エピソード

  • Deep Dive: Nuclear Medicine
    2022/08/02
    • Basic concept: using radioactive (element that remits radiation as it decays) substances coupled with biologically active chemicals to visualize structures (some organs love certain substances- like thyroid and iodine)



    • Important physics concepts to know:
      • Isotope = element on the periodic table with different # of neutrons but same atomic # 
        • Radioisotopes: technetium-99m, iodine-131



    • How nuclear medicine actually works: patient is made radioactive, they emit gamma rays, a gamma camera has a detector made of crystal that scintillates in response, computer creates an image, multiple types of scans that utilize this principles



    • Types of scans:
      • Positron emission tomography (PET) = uses radioisotope that produces positively charged electrons (positrons) that are attached to pharmaceuticals (glucose analog fluorodeoxyglucose [FDG] for example) to image based on metabolic activity 
      • Single photon emission computed tomography (SPECT) = uses gamma camera to take 2D pictures circling around the patient to create a 3D projection



    • Bone scans:
      • Screening for metastatic disease, diagnosing early fractures 
      • Tracer = Technetium-99m (Tc99m) methylene diphosphonate (MDP)
      • Deposits best where there is bone turnover
      • Metastases, superscan, triple-phase



    • Ventilation/perfusion (V/Q) scans:
      • Used to diagnose pulmonary embolism when patients cannot undergo CT angiography 
      • Tracer = Tc99m macroaggregated albumin (MAA)
      • Pulmonary embolism = segmental mismatch with normal ventilation but abnormal perfusion scans; probability can be categorized into normal, low, intermediate, high



    • Cardiac scans:
      • Heart cells with decreased perfusion or viability will take up less tracer
      • Usually perform a resting and stress (adenosine, treadmill) scan
      • Decreased uptake on stress that corrects on rest suggests ischemia rather than infarct (reversible vs irreversible)



    • GI bleed scans:
      • Couple Tech-99m to RBCs and scan abdomen
      • Bleeds show up as increased uptake of radiotracer in bowel lumen that increases in amount and moves through the bowel over time



    • Thyroid scintigraphy:
      • Used to assess nodules, Grave’s disease, cancer
      • Hyperyhyroid patients will show increased uptake if there is truly an increased amount of thyroid hormone being actively produced 
      • Performed using radioactive iodine or T99m pertechnetate which both go to the thyroid 
      • 95% of hot nodules are benign, cold nodules are more concerning for malignancy



    • Biliary scans:
      • Hepatobiliary iminodiacetic acid (HIDA) scan = couples Tc99m to iminodiacetic acid to assess the hepatobiliary system
      • Often used to diagnose acute cholecystitis (very sensitive and specific) or biliary leaks after surgery 
      • Lack of filling of the gallbladder (photopenic area) suggests obstruction of cystic duct and can diagnose acute cholecystitis 
      • Can scan the abdomen to see if tracer is outside of biliary system to suggest leak



    References: Herring's Learning Radiology, Nuclear Medicine: The Requisites, Radiopaedia, Mandell's CORE Radiology

    続きを読む 一部表示
    22 分
  • Chest X-Ray: Lung Anatomy
    2022/07/05
    • Understanding normal anatomy is key before being able to understand what is abnormal



    • Anatomy review
      • Visceral pleura hugs the lungs (forms fissures), parietal pleura lines chest wall
      • Lobes of the lung: right lung has upper, middle, and lower lobes, left lung has upper and lower lobes
      • Fissures: right lung has horizontal/minor fissure and oblique major fissure, left lung has one huge oblique major fissure 
        •  Invisible or fine white lines, if thickened may represent excess fluid from a process such as congestive heart failure
      • Trachea -> carina -> main bronchus -> lobar (secondary) bronchi -> segmental (tertiary) bronchi -> subsegmental bronchi -> bronchioles -> secondary lobules (centrilobular artery and bronchus) -> respiratory bronchioles -> alveoli 
        • Cannot usually see bronchi on chest x-ray
        • Conduction zone = trachea, bronchi, bronchioles, terminal bronchioles
        • Respiratory zone = respiratory bronchioles, alveolar ducts, alveoli 
        • Lung parenchyma = alveoli, ducts, and respiratory bronchioles
        • Type 1 pneumocytes do gas exchange, type 2 pneumocytes produce surfactant, alveolar macrophages ingest and process debris
      • Hemidiaphragms: left is obscured by heart, on lateral radiograph can follow the right hemi all the way across
      • Left main pulmonary artery arches over the left main bronchus 
        • The right pulmonary artery will be anterior and inferior to the bronchus/left pulmonary artery on lateral radiograph
        • Each pulmonary artery may appear as slightly opaque compared to the lumen of the bronchus 
        • Pulmonary vessel markings taper peripherally and will show up as white lines thicker at the base of the lung 
      • Lungs have supply from pulmonary arteries and bronchial arteries (from aorta)
      • Pulmonary veins drain into left atrium
      • Innervation: parasympathetic from vagus, sympathetic from thoracic ganglia 
      • Lymph drainage goes to hilum 
      • Physiology: parasympathetic causes vasoconstriction, bronchoconstriction, gland secretion, sympathetic does opposite and opens things up 



    • Lateral radiograph is important to view areas of the lung that may not be obviously abnormal on frontal view 
      • Normal features of lateral radiograph:
        • Space behind the sternum (lack of could point to mediastinal masses)
        • Absence of a major shadow from the hila (presence could point to sarcoidosis)
        • Consistent height of vertebrae
        • Sharp posterior (requires less fluid to visualize) costophrenic angles (blunted/opacity filled could point to pleural effusion)
        • Continuous right hemidiaphragm (and slightly higher)



    • As with all studies/indications, when looking at an image, do not forget to look at all of the structures in field of view; even if you are reading a chest x-ray to rule out pneumonia/pneumothorax, remember to view all of the other structures, such as the thoracic vertebrae!



    References: Herring's Learning Radiology, Radiopaedia, Mandell's CORE Radiology 

    続きを読む 一部表示
    8 分
  • Chest X-Ray: Basics
    2022/06/28
    • Indications: broad (respiratory or cardiac disease, tube positioning, trauma) 



    • Characteristics of a good chest x-ray (PIER): 
      • Projection (AP, PA, lateral, lateral decubitus): heart will appear bigger on AP,  but not by much, AP is better for intubated/sick patients, two views is KEY
      • Inspiration and ribs: do you see at least 8-9 posterior ribs (if too little inspiration, things can crowd and mimic abnormalities)
      • Exposure: can you see the spine through the heart (too much penetration makes things dark, too little makes things bright and fuzzy)
      • Rotation and clavicles: what is the relationship between the clavicles and thoracic spinous processes (patient rotated to their right will have their left clavicle appear closer to the spinous process)
      • Angle of patient: should be perpendicular, but x-ray beams may be angled upward (apical lordotic), which can make anterior structures look more superior (clavicles above first rib)



    • Approach
      • Start every time with verifying patient information and imaging quality (PIER)/information 
      • Then execute your systematic approach for consistency 
      • Common approach is the tubes + ABCDEFGHI approach
      • First looks at tubes, lines, drains
      • A = airway, B= bones, C = cardiac, D = diaphragm, E = effusions/extra-thoracic tissues, F = fields, fissures, foreign bodies, G = great vessels, gastric bubble, H = hilum and mediastinum, I = impression
      • A/airway = follow the trachea down, is it midline
      • B/bones = follow outline of bones to look for fractures
      • C/cardiac = heart should be around or less than 50% diameter of chest
      • D/diaphragm = right hemi is slightly higher due to liver, are they flattened
      • E/effusions and extra-thoracic tissues = check costophrenic angles, lateral films, look for swelling, subcutaneous air
      • F/fields, fissures, and foreign bodies = check lung fields for opacities, masses, pneumothorax, vessel markings, look at major and minor fissures, assess any foreign bodies (wires)
      • G/great vessels and gastric bubble = follow path of aorta, pulmonary arteries and veins, gastric bubble under left hemidiaphragm
      • H/hilum and mediastinum = look for prominence (sarcoid), lymphadenopathy, masses, check for mediastinal widening (thymus can be normal in kids)
      • I/impression = overall conclusion or what is going on considering your findings 



    References: Herring's Learning Radiology, Radiopaedia, Mandell's CORE Radiology 

    続きを読む 一部表示
    11 分
  • Imaging Modalities
    2022/06/25
    • If this episode doesn't fascinate you, I don't know what will!!



    • Radiographs
      • Ionizing radiation hits a photosensitive film to produce an image
      • Digital radiography: photosensitive plate processed by electronic reader to be stored digitally
      • PACS system: picture archiving, communications, and storage system
      • Plain films = X-ray = radiograph = without contrast material
      • Advantages: availability, less expensive
      • Disadvantages: limited detail, uses radiation (caution in pregnancy)
      • Uses: chest x-ray, abdomen x-ray, bone visualization



    • Densities
      • Air is black (absorbs the least), bone is white (calcium), metal appears whitest, fat and soft tissues appear in between as gray 



    • CT scanners
      • Uses x-ray machine that rotates around patient to create different planes and produce a large series of 2D images slices
      • Important to understand positioning of patient from image (you're look up from the bottom of their feet, with patient's right on the left of the screen)
      • Hounsfield units: -1000 to +1000, water is zero, air is -1000, bone is +400-600, fat is -40 to -100, soft tissues is 20-100
      • Windowing: range of densities to most optimally view certain structures
      • Advantages: greater detail
      • Disadvantages: more radiation, more expensive 
      • Uses: non-contrast head CT for stroke, traumas, 3D reformats 



    • Ultrasound
      • Uses high frequency sound waves emitted from a probe
      • Advantages: less expensive, availability, no ionizing radiation
      • Disadvantages: operator dependent, low resolution 
      • Uses: great for pregnancy, gallstones, breast masses, thyroid nodules
      • Doppler flow: red towards probe, blue away from probe



    • MRI
      • Uses magnetic fields and radio waves to affect hydrogen items 
      • Advantages: great resolution, no radiation
      • Disadvantages: expensive, time-consuming, special precautions (pacemakers)
      • Uses: brain imaging (MS), soft tissues like muscles, tendons, ligaments, herniated discs, spinal cord pathologies 



    • Fluoroscopy
      • Uses ionizing radiation in real-time 
      • Can give barium to a patient which will show up black
      • Uses: esophagrams, voiding cystourethrograms, interventional radiology (angiography)
      • Advantages: mobile, procedure guidance, dynamic
      • Disadvantages: higher dose of radiation



    • Nuclear medicine
      • Uses radioactive substances (elements that emit radiation as they decay) and couples them with drugs that will accumulate in certain tissues
      • Different types of scans: positron emission tomography (PET) scans use radioactive glucose (fluorodeoxyglucose, FDG), single photon emission computed tomography (SPECT) uses a gamma camera to acquire images from many angles to create a 3D map
      • Different organs use different substances; the brain loves glucose and the thyroid loves iodine 
      • Uses: cancer imaging, assessing for metastases
      • Less radiation than CT scans, but must use caution with radiation exposure via shielding and appropriate timing 



    References: Herring's Learning Radiology, Radiopaedia, Mandell's CORE Radiology 

    続きを読む 一部表示
    14 分
  • Introduction
    2022/06/15

    Welcome to the RadEd podcast!


    In this episode: purpose, vision, goals for the podcast


    Disclaimer

    続きを読む 一部表示
    2 分