Robert Raschke

Steven Curry

Silke Remke

Ester Little

Richard Gerkin

Richard Manch

Alan Leibowitz

Banner Good Samaritan Regional Medical Center, Phoenix, AZ

Reference as:  Raschke R, Curry S, Remke S, Little E, Gerkin R, Manch R, Leibowitz A. Arterial ammonia levels in the management of fulminant liver failure. Southwest J Pulm Crit Care 2011;2:85-92. (Click here for PDF version)

Abstract

Previous studies have suggested that an arterial ammonia level greater than 150 mmol/L is highly sensitive for predicting subsequent development of cerebral edema in patients with fulminant liver failure. We performed a prospective cohort study to confirm this relationship. We enrolled 22 consecutive patients who presented to our transplant hepatology service with grade 3-4 encephalopathy associated with fulminant liver failure. All patients underwent placement of an intraparenchymal ICP monitor, and every 12 hourly arterial ammonia levels. The prevalence of intracranial hypertension (IHTN) in our population was 95% (21/22 patients), with 82 discrete episodes recorded. The sensitivity of arterial ammonia levels to predict the onset of IHTN was 62% (95% CI: 40.8 to 79.3) at a cut point of 150 mmol/L. Arterial ammonia levels preceding the first intracranial hypertension event were less than 150 mmol/L in 8 of 21 patients (39%). Fifty nine of 82 episodes of IHTN (73%) occurred when arterial ammonia levels were less than 150 mmol/L. We conclude that the arterial ammonia level is not useful in making decisions regarding management related to cerebral edema in patients with fulminant liver failure. In fact, since almost all our study patients with grade III or IV encephalopathy secondary to fulminant liver failure went on to develop intracranial hypertension, our study supports the contention that all such patients might benefit from ICP monitoring regardless of arterial ammonia levels.

Background

Cerebral edema is the most common cause of death in fulminant liver failure (FLF) (1,2), occurring in 80% of patients with advanced encephalopathy (3). Cerebral edema causes brain injury by compromising cerebral perfusion pressure and/or by causing cerebral herniation. Intracranial hypertension (IHTN) is the most reliable sign of cerebral edema, and is defined as an intracranial pressure (ICP) greater than 20 mmHg (4-6). Many authors have recommended ICP monitoring in FLF to guide management of cerebral edema (7,8) although this procedure entails significant hemorrhagic risk (9,10).

The pathogenesis of cerebral edema in FLF is likely multifactorial, but substantial evidence supports a causal role for hyperammonemia. Elevated ammonia levels alter neurotransmitter synthesis, and interfere with mitochondrial function causing oxidative stress and neuronal apoptosis (4,5,6,11-16). Increased delivery of ammonia to astrocytes provides substrate for the accumulation of intracellular glutamine (17-18). The resulting osmotic effect causes astrocyte swelling and cerebral edema (6,7,19). Clinical studies have repeatedly shown that arterial ammonia levels around 150 mmol/L have a statistically significant association with the development of IHTN and cerebral edema in humans (8,20-22).

Clemmensen and colleagues (8) measured arterial ammonia levels at the onset of grade III encephalopathy in 44 patients with FLF. Fourteen of those patients subsequently developed cerebral herniation. The patients who developed cerebral herniation had significantly higher mean arterial ammonia levels (230 vs. 118 μmol/L P<0.001), and all had ammonia levels > 146 μmol/L. At this cut point, arterial ammonia had a sensitivity of 100%, a specificity of 73% and a PPV of 64% for the subsequent development of cerebral herniation (8).

The results of this study raised the possibility that arterial ammonia levels could be used to select FLF patients likely to benefit from ICP monitoring. If arterial ammonia levels above 146 μmol/L were highly sensitive for predicting the development of IHTN, patients with arterial ammonia levels below this threshold would not likely benefit from ICP monitoring, therefore the significant hemorrhagic risk of monitor placement could be avoided (20,23).

The primary aim of our study was to confirm this premise by reassessing the sensitivity of the arterial ammonia concentration for predicting the onset of intracranial hypertension (IHTN). We chose IHTN as our dependent variable since cerebral herniation is uncommonly seen in patients managed with our neuroprotective treatment protocol (24), and because intracranial hypertension can cause brain injury by compromising cerebral perfusion in the absence of herniation. The secondary aim of our study was to determine whether following serial arterial ammonia levels are valuable in predicting the timing of recurrent IHTN episodes before and after liver transplantation.

Methods

A prospective case series was approved by the Institutional Review Board at Banner Good Samaritan Regional Medical Center, a 650 bed community teaching hospital in Phoenix Arizona. The Transplant Hepatology service identified consecutive patients admitted with FLF, as defined by standard criteria (20) between May 2004 and September 2006. All patients underwent serial neurological examinations by an intensivist, and those who developed grade 3-4 encephalopathy were evaluated for study participation. Eligible patients’ families were asked to provide informed consent.

Serial arterial ammonia levels were obtained in study patients. An arterial catheter was placed and 5 cc of arterial blood was drawn into a sodium heparin-containing tube every 12 hours. These samples were transported to the chemistry laboratory on ice within 30 minutes. Quantitative plasma ammonia concentrations were performed using an enzymatic kinetic assay (Roche Diagnostics, Mannheim Germany). This assay has a reportable range of 5.87-587 mmol/L and a coefficient of variability of 2%.

An intraparenchymal ICP monitor (Codman MicroSensor^® - Codman/Johnson & Johnson Professional, Inc., Randolph, MA) was placed in the non-dominant frontal lobe under local anesthesia by a neurosurgeon. The ICP was monitored continuously thereafter. Hemostatic therapy and ICP management used in the study have been previously described (24). ICP monitors were removed post-transplantation when the patient could tolerate lowering of their head to zero degrees without precipitating IHTN. In patients who did not undergo transplantation, ICP monitors were removed upon clinical recovery or death.  

Our main independent variable was the arterial plasma ammonia level. Our main dependent variable was intracranial hypertension, defined as an ICP > 20 mmHg for > 20 mins.  We performed 3 separate sets of analyses to examine the relationship between arterial ammonia levels and IHTN: 1) we analyzed the arterial ammonia level that most closely preceded the onset of the first episode of IHTN in each patient; 2) we analyzed all arterial ammonia levels in relation to all episodes of IHTN; and 3) we analyzed all arterial ammonia levels in relation to all episodes of IHTN occurring post liver transplantation. The second and third analyses involved data values that were not independent of each other, therefore standard statistical techniques were not appropriate and time series analysis was performed. Statistical analyses were performed using SPSS 13.0 (SPSS Inc. Chicago IL.) Operating characteristics of arterial ammonia levels were calculated at a cut point of 150 mmol/L.  

Results

Twenty two patients were entered – their clinical characteristics at study entry are listed in Table 1.

Our 22 patients cumulatively underwent 3252 hours of ICP monitoring. Mean monitor duration was 147.8 +/- 143.3 hours. Monitors were left after liver transplantation in nine patients for 85.6 +/- 60.6 hours.

The prevalence of IHTN in our population was 95% (21/22 patients). Eighty-two discrete episodes of intracranial hypertension occurred. 62 occurred prior to, 4 during, and 16 after liver transplantation. The peak ICP during IHTN events was 33 +/- 13 mmHg (mean +/- S.D.) and the median duration was 60 minutes.

Relationship between arterial ammonia levels and the first episode of IHTN: The mean arterial ammonia level preceding the first intracranial hypertension event in each patient was 185 +/- 67 mmol/L (range: 96 – 337 mmol/L). The sensitivity of arterial ammonia levels to predict the onset of IHTN was 62% (95% CI: 40.8 to 79.3) at a cut point of 150 mmol/L. Arterial ammonia levels preceding the first intracranial hypertension event were less than 150 mmol/L in 8 of 21 patients (39%). We could not accurately calculate specificity or area under the receiver operator curve (AUROC) since only one patient did not develop IHTN.  

Relationship between arterial ammonia levels and all episodes of IHTN: The mean arterial ammonia levels just prior to each of the individual 82 episodes of IHTN were 122 +/- 80 mmol/L (range: 15 – 270 mmol/L). Fifty nine of 82 episodes of IHTN (73%) occurred when arterial ammonia levels were less than 150 mmol/L.

Relationship between arterial ammonia levels and all episodes of IHTN occurring post liver transplantation: Nine patients underwent liver transplantation. Seventy-nine ammonia levels were obtained post-liver transplantation in these patients. Four transplant recipients experienced 16 post-operative IHTN events. The mean arterial ammonia just prior to each of these events was 70 +/- 48 mmol/L (range: 15 – 161 mmol/L). The sensitivity of the arterial ammonia level preceding each IHTN event was 13% and the specificity was 100% at a cut point of 150 mmol/L. Arterial ammonia levels were statistically lower in post-transplant IHTN episodes than in pre-transplant episodes (P<0.001).

Discussion

Our study showed that almost all patients with grade III or IV encephalopathy secondary to fulminant liver failure will develop intracranial hypertension – this supports the possible benefit of intracranial pressure monitoring in all such patients regardless of arterial ammonia levels. Although the high prevalence of IHTN in our study population prevented us from calculating the specificity of arterial ammonia levels, sensitivity is the key characteristic of this test in terms of our research question. Our study shows that arterial ammonia levels > 150 mmol/L are not sensitive for subsequent development of IHTN, and therefore should not be used to identify a subset of patients unlikely to benefit from ICP monitoring.

Our study did not confirm the clinical utility of arterial ammonia levels in predicting neurological injury in patients with FLF, as suggested by Clemmensen et al (8). This could be because the clinical event of interest in the two studies differed – Clemmensen focused on cerebral herniation, and we measured IHTN directly. Cerebral herniation occurred in 14 of Clemmensens’ 44 patients, but it was not observed in our patients. Our study utilized a management protocol specifically designed to prevent cerebral herniation (24). It is unknown how many of our patients with IHTN would have gone on to herniate if IHTN had not been detected and aggressively treated.           

Several other studies have examined the predictive value of arterial ammonia levels for cerebral edema and IHTN in patients with acute liver failure. Bernal and colleagues studied 165 patients with acute liver failure and grade 3-4 encephalopathy and found that arterial ammonia on admission was higher in those who later developed IHTN (121 vs 109 mmol/L p<0.05 (20). However, the sensitivity of an ammonia cut-point of 150 mmol/L was only 40%, and the positive predictive value (probability that a patient with ammonia > 150 mmol/L would develop IHTN) was only 16%.   

Bhatia and colleagues studied 80 patients with ALF, 58 of whom had grade 3-4 encephalopathy (21). They calculated an optimal cut-point for arterial ammonia for predicting mortality was 124 mmol/L by ROC analysis. Patients with ammonia levels above this cutpoint had a higher frequency of cerebral edema (47% vs. 22% P=0.02). Sensitivity and positive predictive values can be calculated from data presented in their paper, and are 71% and 48% respectively.  

Our results confirm those of Bernal and Bhatia in that all 3 studies showed that the operating characteristics of the arterial ammonia test are insufficient for triaging ALF patients in regards to invasive ICP monitoring. But our study has several important differences. IHTN or cerebral edema was detected in only 29% of Bernal’s patients and 35% of Bhatia’s. Both studies relied heavily on physical examination to diagnose these outcomes despite evidence that it lacks the sensitivity to do so (1,3,25-27). Our study utilized the gold standard (ICP monitoring) in all our patients. We found a much higher prevalence of IHTN – 95% in patients with grade 3-4 encephalopathy. This high prevalence explains the higher positive predictive value in our study, and suggests that previous studies may have suffered from significant underdetection of IHTN and cerebral edema.

Our study is also unique in that we performed repeated measures of arterial ammonia. This was important in terms of our hypothesis that patients’ risk for IHTN might change over time in response to treatments such as lactulose, continuous renal replacement therapy, and liver transplantation. Unfortunately, we found that repeated measures of arterial ammonia were no more clinically useful than the single levels used in previous studies.

Our study has several important limitations. Our limited sample size produced wide confidence intervals about our estimation of sensitivity. Our study only included patients with advanced encephalopathy - it’s possible that arterial ammonia levels might demonstrate improved prognostic significance earlier in the course of FLF. We did not attempt to analyze the effect of cumulative ammonia exposure over time.

 Our findings, and those of previous investigators, suggest that other factors besides peak ammonia levels are important in the pathogenesis of FLF-induced cerebral edema. Two other proposed causative factors are pathological alterations in cerebral blood flow (28-32) and systemic inflammatory response (30,33-34). The interplay of all three factors may be critical to the pathogenesis of cerebral edema in FLF and this might explain why simple measurement of serum ammonia is not sufficient to predict IHTN.

   Further work is needed to elucidate the pathogenesis of IHTN in FLF and identify variables that predict which patients will develop this life-threatening complication. Until then, we suggest that all patients with grade 3 or 4 encephalopathy secondary to FLF are at high risk. Our study shows that arterial ammonia levels in these patients cannot be relied upon to accurately triage patients in regards to their risk for IHTN. Thus, it is not helpful in determining which patients might benefit from ICP monitoring, nor determining when ICP monitoring can safely be discontinued.

Conclusions

An arterial ammonia level of 150 mmol/L is poorly sensitive for determining which patients with ALF will develop IHTN and should not be used to determine which patients are likely to benefit from ICP monitoring. The prevalence of IHTN in FLF patients with grade 3-4 encephalopathy is so high that no other predictive test is likely to be of added value. Although arterial ammonia levels are correlated with episodes of IHTN, most individual IHTN episodes occur when arterial ammonia levels are < 150 mmol/L. After successful transplantation IHTN events can continue to occur even as ammonia levels enter the normal range.

References

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6. Blei AT, Olafsson S, Therrien G, Butterworth RF. Ammonia-induced brain edema and intracranial hypertension in rats after portacaval anastomosis. Hepatology. 1994;19:1437-44.

7. Takahashi H, Koehler RC, Brusilow SW, Traystman RJ. Inhibition of brain glutamine accumulation prevetns cerebral edema in hyperammonemic rats. Am J Physiol. 1991;261:H825-H829.

8. Clemmessen JO, Larsen FS, Kondrup J, Hansen BA, Ott P. Cerebral herniation in patient with acute liver failure is correlated with arterial ammonia concentration. Hepatology 1999;29:648-653.

9. Lee WM. Acute liver failure. N England J Med 1993; 329: 1862.

10. Blei AT, Olafsson S, Webster S, Levy R. Complications of intracranial pressure monitoring in fulminant hepatic failure. Lancet. 1993;341: 157-8.

11. Vaquero J, Chung C, Blei AT. Brain edema in acute liver failure. A window to the pathogenesis of hepatic encephalopathy. Annals of Hepatology. 2003;2:12-22.

12. Tofteng F, Jorgensen L, Hansen BA, Ott P, Koadrap J, Larsen FS. Cerebral microdialysis in patients with fulminant hepatic failure. Hepatology. 2002;36:1333-40.

13. Kosenko E, Felipo V, Montolia C, Grisolia S, Kaminsky Y. Effectos of acute hyperammonemia in vivo on oxidative metabolism in nonsynaptic rat brain mitochondria. Metabolic Brain Diseases. 1996;12:69-82.

14. Norenberg MD. Oxidative and nitrosative stress in ammonia neurotoxicity. Hepatology. 2003;37:245-8.

15. Vaquero J, Chung C, Cahill ME, Blei AT. Pathogenesis of hepatic encephalopathy in acute liver failure. Seminars in liver disease. 2003;23:259-69.

16. Widmer R, Kaiser B, Engels M, Jung T, Grune T. Hyperammonemia causes protein oxidation and enhanced proteasomal activity in response to mitochondria-mediated oxidative stress in rat primary astrocytes. Arch Biochem Biophys. 2007;464:1-11.

17. Swain M, Butterworth RF, Blei AT. Ammonia and related amino acids in the pathogenesis of brain edema in acute ischemic liver failure in rats. Hepatology. 1992;15:449-53.

18. Cordoba J, Gottstein J, Blei AT. Glutamine, myo-inositol, and organic osmolytes after portocaval anastomosis in the rat: Implications for ammonia-induced brain edema. Hepatology. 1996;24:919-23.

19. Tofteng F, Hauerberg J, Hansen BA, Pedersen CB, Jorgensin L, Larsen FS. Persistant arterial hyperammonemia increases the concentration of glutamine and alanine in the brain and correlates with intracranial pressure in patients with fulminant hepatic failure. J Cereb Bood Flow Metab. 2006;26:21-7..

20. Bernal W, Hall C, Karvellas CJ, Auzinger G, Sizer E, Wendon J. Arterial ammonia and clinical risk factors for encephalopathy and intracranial hypertension in acute liver failure. Hepatology. 2007;46:1844-52.

21. Bhatia V, Singh R, Acharya SK. Predictive value of arterial ammonia for complications and outcome in acute liver failure. Gut. 2006;55:98-104.

22. Kundra A, Jain A, Banga A, Bajaj G, Kar P. Evaluation of plasma ammonia levels in patients with acute liver failure and chronic liver disease and its correlation with the severity of hepatic encephalopathy and clinical features of raised intracranial tension. Clin Biochem. 2005;38:696-9.

23. Bass NM. Monitoring and treatment of intracranial hypertension. Liver Transplantation 2000; 6(4. Supp1:S21-S26

23. Davern TJ. Predicting prognosis in acute liver failure: Ammonia and the risk of cerebral edema. Hepatology. 2007;46:1679-81.

24. Raschke RA, Curry SC, Rempe S, Gerkin R, Little E, Manch R, Wong M, Ramos A, Leibowitz AI. Results of a Protocol for the Management of Patients with Fulminant Liver Failure. Critical Care Medicine. 2008;36:2244-8.

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26. Canalese J, Gimson AES, Davis C, Mellon PJ, Davis M, Williams R. Controlled trial of dexamethasone and mannitol for the cerebral oedema of fulminant hepatic failure. Gut 1982;23:625-9.

27. Brajtbord D, Parks RI, Ramsay MA, Paulsen AW, Valek TR, Swygert TH, Klintmalm GB. Management of acute elevation of intracranial pressure during hepatic transplantation. Anesthesiology. 1989;70:139-141.

28. Wendon JA, Harrison PM, Keays R, Williams R. Cerebral blood flow and metabolism in fulminant liver failure. Hepatology. 1994;19:1407-13.

29. Sari A, Yamashita S, Ohosita S, Ogasahara H, Yamada K, Yonei A, Yokota K. Cerebrovascular reactivity to CO₂ in patients with hepatic or septic encephalopathy. Resuscitation. 1990;19:125-34

30. Jalan r, Olde Damink SWM, Hayes PC, Deutz NEP, Lee A. Pathogenesis of intracranial hypertension in acute liver failure: Inflammation, ammonia and cerebral blood flow. Journal of Hepatology. 2004;41:613-20.

31. Kramer D, Aggarwal M, Darby J, Obrist W, Rosenbloom A, Murray G, Linden P, et al. Management options in fulminant hepatic failure. Transplant Proc. 1991;23:1895-8.

32. Jalan R, Olde Damink SWM, Deutz NEP, Hayes PC, Lee A. Restoration of cerebral blood flow autoregulation and reactivity to carbon dioxide in acute liver failure by moderate hypothermia. Hepatology. 2001;34:50-4.

33. Rolando N, Wade J, Davalos M, Wendon J, Philpott-Howard J, Williams R. The systemic inflammatory response syndrome in acute liver failure. Hepatology. 2000;32:734-9

34. Vaquero J, Polson J, Chung C, Helenowski I, Schiodt FV, Reisch J, Lee W, Blei AT, and the U.S. Acute Liver Failure Study Group. Infection and the progression of hepatic encephalopathy in acute liver failure. Gastroenterology.2003;125:755-64.     

Clement U. Singarajah

 Tyler Glenn

Richard A. Robbins

Phoenix VA Medical Center, Phoenix, AZ

Reference as: Singarajah CU, Glenn T, Robbins RA. Right pleural insertion of a small bore feeding tube. Southwest J Pulm Crit Care 2011;2:71-6. (Click here for PDF version)

Abstract

We report a case of a 56 year old man who had a feeding tube inadvertently malpositioned into the right pleural space and had approximately 600 ml of tube feedings infused. After the malposition was recognized, the patient underwent chest tube placement, followed by video assisted thoracic surgery 5 days later. He made an uneventful recovery. The case illustrates the problems with identification and treating feeding tube insertion into the lung.  

Case Presentation

History of Present Illness

A 56 year old male was transferred from another hospital where he had been admitted 9 days earlier for severe community acquired pneumonia secondary to penicillin sensitive Streptococcus pneumoniae, respiratory failure and sepsis syndrome. He had a past medical history of morbid obesity, type 2 diabetes mellitus, hepatitis C, hypertension and had received a pneumococcal vaccination 8 years earlier. His course was complicated by prolonged mechanical ventilation, hypotension resulting in oliguric acute renal failure and atrial fibrillation with a fast ventricular response requiring cardioversion. He had sufficiently improved with antibiotics, hemodialysis and supportive therapy that he was able to be transferred to our hospital. He had a prolonged but uncomplicated course in our intensive care unit (ICU). He was initially unable to be weaned from mechanical ventilation and underwent tracheostomy but was eventually able to tolerate tracheostomy collar and intermittent use of a tracheostomy tube with a speaking valve. He was noted to be intermittently confused and agitated. After 17 days in our ICU, transfer was planned to a general medical floor.  However, prior to leaving our ICU he pulled his feeding tube and another small bore feeding tube was inserted. An abdominal film was performed and he was transferred to the medical floor. After transfer he complained through the night of chest pain and shortness of breath and required increasing inspired oxygen concentrations in order to maintain adequate oxygen saturation. .

Physical Examination

Physical examination was not markedly changed from the previous day. He had a tachycardia of 110, blood pressure of 139/97, respirations of 24, temperature of 36.3 degrees C and weight of 140.6 kilograms. He was not oriented to time or place and seemed to be in moderate discomfort. Pertinent findings including a small bore feeding tube in his left nostril, a tracheotomy in place and rhonchi over both lungs. Abdomen was protuberant but soft and there was no presacral or pretibial edema.

Laboratory Findings

Pertinent laboratory findings included arterial blood gases showing a pH of 7.44, pCO2 of 32 mm Hg, and pO2 of 65.3 on a FiO2 of 0.7. Blood glucose was elevated at 275 and his white blood cell count had increased from 6000/microL on the day of transfer to the floor to 11,400/microL with a left shift.

Radiography

Initial abdominal films are show in figure 1.

Figure 1. Panel A and B are abdominal x-rays taken for feeding tube placement. Panel A shows the feeding tube below the diaphragm indicated by the arrow. Panel B, labeled at the same time and with the same acquisition number does not show the tube below the diaphragm but shows a tube apparently in the right chest. Panel C is an inverted image of Panel B.

A chest X-ray was taken on the patient’s return to the intensive care unit (Figure 2).

Figure 2. A. Chest X-ray shows feeding tube in trachea and right mainstem bronchus, looping in lower right chest and extending to upper right chest (arrows). B. Inverted image of A.

Hospital Course

Because of his high oxygen requirements and dyspnea, the patient was placed on mechanical ventilation. Bronchoscopy confirmed that the tube was in the lung. Due to concern for a pneumothorax should the tube be removed, a chest tube was placed first and directed to drain the pleural effusion. The feeding tube was removed and a follow up chest x-ray confirmed a pneumothorax that was treated with another chest tube. It was estimated that about 600 ml of feeding formula had been infused into the chest. Approximately 700 ml of milky fluid consistent with feeding was collected by the thoracostomy tube. Thoracic surgery consultation was obtained and recommended video-assisted thoracic surgery which was performed 5 days latter. A small amount of what appeared to be feeding formula was removed. He made a slow and uneventful recovery and was discharged to an extended care facility after a total duration of 43 days in our hospital.

Discussion

Malposition of feeding tubes is relatively common (1,2). Given that the tubes are small, relatively flexible and blindly inserted this is not surprising. In a series of more than 2000 insertions, Sorokin and Gottlieb (1) reported a 2.4% rate of lung insertion while de Aguilar-Nascimento and Kudsk (2) found a 3.2% incidence of lung malposition. Most malpositions occurred in the intensive care unit with 95% of the patients having an abnormal mental status and more than half with an endotracheal tube. Therefore, our patient was typical of the patient prone for feeding tube malposition.

To prevent feeding tube malposition, many hospitals insert the tubes under fluoroscopic guidance (3). Perhaps more commonly, other hospitals require radiographic confirmation before beginning feeding (1,2) . The later is the policy at our hospital, but as this case illustrates, mishaps can occur even with this safeguard.

In our case, several errors were made leading to the adverse event. Although recorded at the same time, the initial abdominal films were actually taken at different times. The patient had pulled his first feeding tube and a second tube had been inserted by the ICU nurse into the lung. The medicine house officer who read the films was not informed that two films were taken and saw the tube below the diaphragm on the first film. The house officer missed the tube in the chest on the second film. However, on this and three subsequent films, all read by separate radiologists, the tube malposition was also not identified. It can be difficult with multiple densities, from chest cardiac leads, suction tubing, intravenous tubing, etc. to identify potentially misplaced feeding tubes.

Generally, feeding tube malposition is reasonably well tolerated although aspiration and pneumothorax may result (1-3). Removal of the tube usually results in little apparent clinical harm. Our case is unusual in that an enteral feeding formula was introduced into the pleural space. Although there are previous reports of pneumothorax complication feeding tube insertion, these are relatively uncommon and we were uncertain how to proceed (4).  Eventually we decided on video assisted thoracic surgery with removal of any residual fluid. In this case the patient made an uneventful but prolonged recovery.  

When a feeding tube is in the lung, it may or may not have punctured the pleura. If it has, as was clear in this case by the course it took, (multiple loops), the chance of a pneumothorax on removal may be high. It is a matter of opinion as to whether or not in this situation; a prophylactic chest tube should be placed prior to removal of the feeding tube. In this case, this was performed as he was on mechanical ventilation. In situations where the feeding tube is clearly in a mainstem bronchus, removal is probably safe without due concern for a pneumothorax.

The errors in the formal radiology readings may be reduced by inverting the images within the radiology viewing program, and making sure that the full course of the feeding tube from oropharynx to tip is noted. In some obese patients, such as this one, an abdominal x-ray and chest x-ray may be required to do this.

References

1. Sorokin R, Gottlieb JE. Enhancing patient safety during feeding-tube insertion: a review of more than 2,000 insertions. JPEN J Parenter Enteral Nutr 2006;30:440-5.

2. de Aguilar-Nascimento JE, Kudsk KA. Clinical costs of feeding tube placement. JPEN J Parenter Enteral Nutr 2007;31:269-73.

3. Huerta G, Puri VK. Nasoenteric feeding tubes in critically ill patients (fluoroscopy versus blind). Nutrition 2000;16:264-7.

4. Wendell GD, Lenchner GS, Promisloff RA. Pneumothorax complicating small-bore feeding tube placement . Arch Intern Med 1991;151:599-602.