the breadth of the diaphragm: congenital and acquired...
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©2016 MFMER | slide-1
The Breadth of the Diaphragm: Congenital and Acquired DerangementsIncluding 3D ImagingT. Johnson, J. Choe, D. White, J. Matsumoto, R. Kuzo, S. Blackmon, M. Allen, C. Koo
©2016 MFMER | slide-2
Goals and objectives• Review the normal imaging appearance of the diaphragm
• Discuss updates regarding development of the diaphragm
• Review congenital abnormalities of the diaphragm
• Review both benign and malignant abnormalities of the diaphragm
Disclosures• The authors have no financial disclosures related to this presentation
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Introduction• The diaphragm is a unique skeletal muscle that enables respiration
• Diaphragm abnormalities are often initially discovered on chest radiographs
• Alteration in position• Alteration in shape
• Evaluation of structural defects and intrinsic/adjacent pathology• Performed with CT and occasionally MRI
• Evaluation of diaphragm motion• Performed with fluoroscopy and occasionally MRI
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Normal diaphragm• Normal position of the diaphragm
can vary substantially
• The right hemidiaphragm dome is typically between T10-T12
• Left hemidiaphragm dome is typically ½ vertebral body lower
• 5-10% of patients are at the same level or higher
• The diaphragm tends to be lower with increasing age and higher with increasing weight
Right dome at T10 Left dome slightly below
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Normal diaphragm• Signs distinguishing right and left
hemidiaphragms• Entire anterior-posterior extent of
right diaphragm should be present
• Variable segment of anterior left diaphragm is obscured by heart diaphragm interface
• Gastric bubble under left
• Right ribs are magnified more than left
Right hemidiaphragm is associated with the magnified ribs
Right
Left
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Normal diaphragm• The diaphragm is best seen on CT
when surrounded by fat
• More difficult to see when adjacent to liver or spleen, particularly without contrast
• The diaphragm muscle bundles can take a more nodular appearance at their insertion point near the ribs
• The right crura is typically larger than the left
• Decussation of the right crura forms the esophageal hiatus
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Development of the diaphragm• Development occurs during 4-12 weeks of
embryonic life
• Complex interplay of structures:• Septum transversum
• Initial structure separating the thorax and abdomen
• Posthepatic mesenchymal plate (PHMP)
• Eventually seals the chest from the abdomen
• Pleuroperitoneal folds• Scaffolding positioned
posterolaterally in the cavity• Dorsal esophageal mesentery
• Forms the muscular portion of the diaphragm
Early diaphragm
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Development of the diaphragm• A study by Mayer et al. in 2011 showed
the PHMP plays a central role in sealing the diaphragm
• Abnormal development of the PHMP is central in the formation of congenital diaphragmatic hernias
• Mayer et al. demonstrated in rats that although the pleuroperitoneal folds and septum transversum appear normal, the PHMP is smaller and malformed
• This results in persistence of the pleuroperitoneal canals with resultant formation of a diaphragmatic defect
Late diaphragm
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Congenital abnormalitiesBochdalek hernia
• Results from incomplete closure of the pleuroperitoneal membrane in utero
• Typically posterolateral defects and usually on the left
• Variable size• Small – only retroperitoneal fat• Large – can contain viscera
• Incidental finding in adults• Increasing frequency with age
suggests these can be acquired
Bochdalek hernia
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Congenital abnormalitiesBochdalek hernia
Congenital Bochdalek hernia containing non-obstructed large bowel
Subsequent development of
bowel obstruction in same patient
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Congenital abnormalitiesBochdalek hernia
• Large Bochdalek hernias (congenital diaphragmatic hernia) in the neonatal period can represent a surgical emergency
• Common with incidence of ~1:3,000• Chest radiograph
• Opacification of hemithorax with abdominal viscera
• Mediastinal shift• Ultrasound can be used to diagnose
prenatally
• Can result in lung hypoplasia
Congenital diaphragmatic hernia with abdominal viscera above diaphragm
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Congenital abnormalitiesMorgagni hernia
• Related to abnormal development of the septum transversum
• Uniquely, the Morgagni hernia is covered with a sac of peritoneum and pleura
• Typically on the right
• Variable size• Small – contains omentum• Large – contains viscera
• Can result in volvulus and strangulation
Morgagni hernia
Morgagni hernia
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Acquired abnormalitiesHerniasHiatal hernia (type I)• Hiatal hernia is the most common
hernia in adults• GE junction slips into thorax• More common than
paraesophageal type• Prevalence increases with age
• Associated with obesity and pregnancy• Increased abdominal pressure
• Considered a risk factor for GERD
• Radiograph• Retrocardiac mass with air-fluid
level
• CT and MRI• Extension of the proximal aspect of
the stomach into chest
Air fluid level
Intrathoracic stomach
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Acquired abnormalitiesHerniasParaesophageal (type II-IV)• Less common than hiatal hernia (type I)
• Includes a peritoneal sac as opposed to the simple sliding hiatal hernia, which does not
• Can be asymptomatic or symptomatic• When symptomatic, at higher risk of
developing incarceration
• Classified into three types:• Type II – stomach herniates but
gastroesophageal junction remains normally positioned
• Type III – combination of type I and II• Type IV – stomach along with other
abdominal organs herniate into chestType II paraesophageal hernia
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Acquired abnormalitiesTraumatic diaphragm hernia
• Secondary to blunt or penetrating injury
• Diaphragm injuries occur more frequently on the left• Blunt: related to protection by liver on the right• Penetrating: related to most people being right handed
• Injury typically affects the posterior aspect of the diaphragm or posterolateral diaphragm attachments
• Depending on side of injury, stomach or liver may herniate• If large, may include bowel or spleen
• Early diagnosis is important because defects can enlarge
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Acquired abnormalitiesTraumatic
• Chest radiograph• Sensitivity ranges from 20-71%
• Radiographic findings• Herniation of abdominal viscera• NG tube within intrathoracic stomach• Elevated hemidiaphragm
• Particularly on the right• Suspect injury if right is elevated
4-5 cm above left
Elevated diaphragm
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Acquired abnormalitiesTraumatic
• Chest CT with multi-planar reformats• Sensitivity: 61-100%• Specificity: 77-100%
• Findings:• Dependent viscera – abnormal contact of
the abdominal viscera with the posterior ribs
• Collar sign – constriction of herniated contents
• Hump sign – focal bulge of liver• Absent diaphragm sign – diaphragm is not
present in a location where it should contact an organ
• Abrupt discontinuity of the diaphragm• Asymmetric thickening of the diaphragm
Collar sign
Dependent viscera sign with lacerated spleen
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Acquired abnormalitiesTraumatic
• Indications of penetrating trauma• Wound tract• Herniation of fat through diaphragmatic defect• Focal thickening of diaphragm
• Blood and/or edema
Wound tract
Hematoma
Active extravasation of contrast on delayed
imaging
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Acquired abnormalitiesPositional – elevation
• Unilateral elevation causes• Volume loss• Eventration• Phrenic nerve paralysis• Abdominal disease• Mimics include
• Subpulmonic effusion, pleural mass, diaphragmatic hernia
Subpulmonic effusion mimic
Diaphragm paralysis
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Acquired abnormalitiesPositional – elevation
• Bilateral elevation causes• Volume loss• Abdominal mass effect• Bilateral eventration• Bilateral subpulmonic effusion• Neuromuscular disease• Connective tissue disease• Phrenic nerve paralysis
Shallow inspiration with elevation of both hemidiaphragms
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Acquired abnormalitiesPositional – depression
• Unilateral depression causes• Pneumothorax• Bullous emphysema• Large pleural effusion• Congenital lobar emphysema
Large tension pneumothorax with depression of the right
hemidiaphragm
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Acquired abnormalitiesPositional – depression
• Bilateral depression causes• COPD• Deep inspiration• Bilateral large pleural effusion• Mechanical ventilation at high
pressures• Cystic fibrosis• Pulmonary langerhans cell
histiocytosis• Lymphangioleiomyomatosis
COPD with marked hyperinflation and depression of both hemidiaphragms
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Acquired abnormalitiesParalysis
• Can result from any abnormality along the neuromuscular axis of the diaphragm
• Invasion by neoplasm• Trauma related to surgery• CNS conditions such as multiple
sclerosis, syringomyelia, neurofibromatosis
• Mass effect• Aortic aneurysm, goiter,
lymphadenopathy• Idiopathic
Development of left hemidiaphragm paralysis following CABG
Pre-op
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Acquired abnormalitiesParalysis
• Fluroscopic sniff test• Gold standard• Evaluates for paradoxical upward diaphragm
motion with rapid inspiration through the nose• Normal diaphragm excursion is > 2.5 cm• Excursion < 2.5 cm may be normal or represent
diaphragm weakness• Paradoxical upward motion of the diaphragm > 2
cm suggests paralysis
• Confounding factors• Sniff test is best performed when reversible
conditions affecting the diaphragm have resolved• Pneumonia, pleuritis, peritonitis, etc…
• Severe weakness or complete eventration can be difficult to distinguish from paralysis
MRI sniff test, which has the added ability to assess for
extra-diaphragmatic pathologies not seen with
fluoroscopy
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Acquired abnormalitiesTumors – mimics
• Lateral arcuate ligament pseudotumor
• Ligament that courses along the posterior ribs
• Can take on a nodular appearance simulating a retroperitoneal tumor
• Can be bilateral, which is helpful in excluding a tumor
• When unilateral, typically has a curvilinear appearance and is contiguous with the diaphragm
Diaphragm lateral muscle bundles
A single muscle bundle can simulate a tumor. FDG PET/CT demonstrated non-avidity
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Acquired abnormalitiesTumors – benign
• Rare
• Benign tumors occur with similar frequency as malignant tumors
• Most commonly reported tumor is a benign cyst• Bronchogenic or mesothelial in origin
• Lipomas are the most commonly reported solid benign tumor• Does not disrupt the integrity of the diaphragm as opposed to a
Bochdelak hernia
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Acquired abnormalitiesTumors – benign
Diaphragmatic lipoma Diaphragm cyst
T2 weighting
Post contrastCoronal Coronal
Axial Axial
Diaphragm cyst
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Acquired abnormalitiesTumors – malignant
• Rare
• Typically sarcomas of fibrous or muscular origin
• The most common malignant tumor is rhabdomyosarcoma
• Other types• Schwannoma• Chondroma• Pheochromocytoma• Endometriosis• Hemangiopericytoma
• The diaphragm is a thin structure, which can make assessing the origin of a tumor difficult
• Tumors of the lung, pleura, or abdominal viscera are far more common
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Acquired abnormalitiesTumors – malignant
Rhabdomyosarcoma
FDG avid on PET/CT
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Acquired abnormalitiesTumors – malignant
Fibromyxoid sarcoma
Heterogeneously hyperintense on T2 weighting
Heterogeneously enhancing on T1 post-gadHypointense on T1 fat sat
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Acquired abnormalitiesTumors – malignant
Myxoid chondrosarcoma
Hyperintense on T2 weighting Enhancing on T1 post-gadHypointense on T1 fat sat
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3D modeling• Often described as an imaging revolution
• 3D modeling offers an incredibly powerful pre-surgical planning and education tool
• High resolution CT or MRI is obtained based on relevant anatomy
• Slice thickness is important in determining the level of model detail
• Choice of reconstruction algorithm (i.e. bone vs soft tissue) influences how the model looks
• Acquired data set from CT or MRI is transferred to an independent workstation
• A 3D model is created using a combination of hand tracing and automatic segmentation
• The finalized 3D model is exported in STL file format, which is recognized by 3D printers
Printing of diaphragm hernia for repair
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3D printing• At our institution, a multi-material printer is used, which
generates objects using additive printing
• A photopolymer is laid down by the printer and hardened with UV light
• Materials can be hard or soft and colored differently
• Material costs can range from hundreds to thousands of dollars and print time can take hours to days
• Models can be used for pre-operative planning or a reference during surgery
• Models can function as tools for both patient and medical education
Printing of diaphragm hernia for repair
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References• Nason et al: Imaging of the Diaphragm: Anatomy and Function. RadioGraphics 32:E51-E66, 2012
• Kanematsu M, et al: Dynamic MRI of the diaphragm. J Comput Assist Tomogr 19:67-72, 1995
• Mayer S, et al: The embryology of the diaphragm. Semin Pediatr Surg 20(3):161-1699, 2011
• Chavhan, et al: Multimodality Imaging of the Pediatric Diaphragm: Anatomy and Pathologic Conditions. Radiographics30: 1797-1817, 2010
• Philip N, et al: Epidemiological study of congenital diaphragmatic defects with special reference to aetiology. Eur J Pediatr 150(10):726-729, 1991
• Gale ME: Bochdalek hernia: Prevalence and CT characteristics. Radiology 156:449-452, 1985
• Becmeur F, et al: Accessory diaphragm: Review of 31 cases in the literature. Eur J Pediatr Surg 5:43-47, 1995
• Desir A, and Ghaye B: CT of Blunt Diaphragmatic Rupture. RadioGraphics 32: 477-498, 2012
• Guth A, et al: Pitfalls in the diagnosis of blunt diaphragmatic injury. Am J Surg 170:5-9, 1995
• Kim M, and Hofstetter W: Tumors of the diaphragm. Thorac Surg Clin, 19(4): 521-529, 2009
• Akinci D, et al: Diaphragmatic mesothelial cysts in children: radiologic findings and percutaneous ethanol sclerotherapy. AJR Am J Roentgenol, 19(4): 873-7, 2005
• Matsumoto J, et al: Three-demensional physical modeling: applications and experience at mayo clinic. RadioGraphics35:1989-2006, 2016
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Tucker F. Johnson M.D.johnson.tucker@mayo.edu
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