Modalities · Animated

How Do Modalities See? Each Device's Difference — Animated

Radiography, CT, ultrasound and MRI 'see' the same patient in completely different ways — because each rests on a different physical phenomenon. We take seven modalities one by one: each working principle with an animated visual and citations.

"Imaging" is not one thing. Each modality rests on a different physical language: some read the attenuation of X-rays, some the echo of sound, some the magnetic behavior of nuclei. Below we take seven modalities one by one, each working principle shown with an animation.

Radiography — a single shadow

The most basic method: the X-ray beam crosses the patient in one pass and forms a single 2D projection (shadow) on a flat detector. Fast and cheap, ideal for bone and lung — but depth information is limited; all structures overlap.

tubedetectorSingle projection (2D shadow)
The beam passes from one direction; the result is a shadow cast onto one plane. All depth overlaps.

CT — a slice from hundreds of angles

CT breaks past the limit of radiography: the tube and detector rotate around the patient (rotate–rotate geometry) and collect projections from hundreds of angles; a computer reconstructs a cross-section from this data.1 In modern systems the gantry rotates several times per second.1

tube + detector rotate →reconstructioncross-sectionHundreds of angles → a slice
The tube–detector pair rotates around the patient; the projection at each angle is combined to reconstruct a slice (tomography).

Fluoroscopy — a real-time movie

Where radiography takes a single frame, fluoroscopy produces a moving image with continuous or pulsed X-rays — for dynamic procedures like advancing a catheter or watching a swallow.5 The cost is long exposure time and the dose that accumulates with it.

tube (pulsed)catheter (moving)live imageContinuous / pulsed — moving
The pulsed beam produces many frames per second to show motion; a lower pulse rate lowers the dose.

Mammography — low energy, finest detail

To catch the breast's low-contrast, very small structures (microcalcifications), mammography uses low-energy X-rays and compression; it has the highest spatial resolution in radiology.5 Compression both improves detail and lowers dose.

low-kVp tubemicrocalcificationsdetectorCompression + low energy
The compression paddle thins the breast; the low-energy beam brings out soft-tissue contrast and the finest detail.

Ultrasound — the echo of sound

Ultrasound uses no ionizing radiation. The probe sends a short sound pulse into tissue; the pulse travels at ~1540 m/s in soft tissue and part of it returns as an echo from every interface where the acoustic impedance changes.2 The round-trip time of the echo gives depth, its amplitude gives brightness (pulse–echo).2

probetissue interface (impedance change)↓ pulse    ↑ echoPulse–echo · non-ionizing
The probe emits a pulse; the time of the returning echo gives depth, and its strength sets the brightness in the image.

MRI — nuclei spinning in a magnetic field

MRI also uses no ionizing radiation. In a strong magnetic field, hydrogen nuclei (protons) in the body precess like a spinning top; the precession frequency is proportional to the field strength (the Larmor relation) — about 64 MHz at 1.5 T.3 A radiofrequency (RF) pulse "tips" these protons; the signal they emit as they relax forms the image. This is why MRI's soft-tissue contrast is superb.

B₀precessionRF pulsetip → signalPrecession · Larmor · RF
Protons precess in the B₀ field; an RF pulse tips them, and the signal they emit while relaxing becomes the image.

Nuclear medicine / PET — radiation emitted from within

Where the others place the source outside, in nuclear medicine the source is inside the patient: the administered radiopharmaceutical shows function/metabolism, not anatomy. In PET the tracer emits a positron; when it annihilates with an electron, two 511 keV photons are born about 180° apart.4 A ring-shaped detector catches the two photons simultaneously (in coincidence) to locate the source.4

radiopharmaceutical511 keV ←→ 511 keV (≈180°)coincidenceSource within · functional imaging
Positron–electron annihilation sends two 511 keV photons in opposite directions; the ring detector catches them in coincidence to locate the source.
Related articles
For the numeric comparison table: Modalities and Their Differences. For step-by-step formation of an X-ray image: How Is an X-ray Image Formed?

References

  1. Bushberg JT, Seibert JA, Leidholdt EM, Boone JM. The Essential Physics of Medical Imaging, 3rd ed. Lippincott Williams & Wilkins, 2011. Bölüm 10 (Computed Tomography) — tüp ve dedektörün hasta etrafında dönmesi (rotate–rotate geometri), gantry rotasyonu.
  2. Bushberg JT, et al., a.g.e., Bölüm 14 (Ultrasound) — pulse–echo görüntüleme, yumuşak dokuda ses hızı 1540 m/s, akustik empedans farkları.
  3. Bushberg JT, et al., a.g.e., Bölüm 12 (Magnetic Resonance Basics) — protonun manyetik alanda presesyonu, Larmor bağıntısı; 1,5 T'de proton rezonans frekansı ~64 MHz.
  4. Bushberg JT, et al., a.g.e., Bölüm 15 ve 19 (Radyoaktivite ve PET) — pozitron–elektron anihilasyonu sonucu yaklaşık 180° zıt yönde yayılan iki 511 keV foton; koinsidans algılama.
  5. Bushberg JT, et al., a.g.e., Bölüm 8 (Mammography) ve Bölüm 9 (Fluoroscopy) — düşük enerjili X-ışını ve kompresyon; gerçek zamanlı/pulslu floroskopi.
Note: This content is for education; for clinical decisions or regulatory compliance, consult a qualified medical physicist and current regulations.

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