1 / 65

Paediatric cardiothoracic CTA

Paediatric cardiothoracic CTA. Indications, Technique And Relevant Anatomy. Gerhard van der Westhuizen Medical officer, Radiology 3 Military hospital 12 October 2012. Introduction. MDCT has revolutionised angiographic evaluation of the heart and thoracic vessels. Faster scan times

delila
Download Presentation

Paediatric cardiothoracic CTA

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Paediatric cardiothoracic CTA Indications, Technique And Relevant Anatomy Gerhard van derWesthuizen Medical officer, Radiology 3 Military hospital 12 October 2012

  2. Introduction • MDCT has revolutionised angiographic evaluation of the heart and thoracic vessels. • Faster scan times • Increased anatomical coverage • High quality reconstructions • Previous scanning issues in children included: • Breath-holding ability (motion artifacts) • Slow scan times causing difficulties in administation of contrast • Small gauge IV catheters • Difficult sites • Manual administration • Short distances between central line and heart.

  3. Comparison of thoracic imaging techniques • Echocadiography • CTA more global assessment of cardiovascular structures (pulmonary arteries, anterior mediastinum, thoracic aorta etc). • CTA also includes airway and lung parenchyma. • Sedation needed with echocardiography, not always needed with CTA. • CTA is quicker, less operator dependent. • Costs the same. • CTA limited functional information, less portable, poorer temporal resolution and RADIATION . • IV access not required with echo.

  4. Comparison of thoracic imaging techniques • MR angiography • Less need for sedation with CTA. • CTA is quicker. • Thermal stability (esp. Neonates – out of incubator). • CTA can be performed immediately post-op, no metal issues. • No radiation with MRI.

  5. Comparison of thoracic imaging techniques • Heart catheterisation • Better physiologic and functional information. • Only intracardiac and intravacular anatomical detail. • Biplane compared to 3D options with CTA. • Radiation dose usually higher with catheterisation. • Sedation needed. • More expensive than CTA. • Technically more difficult.

  6. Dose comparison • Study compared conventional chest CT, CTA, Gated CTA and conventional angiography: (Frush, Yoshizumi; 2006) • Average dose in children: • Conventional chest CT 1.0 to 4.0 mSv • CTA 1.0 to 4.0 mSv • Gated CTA 7.0 to 25 mSv • Conventional angiography 5.0 to 20 mSv

  7. Indications • Detection of disease or pathology • i.e. Diagnosis • Improve clinical decision making • Need for other diagnostic testing • Use of specific intervention • No role in defining normal anatomy • No role in assessing function • Not a screening tool • Specific disease states • Extracardiac great vessel anomalies • Intracardiac shunt lesions • Post-operative anatomy • Most often used for congenital heart lesions • Trauma

  8. CTA technique • Preperation • Ask clinician to list specific questions to adress • ? Vascular anomalies • ? Major airways, lung aeration • ? Mediastinal abnormalities – Collections, infection etc. • ? Status of upper abdomen – situs abnormalities/ abscence of spleen • Less frequent ‘protocol’ scanning than in adults

  9. CTA technique • Example: Scan onset differs for conditions like caval-to-pulmonary artery connection compared to systemic arterial-to-pulmonary artery connection. • Artifacts: Coils, stents, clips, valves, septaloccluders, pacing wires etc. Know about them before the scan!

  10. CTA technique • Preperation • Sedation • Mostly needed for 1-2 year age group • Can be performed by other health care providers • If child is intubated – as quickly as possible during inspiration • Quiet breathing also acceptable

  11. CTA technique • IV access – Type • 20 or 22 gauge peripheral • 24 gauge can also provide adequate information • Long extension tubing – small contrast volume may remain in ‘dead space’ if not flushed. • Contrast volume may be less than 5 ml and 1-2 ml in ‘dead space’ is significant.

  12. CTA technique • IV access – Location • Distance from heart – peripheral line in infant same distance as central line in adults. • Anterior mediastinum – use right arm or lower extremity (less streak artifact from left brachiocephalicvein). • Difference in evaluating IVC inflow for Fontan procedure (use lower limb or delayed scan) to evaluating pulmonary stenosis.

  13. CTA tecnique • Avoid artifacts • Remove leads and wires from chest surface • Careful not to have watches/jewelry in gantry when injecting manually.

  14. CTA technique • IV contrast • Type • Volume • Rate • Route • Method • Onset of scanning

  15. CTA technique • Type • Low or isosmolar • 300mg I/ml concentration • 370mg I/ml if total volume is an issue (rarely) • Volume • MDCT lower dose • 1.5ml/kg • Max of 3 ml/kg • (Cardiac catheterisation uses 5-6ml/kg) • These doses are beneficial if repeat scanning is needed

  16. CTA technique • Rate

  17. CTA technique • Route • Peripheral or central • With central – opacification of pulmonary arteries almost instantaneous. • NB to know where tip of catheter is. • Hardware delays may lead to missing peak opacification with small contrast volumes. • Method • Contrast pump whenever possible • Not with 24-G, positional lines, poor backflow or lines on distal forearm, hands or feet. • Manual • Unpredictable enhancement, average rate of 1.5 ml/sec • Extravation detectors not used due to low amount of contrast used.

  18. CTA technique • Onset of scanning • MDCT has obviated much of the calculation required • Possible to scan too early or too late • Too early – Rapid scanning time • Too late – Small volume of contrast, high cardiac output (shot period of optimal enhancement) • Three techniques: • 1. Empiric delay • 2. Bolus tracking • 3. Test bolus

  19. CTA technique • 1. Empiric delay • Paeds: 10-20 sec • Neonates: 4-10 sec • 2. Bolus tracking • “Smartprep” • Serial enhancement at a preselected level • 10 mA (minimum tube mA) • At level of vessel/structure most critical for evaluation • Mostly at mid-ventricular level • Difference of 5-7 sec between actual enhancement and when scanning begins (software and hardware delays) • Counteract this by: • Monitor interval of 1.0 sec • Inject only after first monitoring image shows

  20. CTA technique • 2. Bolus tracking (cont.) • Steps: • 1. Start bolus tracking display of monitoring images • 2. Start contrast injection after 1st monitoring image appears • 3. Start diagnostic scanning when opacification of desired structures begins or just prior to (more guesswork required) • 4. Stop contrast injection if scanning is complete before entire volume is given

  21. CTA technique • 3. Test bolus • Small volume (0.5 – 1.0ml) given • Time from injection to opacification of desired structure then use with diagnostic scan with full contrast bolus. • Onset of scanning is a critical step in CTA! • With evaluation of pulmonary arteries start scanning when right ventricle starts opacifying. • Start scanning when left ventricle starts opacifying for evaluation of aorta.

  22. CTA technique • Scan parameters: • Scan FOV • Use large FOV if child may move • Number of detector rows • Use highest available - 64 • Detector thickness • Thinnest width – 0.625mm • NB for multiplanar recons and 3D volume rendering • Tube current • According to patient’s size • kVp • Reduced for small children (80kVp under 2 years, 100 kVp up to 6 years) • Scan thickness • Include all structures of interest • Reconstruction algorithms • Volume rendering and MIP projections usually sufficient when necessary

  23. Parameters

  24. Coronary artery CT angiography • For adequate visualisation: Use isotropic in-plane and through-plane spatial resolutions <1mm (Equal voxel dimensions in x, y and z axes) • Submillimeter collimation • Pitch <1 (0.2 to 0.3) • Higher milliamperage and kVp necessary to counter increased noise. • Bolus tracking/ test bolus used. • ECG gating necessary for motionless images. • Usually retrospective ECG gating – use diastole. • Increased exposure! • Online dose modulation programs – high mA only during diastole.

  25. Coronary artery CTA Left Right

  26. Normal anatomy • Thoracic aorta • Pulmonary arteries • Pulmonary veins • Superior vena cava • Azygous system

  27. Thoracic aorta • Five segments: • Aortic root • From base of heart • Includes aortic valve • Annulus • Sinus of Valsalva • Ascending aorta • From aortic root to right innominate artery • Proximal aortic arch • Right innominate artery to left subclavian artery • Distal aortic arch/isthmus • Left subclavian artery to ligamentumarteriosum • Descending aorta • Level of ligamentumarteriosum to hiatus in diaphragm

  28. Thoracic aorta • Normal branching pattern: • Brachiocephalic trunk–R subclavian artery, R CCA • Left CCA • L subclavian artery

  29. Pulmonary arteries • Main pulmonary artery/pulmonary trunk lies within the pericardium • Devides into larger right and smaller left pulmonary arteries • Right passes posterior to AA, SVC, R upper lobe pulmonary vein • Then devides into 2 branches – upper lobe branch and interlobar artery supplies middle and lower lobe • The left is shorter and smaller • Courses anterior to the descending aorta and left main bronchus and divides into upper and lower lobe branches.

  30. Pulmonary arteries

  31. Pulmonary veins • Typically 4 pulmonary veins: • Right and left superior and inferior • R superior – Blood from R upper and middle lobes • R inferior – Blood from R lower lobe • L superior – Blood from L upper lobe + lingula • L inferior – Blood from L lower lobe

  32. Pulmonary veins • Variations: • Conjoined – Sup and inf open into L atrium via common ostium. More common on the left. • Accessory – Extra veins seperate from pulm veins. Occurs more commonly on the right.

  33. Pulmonary veins

  34. SVC and azygous system • SVC formed by L and R brachiocephalic veins • Blood from upper extremities, head and neck. • Drains into R atrium • Azygous vein formed by ascending lumbar and right subcostal veins. • Blood from posterior chest and abdominal walls • Arches over right hilum and drains into posterior part of SVC. • Hemiazygous and accessory hemiazygous veins drain from the left into the azygous vein.

  35. Azygoussystem

  36. Normal anatomy of the heart • Cardiac chambers • Right atrium • Larger posterior atrium proper and smaller anterior atrial appendage. Devided by cristaterminalis. • Receives SVC and IVC. • Left atrium • Forms base of the heart. • Valveless R and L pulmonary veins drain into L atrium • Left auricle forms superior part of left border of heart. Seperated by interatrial septum containing fossaovale

  37. Normal anatomy of the heart

  38. Normal anatomy of the heart • Cardiac chambers • Right ventricle • Forms largest part of anterior surface of the heart • Contains coarse trabeculae and tapers into conusarteriosus which leads to pulmonary trunk. • Contains commonly identified muscle band- Moderator band • Left ventricle • Forms apex of the heart and left border. • Fine trabeculae, walls 3 x thicker than right. • Two prominent papillary muscles Seperated by interventricular septum – membranous and muscular parts.

  39. Normal anatomy of the heart

  40. Normal anatomy of the heart • Cardiac valves • Aortic valve: Right, left and non-coronary cusps • Pulmonary valve: Anterior, right and left cusps • Mitral: Aortic (anterior) and mural (posterior) leaflets • Tricuspid: Septal, anterior and posterior leaflets

  41. Normal anatomy of the heart • Cardiac valves

  42. Normal anatomy of the heart • Coronary arteries • Left coronary artery • From left coronary sinus • Bifurcates into LAD ad left circumflex branches • LAD gives rise to diagonal branches. • Circumflex gives rise to left marginal artery. • Right coronary artery • From right coronary sinus • Branches include: Sinuatrial nodal, AV nodal, right marginal and most commonly posterior IV branch.

  43. Normal anatomy of the heart

  44. Normal anatomy of the heart • Cardiac veins • Great cardiac vein accompanies LAD • Middle cardiac vein accompanies posterior IV branch • Small cardiac vein accompanies right marginal branch of RCA. • All larger branches drains into coronary sinus and into right atrium • Small anterior cardiac veins drain directly into right atrium

  45. Thoracic vascular anomalies • Aortic anomalies: • 0.5 to 3% of population • Five groups: • Left aortic arch • Right aortic arch • Double aortic arch • Cervical arch • Innominate artery

  46. Left arch with abberant right subclavian artery • R subclavian artery is seen on CT as last of major arterires from aortic arch. • Most common anomaly of aortic arch • 0.5 to 2% of population

  47. Right aortic arch with aberrant left subclavian artery (Posterior view)

  48. Double aortic arch • Two arches from single ascending aorta • Gives off own CCA and subclavian arteries • Some patients may have persistent airway obstruction related to tracheomalacia from external airway compression

  49. Double aortic arch

  50. Cervical aortic arch • Rare • High-riding ascending aorta above level of clavicles making a sharp downward turn.

More Related