Diagn Interv Radiol 2016; 22:156160

Turkish Society of Radiology 2015

EMERGENCY RADIOLOGY

PICTORIAL ESSAY

Abstract

Fish bone is one of the most common accidentally ingested foreign bodies, and patients commonly present to the emergency department with nonspecic symptoms. Fortunately, most of them are asymptomatic and exit the gastrointestinal tract spontaneously. However, sh bones can get impacted in any part of the aerodigestive tract and cause symptoms. Occasionally, they are asymptomatic initially after ingestion and may present remotely at a later date with serious complications such as gastrointestinal tract perforation, obstruction, and abscess formation. Radiographs are most often negative. High degree of clinical suspicion and familiarity with CT appearance can help to detect sh bone along with any associated complications, and direct further management. We describe and illustrate various CT presentations of ingested sh bone and its complications.

Fish bone is one of the most common accidentally ingested foreign bodies. They may account for up to 84% of the foreign bodies ingested accidentally (1). Majority of them are eliminated from the gastrointestinal system without any symptoms (2, 3). Compli

cations are seen in less than 1% of the cases (3). Complications range from mild inamma-tory changes to abscess formation, viscus perforation, intestinal obstruction, and bleeding. CT with intravenous contrast administration is the imaging modality of choice, as it can detect very small and even radiolucent sh bones. The multiplanar capability of CT further improves the diagnostic accuracy and may also help in management.

The predisposing factors for accidental sh bone ingestion include use of dentures, which impair palatal sensory feed back required to identify sharp objects, old age, alcoholism, mental retardation, eating rapidly, and talking while eating (3, 4). Most sh bones get lodged in the oral cavity or pharynx (5), especially in the tonsils or at the base of the tongue (1). They can also lodge in any other part of the gastrointestinal tract or rarely in trachea or major bronchi (6).

The uncomplicated cases in oral cavity or pharynx are easily visualized by the ear, nose and throat surgeon and can be removed by a scope. However, sh bones can also penetrate into deeper spaces of the neck (Fig. 1) causing edema, inammation, airway narrowing, and abscess formation. The authors also encountered a rare case of sh bone causing perforation of the pharynx and reaching to the skin surface (Fig. 2). Rare complications like vascular perforation, thyroid abscess, and neural injury have been reported (4, 68). Plain radiographs are commonly employed as the rst line of imaging in patients with suspected foreign body ingestion. As the vast majority of sh bones are radiolucent, a negative soft tissue radiograph cannot completely exclude the presence of one (1). A potential pitfall on plain radiographs is the presence of partial calcications of the various normal cartilages in the neck, which can mimic a foreign body. Accurate knowledge of the precise anatomical location of various cartilages can help to solve this conundrum. Doubtful cases warrant further evaluation and CT can clarify the diagnosis (Fig. 3). CT of the neck with contrast can accurately localize the sh bone and detect any associated complications (Fig. 1).

CT findings of accidental fish bone ingestion and its complications

Sandeep Halagatti Venkatesh

Nanda Kumar Venkatanarasimha Karaddi

Predisposing factors

Neck

Department of Radiology (S.H.V. sandeep_ [email protected]), Singapore General Hospital, Outram, Singapore.

Received 10 May 2015; revision requested 6 July 2015; revision received 25 July 2015; accepted 11 August 2015.

Published online 29 December 2015. DOI 10.5152/dir.2015.15187

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Figure 1. a, b. Ingested fish bone with perforation of the right hypopharynx. Axial (a) and sagittal (b) contrast-enhanced CT images of the neck demonstrate a linear hyperdensity lying in the right extra laryngeal space (long arrows) suggestive of ingested fish bone. There is significant edema in the right paralaryngeal area (a, short arrow) resulting in mild narrowing of the airway (a, arrowhead).

Upper and lower gastrointestinal tract

The most common site of impaction in the esophagus is within the cervical portion (9), mostly within the cricopharyngeus muscle at C5/C6 level (Fig. 4). The other sites of impaction within the esophagus are at the level of aortic arch, gastroesophageal junction, where normal extrinsic impression or anatomical narrowing is expected (Fig. 5). Such patients with sh bone impaction in the pharynx and esophagus usually present with symptoms like foreign body sensation, pain,

Main points

Fish bone is one of the most common accidentally ingested foreign bodies. It usually presents with nonspecic symptoms.

As the vast majority of sh bones are radiolucent, a negative soft tissue radiograph cannot completely exclude the presence of one.

Perforations and complications below the level of cricopharyngeus are relatively rare.

Such patients may present with nonspecic acute abdomen mimicking relatively common pathologies.

CT is a highly sensitive method for detecting sh bones; a denitive diagnosis is established by identication of the sh bone.

Potential pitfalls on CT include the presence of positive bowel contrast, cricoid cartilage calcication, artifacts related to fecal material within the colon and contrast opacied small blood vessels which can mimic a sh bone.

Figure 2. Fish bone causing perforation of the pharynx and reaching the skin surface of the neck. Coronal unenhanced CT of the neck demonstrates a linear hyperdensity in the left submandibular region, in keeping with a fish bone (arrow).

and swelling. Hence, diagnosis, especially by CT scan, is not very difficult as denitive clinical history is usually present. Fish bone impaction at these sites can be complicated by esophageal perforation, bleeding, hematoma, and abscess formation. Rarely, stulation into the adjacent trachea or great vessels can be seen (6). Thin wall, lack of adventitia, and relatively poor vascularity of the esophagus

Figure 3. ac. Cricoid cartilage mimicking an ingested fish bone. There is a linear hyperdensity in the prevertebral soft tissue of the neck (long arrow) on the radiograph (a) suggesting an ingested fish bone. On unenhanced CT of the neck, axial (b)and sagittal (c) reconstructed images confirm the linear density to represent dense calcification of the posterior aspect of the cricoid cartilage (b, c, short arrows) mimicking a fish bone on plain radiograph.

CT ndings of sh bone ingestion 157

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Figure 7. Ingested fish bone complicated by gastric perforation and perigastric inflammation. Axial contrast-enhanced CT of the abdomen demonstrates a linear fish bone (arrow) with transmural perforation of the posterior wall of the stomach with associated perigastric inflammatory changes.

Figure 4. Uncomplicated ingested fish bone in the upper esophagus. Unenhanced axial CT of the neck demonstrates a linear hyperdensity (arrow) at C5/C6, approximately at the cricopharyngeous muscle level.

Figure 5. Uncomplicated ingested fish bone at the gastroesophageal junction. Axial unenhanced CT of the abdomen demonstrates a linear hyperdensity (arrow) at the gastroesophageal junction suggestive of ingested fish bone.

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Figure 6. a, b. Ingested fish bone with perforation of the upper esophagus, and air in the deep spaces of the neck. Axial unenhanced CT of the neck (a) and sagittal unenhanced CT of the thorax (b) demonstrate a linear hyperdensity (b, arrow)in the distal esophagus suggestive of an ingested fish bone causing perforation of the upper esophagus resulting in air in the deep spaces of the neck (a, arrowhead). The perforation of upper esophagus was confirmed by esophagoscopy; the fish bone itself had moved into distal esophagus as seen on CT.

Figure 8. a, b. Ingested fish bone migrating into the liver from perforation of the stomach resulting in a hepatic abscess. Contrast-enhanced coronal (a) and axial (b) CT of the abdomen demonstrates a linear hyperdensity suggestive of ingested fish bone (arrows) within the liver parenchyma with small surrounding hypodensity suggestive of developing abscess (b, arrowhead).

makes it more susceptible to perforation and

necrosis (2) (Fig. 6).

Perforations and complications below the level of cricopharyngeus are relatively rare (6, 10). The clinical diagnosis in these cases may be challenging, especially if the clinical history of accidental sh bone ingestion is not forthcoming. Patients may present with nonspecic acute abdomen mimicking relatively common pathologies like acute cholecystitis and peptic ulcer disease. Diagnosis on plain radiography is difficult since the vast majority of sh bones are radiolucent, and the presence of uid collection and overlapping soft tissues of the abdomen commonly obscure the sh bone (2, 6). In these cases, the ingested sh bone may be detected in any part

of the upper gastrointestinal tract, and the denitive diagnosis is established on CT by demonstrating a hyperdense linear foreign body, which is best shown on bone window settings. (11).

In the stomach, because of the natural anatomical angularity of the lesser curvature, perforation is commonly seen at this location. The sh bone may partially perfo-rate the stomach wall, causing perigastric inammatory changes (Fig. 7) and perigas-

tric abscess. It may sometimes penetrate the entire thickness of stomach wall migrating into the adjacent hepatic parenchyma and cause hepatic abscess (Fig. 8) (12). The perforations of the stomach and duodenum (Fig. 9) are reported to present with prolonged and less severe clinical features than the perforations located in other parts of the bowel (13).

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In the small bowel, the most common sites of perforation include the less mobile segments of bowel or those with acute angulations such as ileum (11) (Fig. 10). The rectosigmoid junction is the most common site of sh bone impaction in the large bowel. Jejunum is an uncommon site of perforation (Fig. 11). The common ndings seen on CT include localized pneumoperitoneum, localized bowel wall thickening, localized mesenteric fat stranding, and abscess formation (Fig. 12). In some cases, the sh bone may be seen remote from the site of bowel perforation, lying free within the peritoneum (Fig. 11). Free pneumoperitoneum is rare as bowel perforation occurs by gradual erosion through the wall, which is spontaneously sealed by brin and omentum (3, 11). Occasionally, marked inammatory narrowing of the involved bowel segment may result in bowel obstruction (Fig. 13).

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Figure 9. a, b. Ingested fish bone complicated by duodenal perforation. Coronal contrast-enhanced CT of the abdomen demonstrates a linear hyperdensity in the duodenum suggestive of a fishbone (a, long arrow) with associated wall thickening suggestive of inflammation. There is localized pneumoperitoneum (b, arrowhead) and adjacent extensive inflammatory changes (b, short arrow) from transmural perforation.

Airway

Tracheobronchial foreign body aspiration is rare in adults. Fish bones may be found in the right bronchial tree because anatomically right bronchus is in line with trachea (Fig. 14). They can be asymptomatic or present with cough. Fish bone impaction can also lead to lung collapse and obstructive pneumonia.

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Dierential diagnosis

Fish bone perforations can occasionally simulate malignancy (14, 15) and other acute and chronic inammatory processes. This is commonly due to signicant inammatory thickening or mass-like appearance of the involved structures, lack of background history of sh bone ingestion and unfamiliarity with varied imaging appearance of the sh bones. CT is highly sensitive, and a denitive diagnosis can be es-

Figure 10. a, b. Ingested fish bone causing perforation of the ileum. Coronal contrast-enhanced CT of the abdomen demonstrates a linear hyperdensity (a, arrow) indicative of an ingested fish bone causing bowel wall thickening, mesenteric fat stranding, and a small locule of free gas within the peritoneum (b, arrowhead) indicative of a perforated ileum.

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Figure 11. ac. Ingested fish bone causing transmural perforation of the jejunum. Axial contrast-enhanced CT of the abdomen demonstrates a fish bone (a, long arrow) lying free within the peritoneum after transmural jejunal perforation. Note the marked thickening of the adjacent jejunal wall and associated stranding of the mesenteric and omental fat (b, short arrow) and small fluid collection (c, arrowhead).

CT ndings of sh bone ingestion 159

Conict of interest disclosure

The authors declared no conicts of interest.

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14. Bajwa A, Seth H, Hughes F. Ingested shbone mimicking a gastric submucosal tumour. Grand Rounds 2007; 7:4244.

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Figure 14. Accidental fish bone aspirationinto the large airway. Axial CT of the thorax demonstrates a linear hyperdensity (arrow) consistent with an aspirated fish bone within the lumen of right main bronchus. This was removed via a bronchoscope.

Figure 12. Fish bone ingestion complicatedby perforation of the ascending colon with a complex pericolonic abscess. Coronal contrast-enhanced CT of the abdomen demonstrates a linear hyperdensity indicative of a perforated fish bone (arrow) within the complex pericolonic abscess (arrowheads).

Figure 15. Bowel contrast or fecal material mimicking intraluminal fish bone seen on CT performed for other indications. AxialCT demonstrates an intraluminal linear hyperdensity within the colon (arrow), likely representing ingested oral contrast or dense fecal material, which can mimic a fish bone.

Figure 13. Ingested fish bone causing small bowel obstruction. Coronal contrast-enhanced CT of the abdomen shows linear hyperdensity embedded within the distal ileum (long arrow) causing high-grade small bowel obstruction (short arrows) with transition at the distal ileum.

Conclusion

tablished by identication of the sh bone. Careful attention to technical factors like thin slice thickness [1.52 mm], presence of negative bowel contrast and evaluation of reformats in multiple planes can aid accurate diagnosis.

Familiarity with various imaging features and relevant clinical history can establish the diagnosis of accidental sh bone ingestion. CT with its multiplanar capability is highly valuable to diagnose and accurately localize the ingested sh bone. In addition, CT can also provide a comprehensive evaluation of the complications of sh bone ingestion including those that may be seen remote from the site of bowel perforation.

Pitfalls

Potential pitfalls on CT include the presence of positive bowel contrast, which can

completely obscure or mimic the sh bone (Fig. 15), cricoid cartilage calcication simulating the sh bone (Fig. 3), artifacts related to fecal material within the colon, and contrast opacied small blood vessels, which can mimic the sh bone (3, 6). Clinical history and multiplanar reformat images conrm artifacts from the sh bone.

160 MarchApril 2016 Diagnostic and Interventional Radiology Venkatesh and Karaddi