Contrast-Enhanced Computed Tomography (CECT)

Contrast-enhanced computed tomography (CECT) is X-ray computed tomography (CT) contrast agents are either iodine or barium-based using radiocontrast to investigate the major artery internal structure, blood clot, plug formation, small vessel block in the heart, and brain, ischemia, stroke, nerve structure, nerve damage, bones structure, bone fracture tumor, cancer in a tendentious joint, ligament, muscle cancer, tumor, ulcer in the stomach, ICU critical condition diagnosis especially heart, lung, liver, kidney, and peripheral artery disease. Radiocontrast for X-ray CT is generally iodine-based type scanning.[rx] This is useful to highlight structures such as blood vessels that otherwise would be difficult to delineate from the structure of their surroundings. Using contrast material can also help to obtain functional information about tissues and various organs and mages are taken both with and without radiocontrast. CT images are called precontrast or native-phase images before any radiocontrast has been administrated, and postcontrast after radiocontrast administration.[rx]

Indications

Indications for contrast-enhanced computed tomography (CECT) imaging are developed by the imaging revolution, and some important ones are listed below. These indications include:

  • Evaluating patients with suspected dementia
  • Localizing epileptic foci preoperatively
  • Diagnosing encephalitis
  • Monitoring and assessing vascular spasm following subarachnoid hemorrhage
  • Mapping of brain perfusion during surgical interventions
  • Detecting and evaluating cerebrovascular disease
  • Predicting the prognosis of patients with cerebrovascular accidents
  • Corroborating the clinical impression of brain death
  • Several indications in the field of oncology are listed in this article.
  • Evaluating patients for coronary artery disease.
  • Assessing treatment response and guidance of future therapy in patients with coronary artery disease, cardiomyopathy, and heart failure.
  • Diagnosing coronary artery disease in patients unable to perform a standard exercise stress test.
  • Pre-surgical evaluation of patients with suspected or confirmed coronary artery disease.

Thoraco‐abdominal aorta

  • Diagnosis of congenital and degenerative aortic diseases
  • Assessment of acute aortic injuries and dissections
  • Evaluation of visceral arteries (coeliac, superior mesenteric, and renal arteries)
  • Preoperative planning and follow up
  • Tumor staging and surgical planning

Renal arteries

  • Assessment of anatomy for donor transplants
  • Diagnosis of renal artery stenosis in hypertensives or deteriorating renal function
  • Assessment of renal arteries post‐intervention (renal artery stenting)

Peripheral arterial system

  • Assessment of peripheral vascular disease
  • Assessment of bypass grafts

Carotid/intracranial circulation

  • Characterization of the atherosclerotic disease
  • Assessment of aortic arch vessels
  • Verification of internal carotid artery stenosis
  • Preoperative planning of endovascular and surgical treatment of intracranial aneurysms and vascular malformations

Cardiac imaging

  • Atypical chest pain
  • Patients with intermediate-risk
  • Young patients with a high risk for coronary disease
  • Coronary artery anomalies
  • Non‐invasive follow‐up following percutaneous transluminal angioplasty and stenting
  • Assessment of myocardial scars, aneurysms, tumors, and thrombi
  • Assessment of coronary artery bypass grafts
  • Assessment of the pulmonary veins before and following radiofrequency ablation
  • the diagnostic accuracy of coronary artery disease; the prognostic value of coronary artery disease with regard to the prediction of major cardiac events; detection and quantification of coronary calcium and characterization of coronary plaques
You Might Also Read  Extremity Angiography - Indications, Procedures, Results

Bone and spine

  • Intraspinal or intervertebral foramen cervical dumbbell tumors,
  • tumors beyond the intervertebral foramen
  • Spinous process, supraspinal and interspinous ligament,
  • The contralateral paravertebral muscle thus
  • Investigate stability and flexibility problems of cervical vertebrae and
  • Alleviates cervical stiffness.
  • Reveals the contour of the tumor as well as compression upon the spinal cord, the extent of spinal edema as well as mutual relationships among the tumor, dura mater, and nerve root [,].
  • At the same time, VRT is conducive to analyzing tumors at different levels for intratumoral vascular route and evaluating infliction and erosion extent of vessels thus assessing neurosurgical difficulties and risks.
  • Owing to its high resolution based on the reconstruction thickness at the sub-millimeter level,
  • VRT formulates images from different perspectives for locating vertebral artery, confirming vascular route and compression degree as well as visualizing peripheral vessels around the tumor.
  • Sparing nerve roots: nerve roots above the tumor or enwrapped by the tumor could be dissected and protected, while nerve roots coursing through the tumor should be resected due to their involvement in the tumor original.

Analysis of coronary artery lesions

Systematic analyses of a coronary artery Contrast CT study took into consideration the following steps:

  • (1) Analysis of images reconstructed from different phases of the cardiac cycle, in order to choose those where the coronary arterial tree is best filled with contrast and where movement artifacts are the least.
  • (2) A complete review of axial images that constitute the cardiac volume, paying attention to cardiac anatomy, degree of opacification of chamber and walls of the heart, and aspect of extracardiac structures.
  • (3) Optimization of images aimed to improve the visualization of coronary arteries, by using specific post-processing protocols.
  • (4) Analysis of the coronary artery tree, for which is fundamental the following systematization:
  • □ Examination of the anatomical distribution of coronary arteries aimed to identify normal variants and congenital abnormalities of the origin of vessels.
    □ Detection and localization of coronary artery lesions, carefully avoiding sections and angulations or interposed structures with potential image artifacts.
  • □ Evaluation of composition and morphology of the lesion. In regard to the composition of the plaque, a distinction was made between calcified and non-calcified plaques. Plaques with a mean attenuation of 130 HU or greater were graded as calcified, whereas plaques with a mean attenuation of less than 130 HU were graded as non-calcified. Calcified plaques were identified on nonenhanced scans, and non-calcified plaques were identified on contrast-enhanced scans.
  • □ Qualitative and quantitative assessment of obstruction of the vessel caused by the lesion.

A classification of atherosclerotic coronary artery lesions is possible by applying this systematic analysis. This classification can be made according to the following aspects:

  • The number of vessels involved.

□ The location: proximal, middle, or distal portions of the vessel.

□ The extension of the lesion: focal or diffuse.

□ The degree of obstruction.

a. Non-significant stenosis (less than 60 % of the vessel lumen, including mild and moderate degrees of obstruction).

b. Significant stenosis (equal or more than 60 %, including critical subocclusive and occlusive lesions.

□ The components of the lesion:

a. Non-calcified, mixed, or “soft” lesions.

b. Calcified lesions: The calcium component of the lesion can be focal, diffuse, eccentric or concentric.

Currently, MSCTA has been applied for late-phase image reconstruction in the following ways [] multiplanar reconstruction (MPR), shaded surface display (SSD), bone scintigraphy, maximum intensity projection (MIP), and recently volume rendering technique (VRT) which surpass its predecessors as a supreme technique in reconstructing three-dimensional spatial relationships.

Phases

Depending on the purpose of the investigation, there are standardized protocols for time intervals between intravenous radiocontrast administration and image acquisition, in order to visualize the dynamics of contrast enhancements in different organs and tissues.[rx] The main phases thereof are as follows:[rx]

You Might Also Read  Urine Potassium Test - Indications, Procedures, Results
Phase Time from injection[rx] Time from bolus tracking[rx] Targeted structures and findings[rx]
Non-enhanced CT (NECT)
  • Calcifications
  • Fat in tumors such as in adrenocortical adenomas
  • Fat-stranding is seen in inflammation such as appendicitis, diverticulitis, and omental infarction
Pulmonary arterial phase 6-13 sec[rx]
  • Pulmonary embolism (can use bolus tracking in pulmonary trunk + 6 seconds)[rx]
Pulmonary venous phase 17-24 sec[rx]
Early systemic arterial phase 15-20 sec immediately
  • Arteries, without enhancement of organs and other soft tissues.
Late systemic arterial phase
Sometimes also called the “arterial phase” or “early venous portal phase”
35-40 sec 15-20 sec
  • All structures that get their blood supply from the arteries have optimal enhancement.
  • Some enhancement of the portal vein
Pancreatic phase 30[rx] or 40[rx] – 50[rx] sec 20-30 sec
  • Pancreatic cancers become hypodense compared to the parenchyma.[rx]
Hepatic (most accurate) or late portal phase 70-80 sec 50-60 sec
  • Liver parenchyma enhances through portal vein supply, normally with some enhancement of the hepatic veins.
Nephrogenic phase 100 sec 80 sec
  • All of the renal parenchymas enhances, including the medulla, allowing detection of small renal cell carcinomas
Systemic venous phase 180 sec[ 160 sec
  • Detect venous thrombosis
Delayed phase
Sometimes called the “washout phase” or “equilibrium phase”
6[rx]-15 minutes 6[rx]-15 minutes
  • The disappearance of contrast in all abdominal structures except for tissue with fibrosis, which appears more radiodense.

Adults

The following table shows the preferable volume in normal-weight adults. However, dosages may need to be adjusted or even withheld in patients with risks of iodinated contrast, such as hypersensitivity reactions, contrast-induced nephropathy, effects on thyroid function, or adverse drug interactions.

You Might Also Read  Thoracic Spine X-ray - Indications, Procedure, Results
Sufficient volume for normal-weight adults
Exam Iodine concentration Comments
300 mg/ml 350 mg/ml 370 mg/ml
CT of brain 95ml[rx] 80 ml[rx] 75 ml[rx]
CT of thorax Overall 70 – 95 ml[rx] 60 – 80 ml[rx] 55 – 75 ml[rx] Parenchymal changes in the lung can often be evaluated adequately without the use of intravenous contrast.
CT pulmonary angiogram 20 ml[rx] 17 ml[rx] 15 ml[rx] Minimal amount when using the specific low-contrast protocol.[rx]
CT of abdomen Overall 70 ml[rx] 60 ml[rx] 55 ml[rx]
Liver 55 ml[rx] 45 ml[rx] 40-45 ml[rx] Minimal required amount.[rx]
CT angiography 25 ml[rx] 20 ml[rx] When using the specific low-contrast protocol.[rx]

The dose should be adjusted in those not having normal body weight, and in such cases the adjustment should be proportional to the lean body mass of the person. In obese patients, the Boer formula is the method of choice (at least in those with body mass index (BMI) between 35 and 40):[rx]

For men: Lean body mass = (0.407 × W) + (0.267 × H) − 19.2

For women: Lean body mass = (0.252 × W) + (0.473 × H) − 48.3

Side Effects

Potential adverse effects of contrast medium injection and radiation exposure side effects were explained to all the patients by a radiologist, and written informed consent was obtained before the procedure.

multi-slice computed tomography angiography multi-slice computed tomography angiography multi-slice computed tomography angiography multi-slice computed tomography angiography multi-slice computed tomography angiography

References