patterns unpredictably. Mitigation strategies include prone positioning to shift breast tissue away from the heart and reduce diaphragmatic overlap, improving image quality in up to 70% of affected cases. Attenuation correction using computed tomography (CT) in hybrid SPECT/CT systems accurately compensates for soft-tissue effects, enhancing specificity by 10–20%. Patient selection, such as avoiding recent meals or using vasodilator stress judiciously, minimizes gastrointestinal interference, while late imaging (45–60 minutes post-injection) and oral fluid intake further reduce bowel activity. Hybrid techniques, like SPECT/CT, provide integrated correction for multiple artifacts.

Safety and Radiation Considerations

Radiation dosimetry

Myocardial perfusion imaging (MPI) procedures involve ionizing radiation from radiopharmaceutical tracers, with effective doses varying by modality and protocol. For single-photon emission computed tomography (SPECT) using technetium-99m (Tc-99m) agents such as sestamibi or tetrofosmin, typical effective doses range from 9 to 12 mSv for a standard rest-stress protocol, reflecting administered activities of approximately 740-1110 MBq for stress and half that for rest in one-day imaging. Thallium-201 (Tl-201) SPECT protocols yield higher effective doses of 17 to 41 mSv, due to the tracer's longer half-life and higher administered activities around 111-148 MBq for stress-redistribution studies. In contrast, positron emission tomography (PET) with rubidium-82 (Rb-82) offers lower exposure, with effective doses of 1 to 5 mSv for rest-stress protocols using 925-1850 MBq per phase in three-dimensional acquisition modes. Several factors influence these dose estimates, including tracer type, imaging protocol, and patient-specific variables. One-day protocols generally deliver lower cumulative doses than two-day approaches by minimizing overlap in tracer decay, while patient weight affects dosimetry through activity adjustments—higher weights may require scaled-up injections to maintain image quality, potentially increasing exposure by 10-20%. Hybrid systems incorporating for attenuation correction add a minor external dose of 0.3-1.3 mSv from low-dose CT scans. Effective doses are calculated using International Commission on Radiological Protection (ICRP) models, which weight organ-absorbed doses by tissue-specific radiation sensitivity factors to estimate stochastic risk equivalents. In MPI, organs like the breast and gonads receive elevated absorbed doses—up to 20-30 mGy for breast tissue in Tc-99m protocols—due to proximity to the heart and tracer biodistribution, though these contribute variably to the overall effective dose based on biokinetic data. Recent trends emphasize dose reduction through optimized protocols, such as stress-only imaging with ultra-low Tc-99m activities (370-555 MBq), achieving effective doses below 5 mSv without compromising diagnostic accuracy. Emerging F-18 perfusion tracers, such as approved in 2024, enable rest-stress protocols with effective doses under 9 mSv, facilitating wider PET adoption due to centralized production.

Risk assessment and mitigation

The primary health risks associated with (MPI) stem from ionizing radiation exposure, predominantly stochastic effects such as cancer induction, with an estimated lifetime attributable risk of approximately 1 in 1000 to 1 in 2000 for typical MPI procedures delivering 10-20 mSv effective dose. Deterministic effects, such as skin erythema or cataracts, are rare at diagnostic doses used in MPI, as these thresholds (typically >2 Gy) are not approached in standard protocols. Risk assessment in MPI relies on models like the Biological Effects of (BEIR) VII report, which projects excess cancer mortality based on linear no-threshold assumptions, estimating about 5.5% increased fatal cancer risk per of exposure across populations. This risk is amplified in younger patients due to longer post-exposure and in females owing to higher for certain cancers, potentially doubling the attributable risk compared to older males. Mitigation follows the ALARA (as low as reasonably achievable) principle, emphasizing dose optimization through selection of lower-radiation tracers, such as agents (effective dose ~10-15 mSv) over thallium-201 (~40 mSv) or preferring (PET) tracers like (~2-5 mSv) when clinically appropriate. Additional strategies include shielding with lead aprons during , stress-only imaging protocols to halve doses in normal studies, and advanced camera technologies like cadmium-zinc-telluride detectors that enable 30-50% dose reductions without compromising image quality; MPI is contraindicated in unless benefits outweigh risks, with alternatives like recommended. Professional guidelines from the American Society of Nuclear Cardiology (ASNC) and (ACC) advocate for appropriate use criteria to ensure MPI is justified only when diagnostic benefits exceed radiation risks, targeting average lab doses below 9 mSv in at least half of studies and avoiding unnecessary repeat or combined imaging.

Comparisons with other imaging modalities

Myocardial perfusion imaging (MPI) offers advantages over stress echocardiography in detecting multivessel and subendocardial ischemia due to its direct assessment of myocardial blood flow, whereas stress echocardiography relies on wall motion abnormalities, which may miss subtler perfusion defects. Stress echocardiography, however, avoids and is more operator-dependent but widely available, making it preferable in patients with contraindications to or in settings requiring rapid, bedside evaluation. Both modalities provide strong prognostic value, with normal results indicating low annual event rates, though MPI demonstrates higher (87%-89%) for (CAD) detection compared to echocardiography's specificity advantage. Compared to cardiac magnetic resonance (CMR) imaging, MPI is more readily available for routine assessment in intermediate-risk patients, particularly in facilities without advanced MRI capabilities, while CMR excels in evaluating myocardial viability, , and non-ischemic conditions like due to its superior and lack of . CMR provides high (up to 95%) for viability assessment, outperforming MPI in detailed tissue characterization, but its use is limited by contraindications such as implanted devices and higher costs. Both techniques effectively risk-stratify patients with suspected CAD, though CMR is often reserved for complex or inconclusive cases. In contrast to coronary computed tomography angiography (CTA), which excels at visualizing coronary , plaque composition, and severity with high negative predictive value for ruling out obstructive CAD, MPI focuses on the functional significance of lesions, particularly those with 25%-75% where ischemia may or may not be present. CTA involves lower doses (3-5 mSv) than traditional SPECT MPI (9-12 mSv) but provides limited , making it ideal for low-to-intermediate pretest probability patients without known CAD. MPI is preferred when functional assessment is needed to guide decisions in known or suspected CAD. MPI is typically selected for patients with intermediate pretest probability of CAD, especially when ischemia detection and risk stratification are prioritized over anatomical detail, while hybrid imaging systems combining MPI with CTA or CMR bridge gaps by integrating functional and structural information for more comprehensive evaluation. Choice among modalities depends on local expertise, patient factors (e.g., renal function, ), and clinical scenario, with guidelines recommending stress like MPI for intermediate-to-high risk stable .

Historical Development

Early use of thallium-201

The development of thallium-201 (^{201}Tl) as a radiotracer for myocardial perfusion imaging began in 1973, when researchers at , including E. Lebowitz, M.W. Greene, R. Fairchild, P.R. Bradley-Moore, H.L. Atkins, A. Ansari, P. Richards, and K. Belgrave, successfully produced it via bombardment of natural targets with protons, yielding ^{201}Pb as a precursor that decayed to ^{201}Tl with a 73-hour suitable for imaging. This was selected for its chemical similarity to , enabling uptake in myocardial cells via the Na^+/K^+-ATPase pump in proportion to regional blood flow, as demonstrated in early biodistribution studies in animals showing rapid myocardial concentration and clearance from blood. The first human applications of ^{201}Tl for planar myocardial imaging occurred in 1974, with initial clinical studies reported in 1975 by H.W. Strauss and colleagues, who injected the tracer intravenously at rest in patients undergoing coronary arteriography and used a scintillation camera to visualize perfusion defects corresponding to angiographically confirmed stenoses, establishing its utility for detecting . Early protocols focused on rest-redistribution imaging, where serial scans after a single injection revealed persistent defects in infarcted tissue versus partial refill in ischemic areas, allowing noninvasive differentiation of irreversible damage from viable but underperfused myocardium. By 1976, exercise stress testing was integrated into ^{201}Tl protocols to enhance detection of inducible ischemia, as shown in initial studies where tracer injection during peak treadmill exercise followed by immediate and delayed imaging improved sensitivity for compared to rest alone, with defects resolving on redistribution scans in non-infarcted regions. A seminal 1977 study by G.M. Pohost et al. further validated this approach in both experimental canine models of transient and human exercise testing, demonstrating that redistribution of ^{201}Tl into initially defective areas within 2-4 hours indicated reversible ischemia and myocardial viability, rather than fixed , thus laying the foundation for viability assessment in nuclear cardiology. During the 1980s, foundational limitations of ^{201} imaging were increasingly identified, particularly from soft tissues like the and , which caused false-positive inferior and anterior defects, especially in women, reducing specificity for coronary stenoses as highlighted in segmental analysis studies comparing images to . These challenges, combined with the isotope's low-energy emissions (69-80 keV mercury x-rays and 167 keV gamma), limited and count statistics in planar and early SPECT formats, prompting refinements in collimation and patient positioning. The pioneering use of ^{201}Tl from the mid-1970s onward established myocardial perfusion imaging as a cornerstone of nuclear cardiology, enabling noninvasive evaluation of and influencing the evolution of stress testing protocols, with over 10 million procedures annually by the late worldwide. Its built on advances in production techniques, which advanced synthesis for clinical diagnostics.

Introduction of technetium-99m isotopes

The introduction of (Tc-99m) isotopes represented a pivotal transition in myocardial perfusion imaging (MPI) during the , building on foundational research from the that identified lipophilic cationic complexes suitable for labeling with Tc-99m to assess myocardial blood flow. The pioneering agent, Tc-99m sestamibi (also known as Cardiolite), was approved by the U.S. (FDA) in December 1990 for rest and stress MPI in evaluating , marking the first widely available Tc-99m-based perfusion tracer. This approval followed preclinical and early clinical investigations demonstrating its uptake proportional to regional myocardial perfusion. Subsequently, Tc-99m tetrofosmin (Myoview) received FDA approval on February 9, 1996, providing an alternative with comparable biodistribution but potentially faster hepatic clearance for improved imaging windows. Tc-99m agents offered substantial advantages over thallium-201 (Tl-201), the prior standard, primarily through convenient on-site production from molybdenum-99/Tc-99m generators, which enhanced availability and eliminated the need for off-site synthesis required for Tl-201. The 140 keV gamma emission of Tc-99m yielded superior spatial resolution and higher count rates in (SPECT) imaging compared to Tl-201's suboptimal 69-80 keV photons, reducing scatter and improving defect contrast. These properties enabled one-day rest-stress protocols, where low-dose rest imaging (10-15 mCi) could precede high-dose stress imaging (25-30 mCi) on the same day, minimizing patient inconvenience and overlap. Overall, Tc-99m studies delivered effective doses of approximately 9-12 mSv, often lower than Tl-201 equivalents (around 15-20 mSv), due to optimized and the isotope's 6-hour physical . Clinical milestones in the solidified Tc-99m's role through trials demonstrating its diagnostic equivalence or superiority to Tl-201. Multicenter studies, such as those published in the early , reported for detection ranging from 85-92% with Tc-99m sestamibi, comparable to Tl-201 but with enhanced image quality and fewer attenuation artifacts. For example, head-to-head comparisons in patients undergoing validated Tc-99m agents' accuracy in identifying reversible ischemia, often with fewer false positives due to better myocardial-to-background ratios. A key advancement was the introduction of quantitative gated SPECT (QGS) software by Germano et al., which leveraged Tc-99m's stable myocardial retention to enable simultaneous perfusion and left ventricular function assessment, improving prognostic evaluation of wall motion and . By 2000, Tc-99m isotopes had achieved widespread adoption, comprising over 80% of MPI procedures in major markets like the , driven by their logistical and dosimetric benefits. This shift not only streamlined workflows but also contributed to reduced cumulative in routine practice, as higher-quality images allowed for lower administered activities in optimized protocols.

Evolution to PET and hybrid systems

The emergence of (PET) in myocardial perfusion imaging (MPI) marked a significant advancement beyond traditional single-photon emission computed tomography (SPECT) techniques, offering superior and the ability to quantify absolute myocardial blood flow. (Rb-82), a generator-produced positron-emitting tracer, saw initial clinical use in the for assessing myocardial , building on preclinical studies from the and that demonstrated its uptake in cardiac tissue. However, widespread adoption occurred post-2000, facilitated by the availability of dedicated PET scanners and improved generator technology, which enabled routine clinical application in and for detecting (CAD). Similarly, (N-13) emerged as another key PET tracer, with pivotal clinical trials in 2005 validating its use for dynamic quantitative assessment of regional myocardial in patients with suspected CAD, showing comparable accuracy to established kinetic models. Hybrid imaging systems integrated PET or SPECT with computed tomography (CT), enhancing attenuation correction and anatomical correlation to improve diagnostic accuracy in MPI. In the 2000s, SPECT/CT hybrids like the Siemens Symbia TruePoint system, introduced around 2006, combined variable-slice CT with SPECT cameras, allowing precise localization of perfusion defects and reducing artifacts from soft-tissue attenuation. PET/CT hybrids followed suit, with clinical implementation accelerating after 2005; for instance, Rb-82 PET/CT studies demonstrated high sensitivity (93%) and specificity (81%) for CAD detection, including in challenging populations like obese patients, by fusing functional perfusion data with coronary anatomy. These systems addressed key limitations of standalone PET, such as photon attenuation in the chest, enabling more reliable flow quantification at rest and stress. Key advances in the and further solidified PET's role in quantitative MPI. Professional guidelines, such as the 2013 SNMMI/ASNC/SCCT recommendations and the 2020 EANM procedural guidelines, endorsed quantitative PET for measuring myocardial blood flow and reserve, providing objective metrics beyond visual interpretation to detect multivessel disease and balanced ischemia. In the , artificial intelligence (AI) integration revolutionized image processing, with models enhancing perfusion defect detection in PET/SPECT MPI, improving diagnostic accuracy by up to 20% through automated motion correction and artifact reduction. Radiation dose reductions were also achieved, with modern PET protocols using Rb-82 or N-13 delivering effective doses below 5 mSv for complete rest-stress studies, thanks to shorter acquisition times and optimized tracers. In September 2024, the U.S. FDA approved 18F-flurpiridaz (Flyrcado), a novel fluorine-18-labeled PET tracer with a longer , facilitating centralized production and distribution while offering high extraction fraction and improved quantification of myocardial blood flow for CAD diagnosis. These developments have profoundly impacted clinical outcomes, with PET MPI achieving specificities of 95% for obstructive CAD detection, surpassing SPECT in prognostic value. Notably, evidence has expanded 's utility to microvascular dysfunction, where quantitative flow reserve assessment identifies ischemia without epicardial stenoses, as outlined in the 2023 ASNC consensus and 2020 appropriate use criteria, filling prior gaps in non-obstructive CAD evaluation.

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