Imaging systems do not copy anatomy exactly. The x-ray tube, detector, magnetic field, ultrasound probe and reconstruction algorithms can add structures that aren't there, or show real structures distorted. That is why a radiologist, technologist or physicist looking at an image faces a constant question: "Is this really there?" Not every mark in the image belongs to the patient; some arise directly from the imaging process. These false appearances are called artifacts. Artifacts can lead to false-positive diagnoses, missed real pathology, and unnecessary repeat exposures — so recognizing them is as important as interpreting the image.
What is an artifact?
An artifact is a feature seen in the image that does not correspond to the imaged anatomy — or shows anatomy distorted. Its source is not the patient: it is the tube, detector, magnetic field, ultrasound physics, reconstruction or patient motion. An important distinction: some artifacts are wholly false (e.g. reverberation lines or a mirror image); others distort real anatomy (e.g. partial volume or beam hardening). So an artifact is not always "something that isn't there"; sometimes it is "the wrong version of what is."
Why do artifacts form?
There are three main origins:
- Physics-based: beam hardening, partial volume, chemical shift, reverberation — these arise inevitably from imaging physics; they cannot be wholly removed, only reduced.
- Hardware-based: a dead/drifting detector element (ring artifact), grid error, residual signal (lag), calibration drift.
- Patient-based: motion, metal implants, lack of cooperation.
One artifact can have several origins at once; metal, for instance, is both patient (implant) and physics (excessive attenuation) based, and worsens if the patient moves.1
How does it affect diagnosis?
The risk runs two ways. False positive: mistaking an artifact for a real finding (reading a streak as a bleed). False negative: an artifact hiding a real finding (a metal artifact obscuring an adjacent lesion). The third, often silent cost is the repeat exposure — extra dose and workload. This is exactly where DoseSave's focus intersects: recognizing an artifact is not only a diagnostic skill but also a dose-optimization matter.
Radiography and DR
- Motion blur: if the patient or organ moves during exposure, edges blur and spatial resolution drops. Remedy: short time (high mA) and patient cooperation.
- Grid lines / grid cutoff: if the anti-scatter grid is misaligned or moves out of sync, a fine line pattern or one-sided signal loss is superimposed.
- Ghosting / residual signal (lag) and dead pixels — DR-specific: residual signal from a prior exposure can bleed into the new image as a faint "ghost"; dead/stuck pixels produce fixed-pattern dots.5 These are the artifacts quality control monitors regularly.
- Quantum mottle: low dose → few photons at the detector → a grainy, mottled appearance.4 This is the direct visual consequence of the dose–noise relationship (√N); not an "artifact" in the classic sense but a sign of insufficient signal — yet it degrades image quality just the same. It is the limit of acceptable noise when lowering dose — detail in Dose and Noise (√N).
Computed tomography (CT)
CT has the greatest variety of artifacts; reconstruction, the polychromatic beam and fast scan geometry produce many of them together. The most common:
- Beam hardening: standard backprojection does not fully account for the polychromatic spectrum. In a beam crossing dense tissue (e.g. petrous bone or metal), low-energy photons are absorbed first, so the beam's average energy rises (it hardens).1 The result is cupping (a uniform object darkening toward the center) or dark wedge/webbing bands between two dense structures (e.g. bilateral hip prostheses). Remedy: pre-hardening filtration (e.g. ~10 mm Al) and software correction.
- Streak and metal artifacts: streaking occurs when a region's attenuation exceeds the detector's dynamic range. Classic sources are metallic dental fillings, implants like pacemakers/neurostimulators, and bullet fragments; motion of the high-density object (jaw movement, swallowing) markedly amplifies the streaks.1
- Partial volume effect: if a voxel is large enough to span tissues of different density, the voxel value becomes their average; small structures deviate from their true value. Multi-slice CT (MDCT) with thin sections (e.g. ~1.25 mm) has largely reduced this.1
- View aliasing: if too few projections are acquired to render sharp, high-frequency objects, aliasing appears. Rare clinically since modern scanners collect many views (950–3,000).1
- Cone beam artifacts: undersampling along z at large cone angles; false connections appear between dense structures. Remedy: a more complete data set.1
MRI
- Motion artifacts: breathing, cardiac motion or patient movement produce repeating "ghost" copies along the phase-encoding direction.
- Susceptibility: at metal or tissue–air boundaries the local magnetic field is distorted, causing signal loss and geometric distortion — the voids around dental fillings are the classic example.2
- Chemical shift: because protons in fat and water precess at slightly different frequencies, anatomy is spatially shifted at fat–water boundaries; a dark/bright band appears at the interface.2
- Wraparound (aliasing): anatomy outside the field of view (FOV) but within the slice volume is mapped to the opposite side of the image. Typically seen in the phase-encode direction; reduced by enlarging the FOV or applying an "anti-aliasing" saturation pulse just outside it.2 One of the artifacts technologists meet most often in practice.
Ultrasound
- Reverberation: sound echoes back and forth between two closely spaced strong reflectors (or the probe and a surface); equally spaced, progressively fading false lines appear.3
- Mirror image: near a strong reflector (classic example: the liver–diaphragm interface), multipath reflections place a mirror copy of the real mass beyond the reflector.3
- Acoustic shadowing / posterior enhancement: behind a strongly attenuating structure (stone, calcification, bone) a dark shadow forms; behind a weakly attenuating one (e.g. a cyst), enhancement appears.
- Side / grating lobes: echoes from energy spreading outside the main beam are mismapped onto the main line, creating an artifact.3
Artifact or pathology?
The modalities differ, but the practical clues for telling them apart are shared:
- Check the geometry: artifacts often ignore anatomic boundaries; they run along a physical axis (streaks are radial, reverberation is equally spaced, wraparound sits at the FOV edge).
- Check repeatability: in a different plane/slice, or on a repeat with changed parameters, the artifact disappears or moves; a real finding stays.
- Look for the source: an artifact is usually tied to a known cause (metal, motion, FOV edge, strong reflector).
In short, an image is not reality itself but the result of a physical process — and that process sometimes adds what isn't there and sometimes hides what is. For a definitive call, physicist–radiologist collaboration and, when needed, re-imaging with changed parameters is the safest route. So artifact knowledge is a diagnostic skill for the radiologist, a daily reflex for the technologist, and a check on the system for the physicist.
References
- Bushberg JT, Seibert JA, Leidholdt EM, Boone JM. The Essential Physics of Medical Imaging, 3rd ed. Lippincott Williams & Wilkins, 2011. BT görüntü artefaktları §10.6 (s.367–370): demet sertleşmesi (s.367, Şekil 10-64; kalça implantı Şekil 10-65, s.368), çizgilenme/metal (s.367–368, Şekil 10-66), görünüm örtüşmesi (view aliasing, s.368–369, Şekil 10-67), kısmi hacim (s.368–369, Şekil 10-68), koni-ışın (cone beam, s.369–370, Şekil 10-69). Atıflardaki sayfa numaraları bu baskıya aittir.
- Bushberg JT, et al., a.g.e., Bölüm 13 (MR) — manyetik duyarlılık (susceptibility) artefaktları (s.475, Şekil 13-24, diş dolguları), kimyasal kayma (chemical shift) artefaktları (§13.5, s.480) ve katlanma/örtüşme (wraparound/aliasing) artefaktları (s.485–486, Şekil 13-38).
- Bushberg JT, et al., a.g.e., Bölüm 14 (Ultrasound) — reverberasyon (s.563–564), ayna görüntüsü (mirror image, çok-yollu yansıma, s.567, Şekil 14-52F), akustik gölgelenme/güçlenme ve yan/ızgara lob (side/grating lobe) artefaktları.
- Bushberg JT, et al., a.g.e., kuantum benekliliği (quantum mottle, s.159), kuantum gürültüsü §4 (s.79) ve demet sertleşmesinin fiziksel kökeni §3 (s.51). Doz–gürültü ilişkisi için bkz. Doz ve Gürültü (√N).
- IAEA. Diagnostic Radiology Physics: A Handbook for Teachers and Students (STI/PUB/1564), 2014 — dijital radyografide hayalet/artık sinyal (lag/ghosting), ölü piksel ve tekdüzelik. iaea.org