Neck MR Imaging Anatomy




The normal MR imaging appearance of the neck can be confusing given the number and complexity of structures that pass through it. This article strives to simplify normal MR imaging anatomy of the neck using a spatial approach. We present the protocols used at our institution and provide tables with details. Magnetic resonance (MR) imaging anatomy and appearance of the deep spaces of the neck are described with extensive labeled imaging correlates. Pearls and common pitfalls encountered with MR imaging of the neck are discussed. Additional aspects of normal neck MR imaging are described including lymph node, brachial plexus, and vascular anatomy.


The anatomy of the neck can be daunting for both radiologists and clinicians alike. Although small, the neck contains many vital structures. Therefore, mastery of its radiologic anatomy is essential for physicians evaluating for pathology. Magnetic resonance imaging (MR imaging) has become a vital tool to diagnose many disease processes affecting the neck region. Similar to computed tomography (CT), MR imaging has the advantage of cross-sectional imaging. Unlike CT, however, MR imaging does not require the use of intravenous contrast material to add soft tissue contrast, as the intrinsic signal characteristics of the interrogated tissues can often provide inherent differentiation. Moreover, when gadolinium contrast is required for MR imaging, it is generally considered safer than iodinated contrast used for CT, with a lower incidence of anaphylaxis and renal nephrotoxicity in patients with impaired renal function.


Additionally, MR imaging does not carry the burden of radiation exposure, which can become problematic for patients undergoing multiple CT scans throughout life, particularly considering the relative radiosensitivity of the thyroid gland. To spare ionizing radiation exposure, MR imaging of the neck can be performed in children, who are especially sensitive to the effects of repeated exposure. However, in very young children, general anesthesia is typically administered to prevent significant motion degradation. Therefore, the risks and benefits of MR imaging in young children must be weighed accordingly. MR imaging is advantageous in that multiplanar imaging can be easily performed without needing to reposition the patient, allowing for improved differentiation of masses, vessels, and soft tissue.


The suprahyoid neck is best imaged by MR imaging, as it is less affected by dental amalgam as compared with CT. Ultrasound may be used to evaluate the carotid arteries and thyroid gland, but cannot penetrate deeply enough to evaluate the visceral structures of the neck. Since the advent of MR imaging, serial improvements in spatial resolution and protocol technique have allowed for proper evaluation of normal anatomy, as well as the full array of pathology. This article describes the protocols used at our institution and the normal neck anatomy seen with current MR imaging techniques. Correlative imaging examples are provided as well.


Many systems are used for classifying and organizing the neck structures. This article approaches the neck from a neck space perspective. The neck space concept is a commonly used method to assist radiologists in organizing the neck and establishing appropriate differential diagnoses for pathology discovered within a specific space of the neck. For imaging purposes, the boundaries of the neck are considered to be the mandible and the mylohyoid muscles anterosuperiorly, the base of the skull posterosuperiorly, the scapulae posteroinferiorly, and the thoracic inlet (sternum, first ribs, first thoracic vertebra) centrally at the inferior aspect.


Protocol


Most neck MR imaging examinations performed at our institution follow a standard “General Neck” protocol, typically performed on a 1.5-Tesla magnet, although 3.0-Telsa examinations can provided increased spatial and contrast resolution ( Table 1 ). For all neck imaging, the patient is placed head first and supine into the magnet. A neurovascular array coil is placed on the patient. We use a 20-cm to 23-cm field of view (FOV), 5-mm to 6-mm slice thickness, and 1-mm to 2-mm interscan spacing. A wide range of matrices are used (see Table 1 ). First, a sagittal T1 sequence is obtained using a spin-echo pulse sequence from the clivus to the thoracic inlet, providing information about the pre-epiglottic space and the nasopharynx. Next, axial fluid-attenuated inversion recovery (FLAIR) and diffusion sequences are obtained through the entire brain. Then, an axial T2 fat-saturated fast spin-echo (FSE) sequence is performed from the clivus to the thoracic inlet, followed by an axial T1 FLAIR sequence, which is the best sequence for establishing anatomic relationships and identifying pathology within fat. FSE imaging provides the added benefit of a relatively short acquisition time limiting motion degradation, reduced magnetic susceptibility artifacts, and improved patient tolerance. Moreover, spin-echo techniques have high signal-to-noise ratios and therefore superior spatial resolution, as compared with inversion recovery sequences. Next, an axial dynamic spoiled gradient sequence is obtained from the skull base to the bottom of the hyoid bone following the administration of intravenous gadolinium. Then, sequential postcontrast axial T1 FLAIR and axial T1 fat-saturated images are obtained from the clivus to the thoracic inlet. Fat saturation assists in elucidating adenopathy, as well as enhancing mass lesions, which may otherwise be obscured by bright fat. Finally, an axial T1 postcontrast sequence is obtained through the brain.



Table 1

General neck
































































































































































1.5 Tesla T1, SE Diffusion Brain T2-FLAIR T2-Fat Sat, FSE T1-FLAIR Dynamic SPGR T1-FLAIR T1-Fat Sat, SE T1, SE Brain T1, SE a T1, SE a
TR, ms 600 10,000 10,000 3000–5000 1600–2500 230–305 1600–2500 500–700 500–700 500–700 450–700
TE, ms Min.Full Minimum 100 98 24 In Phase 24 Minimum Min.Full 19.23 19.23
TI, ms 2200 90
Slice, mm 5 6 6 5–6 5–6 4–5 5–6 5–6 6 3 3
Interscan spacing, mm 1.5 0 1.5 1.5–2 1.5–2 1 1.5–2 1.5–2 1.5 0.5 0.5
Gadolinium Pre Pre Pre Pre Pre Post Post Post Post Pre Post
Acquired planes Sagittal Axial Axial Axial Axial Axial Axial Axial Axial Coronal Coronal
Matrix, freq. 512 128 256 512 256 256 512 256 256 256 256
Matrix, phase 256 128 192 256 192 128 256 192 192 256 256
FOV, cm 20 22 23 20 20 20 20 20 23 20 20
Signal Averages 2NEX 1NEX 1NEX 3NEX 3NEX 1NEX 3NEX 2NEX 1NEX 2NEX 2NEX

Abbreviations: FLAIR, fluid attenuation inversion recovery; FOV, field of view; FSE, fast spin echo; SE, spin echo; SPGR, spoiled gradient recalled.

a Part of the nasopharynx protocol, imaged from posterior globe to posterior spinal cord in anteroposterior dimension and the top of frontal sinus to C1 in craniocaudal dimension.



Our institution also offers a “Larynx” protocol with a smaller FOV (18–20 cm) and smaller slice thickness (3–5 mm as compared with 5–6 mm for the general neck protocol). This sequence also provides smaller interscan spacing (0.5–1.5 mm). First, a sagittal T1 sequence is performed followed by axial T1 and T2 sequences. These images are obtained from the bottom of the pituitary gland to the thoracic inlet. Next, the axial T1 larynx sequence is performed from the hyoid bone to the thoracic inlet followed by postcontrast axial T1 fat-saturated images, both at 3-mm slice thickness. Finally, delayed axial T1 postcontrast standard and fat-saturated sequences are obtained at 5-mm slice thickness. A 256 × 256 matrix is used for the infrahyoid neck to increase the signal-to-noise ratio ( Table 2 ). The neck surface coil is vital to infrahyoid neck imaging, as is adequate motion suppression.



Table 2

Larynx
















































































































1.5 Tesla T1, SE T1, SE T2, SE T1, SE T1-Fat Sat, SE T1, SE T1-Fat Sat, SE
TR, ms 625 500–700 3000–5000 400–500 600–750 625 575
TE, ms Minimum Full Minimum 102 Minimum Full Minimum Minimum Full Minimum
TI, ms
Slice, mm 4 5 5 3 3 5 5
Interscan spacing, mm 1 1.5 1.5 0.5 0.5 1.5 1.5
Gadolinium Pre Pre Pre Pre Post Post Post
Acquired planes Sagittal Axial Axial Axial Axial Axial Axial
Matrix, freq. 512 448 448 256 512 448 512
Matrix, phase 256 256 256 256 256 256 256
FOV, cm 20 18 18 18 18 18 18
Signal averages 2NEX 2NEX 3NEX 2NEX 2NEX 2NEX 2NEX

Abbreviations: FOV, field of view; SE, spin echo.


Additional “nasopharynx” T1 spin-echo precontrast and postcontrast sequences are obtained in the coronal plane using the thinner slice thickness and interscan spacing described previously (see Table 1 ).


Typically, imaging of the suprahyoid neck requires only a standard head coil, whereas the infrahyoid neck requires a dedicated neck coil. The use of surface coils may improve spatial resolution, but at the cost of anatomic coverage. Water bags may be placed on either side of the patient’s neck to reduce magnetic susceptibility artifact.




Anatomy


The hyoid bone is used as a landmark to divide the neck into the suprahyoid and infrahyoid neck ( Fig. 1 A). The suprahyoid neck can be further subdivided into the following spaces: parapharyngeal space, pharyngeal mucosal space, masticator space, parotid space, sublingual and submandibular spaces, and the buccal space. There are spaces that are common to both the suprahyoid and infrahyoid neck, including the carotid space, retropharyngeal/danger space, perivertebral space, and the posterior cervical space. Finally, the visceral space is located solely within the infrahyoid neck.






Fig. 1


Suprahyoid neck anatomy: ( A ) Sagittal T1-weighted midline image of the neck demarcating the level of the hyoid bone ( blue line ), separating the suprahyoid neck above from the infrahyoid neck below. Other colored lines demarcate the various levels listed below ( red line, B; orange line, C; yellow line, D; green line, E ). ( B ) Axial T2-weighted image at the skull base: the cephaled-most aspect of the masticator space ( red outline ) extends superior to the zygomatic arch ( arrow ). Any disease process that occurs in this space warrants evaluation superiorly to the aponeurosis of the temporalis muscle (T) along the calvarium. GS, greater wing of sphenoid; Max, maxillary sinus; m, mandible; asterisk, pterygopalatine fossa. ( C ) Axial T1-weighted image more inferiorly at the alveolar ridge: The parapharyngeal space (PPS, black outline ) is readily apparent as a T1 hyperintense region, relating to its fat content. Anterolateral is the masticator space ( red border ) containing the masseter (M), lateral pterygoid (lp), and medial pterygoid (mp) muscles. The buccal space is located just anterior to the masticator space (B, asterisk border). Lateral to the parapharyngeal space is the parotid space ( green border ), which encompasses the isointense gland itself along with the retromandibular vein (v) within the substance of the parotid parenchyma. The carotid space encompassing the internal carotid artery (IC) and internal jugular vein (IJ) provides an additional lateral border to the PPS. Note the T1 isointense mucosal space medial to the PPS, including the torus tubaris ( arrow ). Posteriorly is the perivertebral space ( yellow border ) containing the longus colli muscle. ( D ) Axial T2-weighted image more inferiorly at the level of the oropharynx: Note the continuation of the masticator space ( red outline ) containing the mandible (m) and masseter (M). The parotid ( green border ) and parapharyngeal spaces have tapered down. The perivertebral space ( yellow outline ) is again noted, located just dorsal to the retropharyngeal space ( blue border ). Ton, palatine tonsils; IJ, internal jugular vein; IC, internal carotid artery; v, retromandibular vein; LC, longus colli. ( E ) Axial T1-weighted image at the level of the submandibular glands and hyoid bone (labeled): As the other suprahyoid neck spaces continue to taper down, the submandibular space appears ( orange outline ). This is bordered medially and superiorly by the isointense mylohyoid muscle (labeled) and contains the submandibular gland (labeled) as well as fat. The median raphe of the tongue is denoted by an arrow and the epiglottic valeculla can be seen posteriorly (v).


Deep cervical fascial planes are used to divide the neck further into deep fascial spaces. The deep cervical fascia is made up of 3 layers: a superficial layer, a middle layer, and a deep layer. The spatial resolution of MR imaging does not allow direct visualization of the fascia itself, but knowledge of the fascial layer’s course provides a manner by which to divide the neck into the deep fascial spaces with cross-sectional imaging. Of note, the superficial fascial layer is a separate layer not included within the 3 sublayers of the deep cervical fascia and consists of the subcutaneous tissues of the head and neck. The platysma and muscles of facial expression are embedded within this fascial layer, along with vessels, superficial lymph nodes, and cutaneous nerves.




Anatomy


The hyoid bone is used as a landmark to divide the neck into the suprahyoid and infrahyoid neck ( Fig. 1 A). The suprahyoid neck can be further subdivided into the following spaces: parapharyngeal space, pharyngeal mucosal space, masticator space, parotid space, sublingual and submandibular spaces, and the buccal space. There are spaces that are common to both the suprahyoid and infrahyoid neck, including the carotid space, retropharyngeal/danger space, perivertebral space, and the posterior cervical space. Finally, the visceral space is located solely within the infrahyoid neck.






Fig. 1


Suprahyoid neck anatomy: ( A ) Sagittal T1-weighted midline image of the neck demarcating the level of the hyoid bone ( blue line ), separating the suprahyoid neck above from the infrahyoid neck below. Other colored lines demarcate the various levels listed below ( red line, B; orange line, C; yellow line, D; green line, E ). ( B ) Axial T2-weighted image at the skull base: the cephaled-most aspect of the masticator space ( red outline ) extends superior to the zygomatic arch ( arrow ). Any disease process that occurs in this space warrants evaluation superiorly to the aponeurosis of the temporalis muscle (T) along the calvarium. GS, greater wing of sphenoid; Max, maxillary sinus; m, mandible; asterisk, pterygopalatine fossa. ( C ) Axial T1-weighted image more inferiorly at the alveolar ridge: The parapharyngeal space (PPS, black outline ) is readily apparent as a T1 hyperintense region, relating to its fat content. Anterolateral is the masticator space ( red border ) containing the masseter (M), lateral pterygoid (lp), and medial pterygoid (mp) muscles. The buccal space is located just anterior to the masticator space (B, asterisk border). Lateral to the parapharyngeal space is the parotid space ( green border ), which encompasses the isointense gland itself along with the retromandibular vein (v) within the substance of the parotid parenchyma. The carotid space encompassing the internal carotid artery (IC) and internal jugular vein (IJ) provides an additional lateral border to the PPS. Note the T1 isointense mucosal space medial to the PPS, including the torus tubaris ( arrow ). Posteriorly is the perivertebral space ( yellow border ) containing the longus colli muscle. ( D ) Axial T2-weighted image more inferiorly at the level of the oropharynx: Note the continuation of the masticator space ( red outline ) containing the mandible (m) and masseter (M). The parotid ( green border ) and parapharyngeal spaces have tapered down. The perivertebral space ( yellow outline ) is again noted, located just dorsal to the retropharyngeal space ( blue border ). Ton, palatine tonsils; IJ, internal jugular vein; IC, internal carotid artery; v, retromandibular vein; LC, longus colli. ( E ) Axial T1-weighted image at the level of the submandibular glands and hyoid bone (labeled): As the other suprahyoid neck spaces continue to taper down, the submandibular space appears ( orange outline ). This is bordered medially and superiorly by the isointense mylohyoid muscle (labeled) and contains the submandibular gland (labeled) as well as fat. The median raphe of the tongue is denoted by an arrow and the epiglottic valeculla can be seen posteriorly (v).

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Sep 18, 2017 | Posted by in MAGNETIC RESONANCE IMAGING | Comments Off on Neck MR Imaging Anatomy

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