Stoelinga PJ, Peters JH, van de Staak WJ, Cohen MM Some new findings in the basal-cell nevus syndrome. Oral Surg Oral Med Oral Pathol. 1973; 36:686-692
Gorlin RJ, Goltz RW. Multiple nevoid basal-cell epithelioma, jaw cysts and bifid rib. A syndrome. N Engl J Med. 1960; 262:908-912
Jawa DS, Sircar K, Somani R, Grover N, Jaidka S, Singh S. Gorlin-Goltz syndrome. J Oral Maxillofac Pathol. 2009; 13:89-92
Kiwilsza M, Sporniak-Tutak K. Gorlin-Goltz syndrome – a medical condition requiring a multidisciplinary approach. Med Sci Mon Int Med J Exp Clin Res. 2012; 18:RA145-153
Maroto MR, Porras JL, Saez RS, de los Rios MH, Gonzalez LB. The role of the orthodontist in the diagnosis of Gorlin's syndrome. Am J Orthod Dentofacial Orthop. 1999; 115:89-98
Baliga SD, Rao SS. Nevoid-basal cell carcinoma syndrome: a case report and overview on diagnosis and management. J Maxillofac Oral Surg. 2010; 9:82-86
Lo Muzio L. Nevoid basal cell carcinoma syndrome (Gorlin syndrome). Orphanet J Rare Dis. 2008; 3
Lo Muzio L, Nocini P, Bucci P, Pannone G, Consolo U, Procaccini M. Early diagnosis of nevoid basal cell carcinoma syndrome. J Am Dent Assoc. 1999; 130:669-674
Lo Muzio L, Nocini PF, Savoia A, Consolo U, Procaccini M, Zelante L Nevoid basal cell carcinoma syndrome. Clinical findings in 37 Italian affected individuals. Clin Genet. 1999; 55:34-40
Yesudian D, Krishnan SG, Jayaraman M, Janaki VR, Yesudian P. Atypical gorlin's syndrome. Indian J Dermatol Venereol Leprol. 1995; 61:314-316
Dere KA Keratocystic odontogenic tumor: the correlation between recurrence rate and conservative treatment approach. nt J Oral Maxillofac Surg. 2015; 44
Madras J, Lapointe H. Keratocystic odontogenic tumour: reclassification of the odontogenic keratocyst from cyst to tumour. J Can Dent Assoc. 2008; 74
Kennedy RA. WHO is in and WHO is out of the mouth, salivary glands, and jaws sections of the 4th edition of the WHO classification of head and neck tumours. Br J Oral Maxillofac Surg. 2018; 56:90-95
Whaites E. Essentials of Dental Radiography and Radiology.Oxford: Elsevier; 2007
Yoshiura K, Weber AL, Runnels S, Scrivani SJ. Cystic lesions of the mandible and maxilla. Neuroimaging Clin N Am. 2003; 13:485-494
Scholl RJ, Kellett HM, Neumann DP, Lurie AG. Cysts and cystic lesions of the mandible: clinical and radiologic-histopathologic review. Radiographics. 1999; 19:1107-1124
Gohel A, Villa A, Sakai O. Benign jaw lesions. Dent Clin North Am. 2016; 60:125-141
Weber AL, Bui C, Kaneda T. Malignant tumors of the mandible and maxilla. Neuroimaging Clin N Am. 2003; 13:509-524
Gorlin-Goltz is a multisystemic inherited disorder characterized by multiple oral and systemic manifestations. Although rare, it is important for the general dentist to be aware of this condition due to the presentation of multiple odontogenic keratocysts, and to understand the differential diagnoses of jaw radiolucencies. This case describes a 53-year-old Afro-Caribbean patient who was referred by his dentist to the Maxillofacial team at Queen's Hospital regarding a ‘strange sensation’ in the mouth. Upon further investigation it was found that he had Gorlin-Goltz syndrome.
CPD/Clinical Relevance: This article highlights the importance of looking at ‘the bigger picture’ clinically and radiographically and provides a reminder of the oral manifestations of Gorlin-Goltz syndrome and differential diagnoses of jaw radiolucencies.
Article
Gorlin-Goltz is a rare condition characterized by various systemic manifestations, including multiple odontogenic keratocysts (OKCs). Due to the multitude of clinical and radiographic signs affecting the head and neck area, the dental practitioner has the opportunity to detect these signs and refer for further investigation and diagnosis. This emphasizes the importance of awareness of the condition's manifestations, in particular with regard to radiographic signs indicative of odontogenic keratocysts as they may present as incidental findings on routine dental radiographs.
In Gorlin-Goltz, multiple OKCs are found in the maxilla and the mandible, whereas in non-syndromic cases there is usually one sporadic OKC. It is important for the general dentist to be able to recognize anomalous radiographic appearances and be aware of the differential diagnoses of jaw radiolucencies, in particular the differences between benign and malignant conditions. This would enable the clinician to know when to refer for further management, including further imaging, for example dental panoramic tomography (DPT) and CT scans. The case report below highlights such a case where a patient was referred by his dentist regarding a radiolucency detected on an intra-oral radiograph.
Case presentation
A fit and healthy 53-year-old Afro-Caribbean male was referred to the Oral and Maxillofacial Surgery at Queen's Hospital by his dentist regarding a ‘strange sensation’ in the lower left canine and premolar area. A photocopy of a periapical radiograph was attached which showed a small radiolucency associated with the lower left first premolar. The patient was asymptomatic at the time. On examination, there was no swelling or paraesthesia. He was partially dentate with a large diastema between the lower central incisors. The lower left central and lateral incisors were distally inclined.
Investigations
The radiolucency on the intra-oral radiograph appeared to extend beyond the margins of the image. A DPT was taken (Figure 1) showing multiple large radiolucencies in the mandible and maxilla. In the anterior mandible there was a large well-defined uniformly radiolucent lesion, with scalloped margins, extending from the superior to the inferior border of the mandible and from the distal root of LL7 to the distal root of LL6, displacing the roots of LL12 and LL5. Similar radiolucencies were present in the left posterior mandible and the right and left posterior maxilla. These radiolucencies were suspected to be OKCs owing to their unilocular, well defined and corticated uniformly radiolucent appearance. Nevertheless, histopathological evaluation was required to confirm such a diagnosis.
Figure 1. DPT showing multiple radiolucencies in the mandible and maxilla.
Diagnosis
A discussion with the patient followed the extraordinary findings of the DPT. He denied any history or awareness of jaw cysts. When asked if he was familiar with the term ‘Gorlin-Goltz syndrome’, the patient showed immediate recognition: his son was being treated at Great Ormond Street Hospital for the same condition. Upon further questioning it was found that his father had suffered from oral cysts in the past.
The patient was subsequently sent for a CT head and neck scan (Figures 2 and 3) to ascertain the extent of the cysts and to detect other radiographic markers of Gorlin-Goltz. He was also listed for biopsy of the anterior cyst under local anaesthetic to verify OKC.
Figure 2. Axial view of CT head showing calcified falx cerebri.Figure 3. Sagittal view of CT head showing calcified falx cerebri and meninges.
The CT scans clearly showed calcified falx cerebri and other meninges, other major criteria for the syndrome, as well as cervical vertebral ribs (a minor criterion). The biopsy result confirmed the cyst is an OKC.
Treatment
The patient was understandably overwhelmed by the diagnosis. He felt that he would like to concentrate on his son's treatment and postpone the removal of any cysts. He is therefore continuing to be reviewed at our clinic with a view to treatment in the future.
Discussion
Gorlin-Goltz syndrome
Gorlin-Goltz is a multisystemic autosomal dominant inherited disorder characterized by multiple odontogenic keratocysts (OKCs), basal cell carcinomas (BCCs), palmar or plantar pits and other dental, skeletal, ophthalmic, neurological abnormalities and facial dysmorphia.1 It was first reported in 1894, although Gorlin and Goltz did not formally document its clinical features until the 1960s.2 It is caused by a mutation in the patched gene (a tumour suppressor gene) due to abnormalities on the long arm of chromosome 9, causing cell proliferation and producing multiple OKCs and BCCs.3 It is estimated that the prevalence of Gorlin-Goltz syndrome is 1 in 60,000 generally, and 1 in 57,000–164,000 in England.4 Males and females are affected equally, although simple keratocysts are found more commonly in males.5 Caucasians tend to be most affected by the syndrome, and it usually presents in patients aged 17–35.6
Its diagnosis is based on the presence of two major criteria and one minor clinical criterion, or one major and two minor criteria (Tables 1 and 2). Early diagnosis and treatment of Gorlin-Goltz syndrome are essential as 10% of patients are at risk of aggressive basal cell carcinoma and the development of other malignant neoplasia. Over 100 minor criteria have been described, hence patients with a myriad of clinical presentations may be seen.3
Minor Criteria
Cutaneous defects
Basal cell naevus
Benign dermal cysts/tumours
Palmar pitting
Palmar and plantar keratosis
Dermal calcinosis
Osseous anomalies
Multiple odontogenic keratocysts
Mild mandibular prognathism
Frontal bossing
Vertebral defects
Spina bifida
Bifurcated ribs
Ophthalmic anomalies
Hypertelorism
Widened nasal bridge
Congenital blindness
Neurological anomalies
Intellectual disability
Dural calcification
Congenital hydrocephalus
Bridging of the sella
Sexual anomalies
Hypogonadism
Ovarian tumour-like fibrosarcoma
Major Criteria
Multiple basal cell carcinomas occurring below the age of 20
Odontogenic keratocysts of the jaw confirmed histologically
Three or more palmar or plantar pits
Bilamellar calcification of the falx cerebri
Rib anomalies that include bifid, fused or significant splaying
First degree relative with nevoid basal cell carcinoma syndrome
Our aforementioned patient fulfilled three major criteria for Gorlin-Goltz syndrome: OKC confirmed histologically, calcified falx cerebri and a first degree relative suffering the same condition. As with previously described cases, our patient's initial finding was the identification of multiple lesions in the mandible which were confirmed as OKCs. Less than 10% of patients with multiple OKCs have other manifestations of Gorlin-Goltz syndrome and previous reports have suggested multiple OKCs alone may be enough to establish this disorder.7,8 In Gorlin-Goltz, OKCs tend to occur more commonly in the mandible with approximately a third affecting the maxilla.9,10 Within the mandible the most common areas include:5
Molar ramus region;
Incisor-canine region;
Premolar region.
Patients should be informed that, although benign in nature, the OKC is locally destructive and has a recurrence rate of 3–60%.11
Odontogenic keratocysts
The odontogenic keratocyst has a colourful history with regards to nomenclature and classification. It has experienced many name changes owing to its combined cystic nature and neoplastic potential. In 2005, the WHO changed the classification of OKC from a cyst to a tumour because of certain neoplastic features, including recurrence, potentially aggressive and destructive behaviour, and pathogenesis associated with mutation of the ‘patched’ tumour suppressor gene (PTCH).12 It therefore received the name ‘keratocystic odontogenic tumour’. However, in 2017, the evidence to class it as a neoplasm was deemed insufficient and it was redesignated as a cyst and regained the name ‘odontogenic keratocyst’.13
Differential diagnosis of jaw radiolucencies
Cysts tend to have smooth, well-defined margins and be uniformly radiolucent. They are usually well corticated, although the level of cortication may be influenced by the presence of infection. They tend to be slow growing and cause displacement of adjacent structures and bony expansion in the later stages.14 Cysts may be differentiated from each other radiographically by their location and association with adjacent structures, eg impacted teeth or non-vital teeth.15 Some cysts may display calcification (eg calcifying epithelial odontogenic tumour), which helps to distinguish them from other cysts.16
Benign tumours are slow growing, well-defined lesions with smooth borders. Similarly to cysts they tend to cause displacement and expansion rather than resorption. However, these tumours have varying radiodensities, and may appear as radiolucent, mixed or radio-opaque, depending on the lesion.17
Malignant tumours can be distinguished from benign jaw radiolucencies by their poorly-defined radiographic appearance and irregular margins.14 Due to their fast and aggressive pattern of growth, they tend to resorb roots and erode adjacent structures rather than displace or expand.18 Some benign lesions, such as odontogenic keratocysts, may also exhibit aggressive growth and require prompt management. It is crucial to be able to distinguish these characteristics from those of benign lesions to ensure rapid referral.
Table 3 highlights distinguishing features of some jaw radiolucencies to aid differentiation. This is by no means an extensive list and further reading is encouraged.
Radiolucent Lesion
Radiographic Features
CYSTS
Radicular and residual cysts
Mostly in the anterior maxilla
Well-demarcated and unilocular
Cortex of cyst continuous with lamina dura of associated non-vital tooth
Can be difficult to differentiate from periapical granuloma
Residual cysts are radicular cysts that remain following extraction of the associated tooth
Odontogenic keratocyst
Behaviour and appearance tends to differ from other odontogenic cysts
Commonly seen in mandibular third molar region extends up the ramus
May be multilocular
May cause root resorption but this tends to be less common and severe than in ameloblastomas
Dentigerous cyst
Associated with unerupted teeth, commonly mandibular third molars, second premolars and maxillary canines
The crown of the unerupted tooth is included in the cyst cavity
Typical appearance of well-demarcated, unilocular radiolucency
Lateral periodontal cyst
Well-defined radiolucent lesion lateral to the root of a tooth
Calcifying odontogenic cyst
Unilocular radiolucency with irregular calcifications within the lesion
Sometimes associated with impacted teeth
May cause root resorption
BENIGN TUMOURS
Ameloblastoma
Mostly in third molar region
Associated with follicular cysts or impacted teeth
Radiolucent, unilocular or multilocular, characteristic ’soap-bubble’ appearance
May cause significant resorption of roots and erosion of cortical bone
In premolar/molar region, usually lower third molar region
Half are associated with an impacted tooth
Calcifications may be present near the crown of the impacted tooth
Ameloblastic fibroma
Mixed radiolucency in the posterior mandible or maxilla
Half associated with an unerupted or ectopic tooth
MALIGNANT TUMOURS
Carcinoma of oral cavity with secondary invasion of maxilla/mandible
Early involvement appears as irregular saucer-shaped erosion of cortical bone
Evolves to larger irregular cavity
Malignant ameloblastoma
May be undistinguishable from benign ameloblastoma
If the lesion has carcinomatous features may have characteristic features of malignancies and be indistinguishable from other jaw carcinomas
Odontogenic carcinoma
90% are found in the mandible
Radiolucent irregular lesion, may contain bony spicules
Summary
Gorlin-Goltz syndrome is a well-known syndrome with a variety of findings in the head and neck region. The role of the dentist in initial recognition of signs is therefore invaluable and awareness of this rare condition is essential to aid early diagnosis. General dentists should be looking at the ‘bigger picture’, in particular family history, and clinical and radiographic signs to help recognize this condition. Early diagnosis is crucial in young patients to provide optimal management while cysts are relatively less extensive, and advice concerning protection of the skin from sunlight can be provided to reduce incidence of basal cell carcinomas.
There is a wide variety of radiolucencies that may manifest in the maxillae and it is vital that dentists carefully assess radiographs for abnormalities and are able to differentiate between various types of lesions, in particular between malignant and benign lesions. This enables correct and prompt referral for further investigations and management, as appropriate.
