Dynamic manoeuvres on MRI in oral cancers – A pictorial essay

• Abstract
• Introduction
• Learning Objectives
• Normal Anatomy
• Dynamic Manoeuvres
• Manoeuvre 1: Puffed Cheek Manoeuvre
• Technique
• Advantage
• Limitation
• Manoeuvre 2: Water Distension of Oral Vestibule
• Technique
• Advantage
• Limitation
• Manoeuvre 3: Tongue Protrusion Manoeuvre
• Technique
• Advantage
• Limitation
• Manoeuvre 4 Open Mouth Manoeuvre
• Technique
• Advantage
• Limitation
• Conclusion
• References

Abstract

Magnetic resonance imaging has been shown to be a useful tool in the evaluation of oral malignancies because of direct visualization of lesions due to high soft tissue contrast and multiplanar capability. However, small oral cavity tumours pose an imaging challenge due to apposed mucosal surfaces of oral cavity, metallic denture artefacts and submucosal fibrosis. The purpose of this pictorial essay is to show the benefits of pre and post contrast MRI sequences using various dynamic manoeuvres that serve as key sequences in the evaluation of various small oral (buccal mucosa and tongue as well as hard/soft palate) lesions for studying their extent as well as their true anatomic relationship.

Introduction

In the imaging of oral cavity lesions, it is important to determine precisely the site of tumour origin, size, trans-spatial extension and invasion of deep structures.[1] Evaluation of small tumours of the oral cavity is always a diagnostic challenge for both the head and neck surgeon and the head and neck radiologist.

Small gingivo-buccal, retromolar trigone (RMT) or small tongue lesions are routinely obscured on cross sectional imaging by close apposition of mucosal surfaces of lips and cheeks to the gingival surfaces of alveolar processes or apposition of the tongue to the lingual surfaces of alveolar processes and the hard palate.[2]

Dynamic manoeuvres on multidetector CT (MDCT) imaging of oral cavity lesions are well known an established technique.[1], [2], [3], [4], [5], [6], [7] However, MDCT remains suboptimal in the evaluation of small oral cavity lesions particularly in patients with sub-mucosal fibrosis, RMT lesions, post-operative evaluation and in presence of metallic dental streak artefacts. MRI in these circumstances scores over MDCT and is a preferred modality with excellent soft tissue contrast resolution.

MR imaging with various dynamic manoeuvres provides precise imaging information about the location of small inconspicuous lesions in the oral cavity - their exact site of origin and the extent of the larger or exophytic tumours.[8] Use of dynamic manoeuvres in MRI helps either ‘rule in’ small lesions or ‘rule out’ tumour extension.

Learning Objectives

• To demonstrate usefulness of various dynamic manoeuvres in pre and post-contrast MRI sequences for the evaluation small buccal mucosa/alveolar mucosa lesions

• To demonstrate true anatomic relationships of small oral cavity lesions arising from tongue, hard/soft palate, and floor mouth lesions

• To compare with conventional MR sequences for evaluation of oral cavity lesions.

Normal Anatomy

The oral cavity is divided into a central part “oral cavity proper” and “vestibule”. The oral cavity proper is bounded by the alveolar arches and communicates posteriorly with the oropharynx. Its roof is formed by hard palate and floor by mucosa of floor of mouth. The anterior two-third of the tongue also known as mobile tongue is contained within oral cavity proper.[2] The vestibule is lined by the buccal mucosa laterally, superiorly and inferiorly by reflections of the buccal mucosa onto the mandible and maxilla respectively, referred as the upper and lower gingivobuccal sulci (GBS) and the gingival mucosa medially.[3] The buccal space or bucco-masseteric space lies lateral to the vestibule.

At rest, the buccal mucosa, gingival mucosa, mucosa lining the inner surface of lips and vestibular reflections remain apposed to each other. Superior and inferior GBS remain apposed with gingiva.[8] RMT is a triangular shape mucosal fold that extends behind the last molar teeth of mandible up to the maxillary last molar teeth on either side. Pterygomandibular raphe lies behind the RMT and attaches superiorly to pterygoid hamulus and inferiorly posterior border of mylohyoid muscle.[2], [3], [8]

Dynamic Manoeuvres

The purpose of radiological interpretation is to portray meaningful information to clinical colleagues. Below described the useful dynamic manoeuvres that act as key sequences for evaluation of small or hidden oral cavity lesions [Table 1]. The optimal MRI sequences for each manoeuvres and its MRI parameters are mentioned below [Table 2].

Manoeuvre 1: Puffed Cheek Manoeuvre

Technique

Puffed cheek MRI manoeuvre is performed by asking the patient to blow the mouth uniformly through pursed lips. This technique can be optimized by asking the patient to move the tongue away from the hard palate and the teeth.

By puffing the cheeks, the oral vestibule is filled with air, which by creating a negative contrast, separates the buccal and labial mucosa from the gingival mucosa, allowing both mucosal surfaces to be assessed separately[1] [Figure 1]. This manoeuvre can be easily adopted by the patient and adds negligible amount of time on total scan time. The buccinator muscle is better seen on puffed-cheek images [Figure 1] than on the conventional MRI scans,[5], [6] thus helping either “rule in” or “rule out” tumour extensions and the depth of muscle invasion.

Advantage

It is helpful in evaluation of small primary buccal mucosa lesion involving anterior buccal mucosa, anterior part of upper or lower GBS and angle mouth/vestibule. Strong metallic artefacts caused by dental implants and metallic orthodontic appliances are a common problem in head and neck MRI.[6] This manoeuvre is used to improve detection and correct staging of small lesions in the oral cavity whenever artefacts are present [Figure 2]. Also, it helps to delineate the extent, mucosal and sub-mucosal spread [Figure 3], buccinator involvement and rule out/rule in outer gingival or alveolar mucosal involvement.[9], [10] Precise evaluation of location, extent and anatomic relationship of the oral cavity lesions helps the surgeon in planning of primary surgery and type of reconstruction for minimizing morbidity.

Limitation

This manoeuvre has limitations in patients with severe sub-mucosal fibrosis, evaluation of posterior GBS and RMT lesions and in post-operative patients with large flap reconstruction for oral cancers which does not allow proper distension of oral cavity.

Manoeuvre 2: Water Distension of Oral Vestibule

Technique

This manoeuvre is performed by distension of oral vestibule by asking patient to drink 20-40 cc of plain water and hold it in mouth, patients have good compliance to hold water in mouth for 80 seconds only during pre and post contrast T2W and T1WFS sequences. This manoeuvre aids by providing an excellent natural contrast between lesion and adjacent normal buccal mucosa and other anatomic structures on T2W and post contrast T1W FS (fat saturated) MRI sequences. The pterygomandibular raphe and RMT can be better delineated [Figure 4]. The natural contrast also delineates inner alveolar mucosa, thus help rule in/rule out alveolar mucosa involvement.

Advantage

Evaluation of small posterior buccal mucosa/RMT tumours and its deeper extent is a real challenge to radiologist. The manoeuvre can optimally distend the oral vestibule. As water retains in RMT region in dependent position during MRI study, it helps in distension of posterior (dependent) aspect upper and lower GBS and RMT that are not well evaluated with puffed cheek technique or on CT scan [Figure 5].

The author recommends water distension technique particularly in evaluation of patients with severe sub-mucosal fibrosis, lesion sitting in RMT and lesions of posterior buccoalveolar mucosa [Figure 6] where smaller mucosal lesions can be missed during clinical examinations or exact depth and extent cannot be evaluated during clinical examination/CT scan/conventional MRI scan. This manoeuvre has added value for chronic tobacco chewer with significant submucosal fibrosis which hinders evaluation of oral cavity either clinically or on conventional CT scan, and also on MRI [Figure 7].

Post-operative oral cavity lesions are a real challenge to onco-radiologists particularly to demonstrate small recurrent malignant lesions of buccal mucosa. Due to post-operative fibrosis, these patients cannot perform puffed cheek manoeuvre. In such scenarios, water distension manoeuvre helps to distend the oral vestibule [Figure 8].

MRI is a reliable tool in assessing the depth of invasion and thickness of tumours of tongue and has a significant correlation with the final histopathological findings.[11], [12] However, in certain exophytic lesions, conventional MRI has limitations in assessing depth of tumour invasion and tumour thickness. Water distension manoeuvre helps in evaluation of exophytic tongue lesions, delineates true exophytic and intra-substance infiltrative component [Figure 9].

Limitation

Water distension of vestibule cannot be performed in patients with oro-cutaneous fistula, edentulous patients and in post-operative oral cavity with large flap reconstruction. This manoeuvre does not give any additional information for large buccal mucosa or other large oral cavity lesions because for such lesions locoregional extension and relationship with adjacent neck spaces are more relevant.

Manoeuvre 3: Tongue Protrusion Manoeuvre

MRI with contrast is the choice of modality for evaluation of tongue lesions and its extent. Small tongue lesions along the lateral and ventral surface of tongue are difficult to assess due to close apposition of soft tissue at rest and artefacts generated by dental amalgams.[8]

Technique

This manoeuvre is performed by asking the patient to protrude the tongue against floor of mouth as much as possible and sequence acquired while the patient protrudes the tongue [Figure 10].

Advantage

This is a useful additional manoeuvre along with conventional MRI sequences for small tongue lesion along lateral and ventral aspect of anterior oral tongue or lesion involving tip (apex) of tongue [Figure 11].

Limitation

Manoeuvre does not give any additional information for large tongue lesions or lesions of isolated floor of mouth/base of tongue. Motion artifacts are common while performing this manoeuvre.

Manoeuvre 4 Open Mouth Manoeuvre

Technique

The open mouth manoeuvre is performed by asking the patient to hold in open mouth position during MRI sequence [Figure 12]. A device (syringe) can be placed between teeth to ensure proper immobilization. The open mouth technique is also helpful when lesion of the oropharynx is not clearly visible because of dental amalgam artefact.[3]

Advantage

It is a useful manoeuvre for evaluation of small lesions of hard palate or and soft palate mucosa[9] [Figure 13]. It helps to delineate precise thickness of the lesion, presence and involvement of extent of upper alveolar mucosa, RMT and adjacent GB sulcus easily or secondary involvement of palate in primary upper alveolar lesions. Delineate exact extent of palatal lesions which helps in oncoplastic reconstructions of palatal defects.

Limitation

Motion artifact is a major limitation of this manoeuvre.

Conclusion

Dynamic manoeuvres are simple and easy with short duration MR sequences as they overcome the limitations of MDCT scan and MRI and thus provide more detailed and specific information to the surgical oncologist for delineating exact margins and better oncoplastic reconstruction in the era of minimal invasive surgery. The use of dynamic manoeuvres in MRI helps either ‘rule in’ small lesions or ‘rule out’ tumour extensions in lesions of oral cavity. Such manoeuvres should always be incorporated in routine clinical MRI practice for evaluation of oral cavity lesions by the radiologist.

Conflict of Interest

There are no conflicts of interest.

• References

• 1 Celebi I, Oz A, Sasani M, Bayindir P, Sözen E, Vural C, Başak M. Using dynamic manoeuvres in the computed tomography/magnetic resonance assessment of lesions of the head and neck. Can Assoc Radiol J 2013; 64: 351-7
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• 4 Kim HC, Moon MH, Han MH, Kim JH, Kim IO, Chang KH. CT and MR imaging of the buccal space: Normal anatomy and abnormalities. Korean J Radiol 2005; 6: 22-30
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• 7 Dillon JK, Glastonbury CM, Janeen F, Schmidt BL. Gauze padding: A simple technique to delineate small oral cavity tumors. Am J Neuroradiol 2011; 32: 934-7
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• 9 Henrot P, Blum A, Toussaint B, Troufleau P. Dynamic manoeuvres in local staging of head and neck malignancies with current imaging techniques: Principles and clinical applications. Radiographics 2003; 23: 1201-13
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• 10 Paul P, Sable N, Arya S. Imaging of Oral Cancer. In: Panta P. (eds) Oral Cancer Detection. Springer Nature; 2019: 109-131
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  CrossrefSearch in Google Scholar
• 11 Lam P, Au-Yeung KM, Cheng PW, Wei WI, Yuen AP, Trendell-Smith N. et al. Correlating MRI and histologic tumour thickness in the assessment of oral tongue cancer. Am J Roentgenol 2004; 182: 803-8
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• 12 Weimar EAM, Huang SH, Lu L, O’Sullivan B, Perez-Ordonex B. et al. Radiologic-pathologic correlation of tumour thickness and its prognostic importance in squamous cell carcinoma of the oral cavity: Implication for the eight edition tumor, node, metastasis classification. AJNR Am J Neuroradiol 2018; 39: 1896-902
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Address for correspondence

Publication History

Received: 27 February 2020

Accepted: 24 July 2020

Article published online:
19 July 2021

© 2020. Indian Radiological Association. This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial-License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commercial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/).

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• References

• 1 Celebi I, Oz A, Sasani M, Bayindir P, Sözen E, Vural C, Başak M. Using dynamic manoeuvres in the computed tomography/magnetic resonance assessment of lesions of the head and neck. Can Assoc Radiol J 2013; 64: 351-7
  MissingFormLabel

  CrossrefPubMedSearch in Google Scholar
• 2 Fatterpekar GM, Delman BN, Shroff MM, Naidich TP, Sacher MS, Som PM. Distension technique to improve computed tomographic evaluation of oral cavity lesions. Arch Otolaryngol Head Neck Surg 2003; 129: 229-32
  MissingFormLabel

  CrossrefPubMedSearch in Google Scholar
• 3 Arya S, Chaukar D, Pai P. Imaging in oral cancers. Indian J Radiol Imaging 2012; 22: 195-208
  MissingFormLabel

  Thieme ConnectPubMedSearch in Google Scholar
• 4 Kim HC, Moon MH, Han MH, Kim JH, Kim IO, Chang KH. CT and MR imaging of the buccal space: Normal anatomy and abnormalities. Korean J Radiol 2005; 6: 22-30
  MissingFormLabel

  CrossrefPubMedSearch in Google Scholar
• 5 Weissman JL, Carrau RL. Puffed-cheek” CT improves evaluation of the oral cavity. Am J Neuroradiol 2001; 22: 741-4
  MissingFormLabel

  PubMedSearch in Google Scholar
• 6 Lemos M, Gomes RLE, Zuppani HB, Silva CJ, Gebrim EMM, Garcia MRT. Sao Paulo/BR; São Paulo, SP/BR. The role of imaging in the diagnosis and staging of oral cavity cancer. Educational Exhibit ECR 2018
  MissingFormLabel
• 7 Dillon JK, Glastonbury CM, Janeen F, Schmidt BL. Gauze padding: A simple technique to delineate small oral cavity tumors. Am J Neuroradiol 2011; 32: 934-7
  MissingFormLabel

  CrossrefPubMedSearch in Google Scholar
• 8 Oberoi R, Jena A. Usefulness of dynamic manoeuvres in MR evaluation of oral malignancies. Indian J Radiol Imaging 2006; 16: 379-84
  MissingFormLabel

  Thieme ConnectSearch in Google Scholar
• 9 Henrot P, Blum A, Toussaint B, Troufleau P. Dynamic manoeuvres in local staging of head and neck malignancies with current imaging techniques: Principles and clinical applications. Radiographics 2003; 23: 1201-13
  MissingFormLabel

  CrossrefPubMedSearch in Google Scholar
• 10 Paul P, Sable N, Arya S. Imaging of Oral Cancer. In: Panta P. (eds) Oral Cancer Detection. Springer Nature; 2019: 109-131
  MissingFormLabel

  CrossrefSearch in Google Scholar
• 11 Lam P, Au-Yeung KM, Cheng PW, Wei WI, Yuen AP, Trendell-Smith N. et al. Correlating MRI and histologic tumour thickness in the assessment of oral tongue cancer. Am J Roentgenol 2004; 182: 803-8
  MissingFormLabel

  CrossrefPubMedSearch in Google Scholar
• 12 Weimar EAM, Huang SH, Lu L, O’Sullivan B, Perez-Ordonex B. et al. Radiologic-pathologic correlation of tumour thickness and its prognostic importance in squamous cell carcinoma of the oral cavity: Implication for the eight edition tumor, node, metastasis classification. AJNR Am J Neuroradiol 2018; 39: 1896-902
  MissingFormLabel

  CrossrefPubMedSearch in Google Scholar