When Should You Hold Tube Feeding With Refeeding Syndrome
BMJ. 2008 Jun 28; 336(7659): 1495–1498.
Refeeding syndrome: what it is, and how to prevent and treat it
Hisham M Mehanna
1Institute of Head and Neck Studies and Education, Department of Otorhinolaryngology—Head and Neck Surgery, University Hospital, Coventry CV2 2DX
2Heart of England Foundation Trust, Birmingham
Jamil Moledina
3Department of Otorhinolaryngology—Head and Neck Surgery, University Hospital, Coventry
Jane Travis
4Department of Dietetics, University Hospital, Coventry
- Supplementary Materials
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GUID: 908274A2-C956-434C-8A97-7880F5E9F82E
GUID: B6B74A21-7E93-442E-AB60-54C6AC66A783
Refeeding syndrome is a well described but often forgotten condition. No randomised controlled trials of treatment have been published, although there are guidelines that use best available evidence for managing the condition. In 2006 a guideline was published by the National Institute for Health and Clinical Excellence (NICE) in England and Wales. Yet because clinicians are often not aware of the problem, refeeding syndrome still occurs.1
This review aims to raise awareness of refeeding syndrome and discuss prevention and treatment. The available literature mostly comprises weaker (level 3 and 4) evidence, including cohort studies, case series, and consensus expert opinion.2 Our article also draws attention to the NICE guidelines on nutritional support in adults, with particular reference to the new recommendations for best practice in refeeding syndrome.3 These recommendations differ in parts from—and we believe improve on—previous guidelines, such as those of the Parenteral and Enteral Nutrition Group of the British Dietetic Association (box 1).4
What is refeeding syndrome?
Refeeding syndrome can be defined as the potentially fatal shifts in fluids and electrolytes that may occur in malnourished patients receiving artificial refeeding (whether enterally or parenterally5). These shifts result from hormonal and metabolic changes and may cause serious clinical complications. The hallmark biochemical feature of refeeding syndrome is hypophosphataemia. However, the syndrome is complex and may also feature abnormal sodium and fluid balance; changes in glucose, protein, and fat metabolism; thiamine deficiency; hypokalaemia; and hypomagnesaemia.1 6
How common is refeeding syndrome?
The true incidence of refeeding syndrome is unknown—partly owing to the lack of a universally accepted definition. In a study of 10 197 hospitalised patients the incidence of severe hypophosphataemia was 0.43%, with malnutrition being one of the strongest risk factors.7 Studies report a 100% incidence of hypophosphataemia in patients receiving total parenteral nutrition solutions that do not contain phosphorus. When solutions containing phosphate are used, the incidence can decrease to 18%.8
Several prospective and retrospective cohort studies of hyperalimentation in intensive care units have documented the occurrence of refeeding syndrome.6 9 In a well designed prospective cohort study of a heterogeneous group of patients in intensive care units, 34% of patients experienced hypophosphataemia soon after feeding was started (mean (standard deviation) 1.9 (1.1) days).10 Many case reports have highlighted the potentially fatal nature of the condition.11 12 However, it is often not recognised or maybe inappropriately treated, especially on general wards.1 6
How does refeeding syndrome develop?
Prolonged fasting
The underlying causative factor of refeeding syndrome is the metabolic and hormonal changes caused by rapid refeeding, whether enteral or parenteral. The net result of metabolic and hormonal changes in early starvation is that the body switches from using carbohydrate to using fat and protein as the main source of energy, and the basal metabolic rate decreases by as much as 20-25%.13
During prolonged fasting, hormonal and metabolic changes are aimed at preventing protein and muscle breakdown. Muscle and other tissues decrease their use of ketone bodies and use fatty acids as the main energy source. This results in an increase in blood levels of ketone bodies, stimulating the brain to switch from glucose to ketone bodies as its main energy source. The liver decreases its rate of gluconeogenesis, thus preserving muscle protein. During the period of prolonged starvation, several intracellular minerals become severely depleted. However, serum concentrations of these minerals (including phosphate) may remain normal. This is because these minerals are mainly in the intracellular compartment, which contracts during starvation. In addition, there is a reduction in renal excretion.
Refeeding
During refeeding, glycaemia leads to increased insulin and decreased secretion of glucagon. Insulin stimulates glycogen, fat, and protein synthesis. This process requires minerals such as phosphate and magnesium and cofactors such as thiamine. Insulin stimulates the absorption of potassium into the cells through the sodium-potassium ATPase symporter, which also transports glucose into the cells. Magnesium and phosphate are also taken up into the cells. Water follows by osmosis. These processes result in a decrease in the serum levels of phosphate, potassium, and magnesium, all of which are already depleted. The clinical features of the refeeding syndrome occur as a result of the functional deficits of these electrolytes and the rapid change in basal metabolic rate.
What electrolytes and minerals are involved in the pathogenesis?
Phosphorus
Phosphorus is predominantly an intracellular mineral. It is essential for all intracellular processes and for the structural integrity of cell membranes. In addition, many enzymes and second messengers are activated by phosphate binding. Importantly it is also required for energy storage in the form of adenosine triphosphate (ATP). It regulates the affinity of haemoglobin for oxygen and thus regulates oxygen delivery to tissues. It is also important in the renal acid-base buffer system.
In refeeding syndrome, chronic whole body depletion of phosphorus occurs. Also, the insulin surge causes a greatly increased uptake and use of phosphate in the cells. These changes lead to a deficit in intracellular as well as extracellular phosphorus. In this environment, even small decreases in serum phosphorus may lead to widespread dysfunction of cellular processes affecting almost every physiological system (see box A on bmj.com).14
Potassium
Potassium, the major intracellular cation, is also depleted in undernutrition. Again, serum concentration may remain normal. With the change to anabolism on refeeding, potassium is taken up into cells as they increase in volume and number and as a direct result of insulin secretion. This results in severe hypokalaemia. This causes derangements in the electrochemical membrane potential, resulting in, for example, arrhythmias and cardiac arrest.
Magnesium
Magnesium, another predominantly intracellular cation, is an important cofactor in most enzyme systems, including oxidative phosphorylation and ATP production. It is also necessary for the structural integrity of DNA, RNA, and ribosomes. In addition, it affects membrane potential, and deficiency can lead to cardiac dysfunction and neuromuscular complications.18
Glucose
Glucose intake after a period of starvation suppresses gluconeogenesis through the release of insulin. Excessive administration may therefore lead to hyperglycaemia and its sequelae of osmotic diuresis, dehydration, metabolic acidosis, and ketoacidosis. Excess glucose also leads to lipogenesis (again as a result of insulin stimulation), which may cause fatty liver, increased carbon dioxide production, hypercapnoea, and respiratory failure.15
Vitamin deficiency
Although all vitamin deficiencies may occur at variable rates with inadequate intake, thiamine is of most importance in complications of refeeding. Thiamine is an essential coenzyme in carbohydrate metabolism. Its deficiency result in Wernicke's encephalopathy (ocular abnormalities, ataxia, confusional state, hypothermia, coma) or Korsakoff's syndrome (retrograde and anterograde amnesia, confabulation).19
Sodium, nitrogen, and fluid
Changes in carbohydrate metabolism have a profound effect on sodium and water balance. The introduction of carbohydrate to a diet leads to a rapid decrease in renal excretion of sodium and water.20 If fluid repletion is then instituted to maintain a normal urine output, patients may rapidly develop fluid overload. This can lead to congestive cardiac failure, pulmonary oedema, and cardiac arrhythmia.
How can refeeding syndrome be prevented?
Identification of high risk patients is crucial (boxes 2 and 3).3 4 Any patient with negligible food intake for more than five days is at risk of developing refeeding problems. Patients may be malnourished as a result of reduced intake (for example, owing to dysphagia, anorexia nervosa, depression, alcoholism); reduced absorption of nutrition (as in, for example, inflammatory bowel disease, coeliac disease); or increased metabolic demands (for example, in cancer, surgery). High risk patients include those who have been chronically undernourished, especially those who also have diminished physiological reserve. Patients with dysphagia (for example, as a result of stroke) in particular may be at high risk.
The figure summarises how to prevent and treat refeeding syndrome. To ensure adequate prevention, the NICE guidelines recommend a thorough nutritional assessment before refeeding is started.3 Recent weight change over time, nutrition, alcohol intake, and social and psychological problems should all be ascertained. Plasma electrolytes (especially phosphate, sodium, potassium, and magnesium) and glucose should be measured at baseline before feeding and any deficiencies corrected during feeding with close monitoring.3
The NICE guidelines recommend that refeeding is started at no more than 50% of energy requirements in "patients who have eaten little or nothing for more than 5 days." The rate can then be increased if no refeeding problems are detected on clinical and biochemical monitoring (level D recommendation—see box 3).
For patients at high risk of developing refeeding syndrome, nutritional repletion of energy should be started slowly (maximum 0.042 MJ/kg/24 hours) and should be tailored to each patient. It can then be increased to meet or exceed full needs over four to seven days. In patients who are very malnourished (body mass index ≤14 or a negligible intake for two weeks or more), the NICE guidelines recommend that refeeding should start at a maximum of 0.021 MJ/kg/24 hours, with cardiac monitoring owing to the risk of cardiac arrhythmias (level D recommendation).3 This explicit specification of the rate of refeeding in severely malnourished patients should help avoid complications arising from rapid refeeding and is an improvement on previous guidelines.4 The NICE guidelines also state that correcting electrolyte and fluid imbalances before feeding is not necessary and that this should be done along with feeding. This is a change from previous guidelines4 and potentially avoids prolongation of malnourishment and its effects on patients.
All guidelines recommend that vitamin supplementation should be started immediately, before and for the first 10 days of refeeding. Circulatory volume should also be restored. Oral, enteral, or intravenous supplements of the potassium, phosphate, calcium, and magnesium should be given unless blood levels are high before refeeding. Good quality studies on the exact levels of supplementation are lacking, however, and so the required levels of these supplements cited by NICE (figure ) are only level D recommendations.3
Electrolyte levels should be measured once daily for one week, and at least three times in the following week. Urinary electrolytes could also be checked to help assess body losses and to guide replacement.
How can refeeding syndrome be detected and treated?
Refeeding syndrome is detected by considering the possibility of its existence and by using the simple biochemical investigations described above. If the syndrome is detected, the rate of feeding should be slowed down and essential electrolytes should be replenished. The hospital specialist dietetics team should be involved.
The best method for electrolyte repletion has not yet been determined. Hypophosphataemia, hypomagnesaemia, and hypokalaemia in hospitalised patients are ideally treated with intravenous supplementation (table ), but this is not without risks. A prospective comparative cohort study of 27 patients with severe hypophosphataemia showed the safety of administering 15-30 mmol phosphate over three hours via a central venous catheter in an intensive care unit.16 However, the researchers reported the need for repeated doses in most patients. Terlevich et al reported efficacy of 50 mmol phosphate infused into a peripheral vein over 24 hours in 30 patients with no pre-existing renal dysfunction on general wards.17 Further infusions may be required and so careful monitoring of blood levels is required. Caution is needed in patients with existing renal impairment, hypocalcaemia (which may worsen), or hypercalcaemia (which may result in metastatic calcification).
Mineral | Dose |
---|---|
Phosphate | |
Maintenance requirement | 0.3-0.6 mmol/kg/day orally |
Mild hypophosphataemia (0.6-0.85 mmol/l) | 0.3-0.6 mmol/kg/day orally |
Moderate hypophosphataemia (0.3-0.6 mmol/l) | 9 mmol infused into peripheral vein over 12 hours |
Severe hypophosphataemia (<0.3 mmol/l) | 18 mmol infused into peripheral vein over 12 hours |
Magnesium | |
Maintenance requirement | 0.2 mmol/kg/day intravenously (or 0.4 mmol/kg/day orally ) |
Mild to moderate hypomagnesaemia (0.5-0.7 mmol/l) | Initially 0.5 mmol/kg/day over 24 hours intravenously, then 0.25 mmol/kg/day for 5 days intravenously |
Severe hypomagnesaemia (<0.5 mmol/l) | 24 mmol over 6 hours intravenously, then as for mild to moderate hypomagnesaemia (above) |
Fluid repletion should be carefully controlled to avoid fluid overload as described earlier. Sodium administration should be limited to the replacement of losses. In patients at high risk of cardiac decompensation, central venous pressure and cardiac rhythm monitoring should be considered.
Conclusion
Adherence to the NICE guidelines for preventing and treating refeeding syndrome (boxes 2 and 3) should reduce the incidence and associated complications of the syndrome. Further research is needed to determine the true incidence of refeeding syndrome and to ascertain the best management protocols.
Supplementary Material
[extra: Web extra: Box A]
Notes
A web extra box (box A) about the complications of refeeding syndrome and their underlying mechanisms is on bmj.com
Notes
We thank Chuka Nwokolo (Department of Gastroenterology, University Hospital, Coventry) for his efforts and comments in reviewing this article.
Contributors: HMM planned the article, did the searches, evaluated the evidence, and wrote and reviewed the manuscript; he is also the guarantor. JM did the searches, evaluated the evidence, and helped with writing the article. JT did the searches, evaluated the evidence, and reviewed the manuscript.
Competing interests: None declared.
Provenance and peer review: Commissioned; externally peer reviewed.
*Recommendations derived from low grade evidence—mainly cohort and case series studies—and from consensus expert opinion
Footnotes
*Recommendations derived from low grade evidence—mainly cohort and case series studies—and from consensus expert opinion
References
3. National Institute for Health and Clinical Excellence. Nutrition support in adults Clinical guideline CG32. 2006. www.nice.org.uk/page.aspx?o=cg032
4. Dewar H, Horvath R. Refeeding syndrome. In: Todorovic VE, Micklewright A, eds. A pocket guide to clinical nutrition 2nd ed. British Dietetic Association, 2001
5. Solomon SM, Kirby DF. The refeeding syndrome: a review. JPEN J Parenter Enteral Nutr 1990;14:90-7. [PubMed] [Google Scholar]
6. Crook MA, Hally V, Pantelli JV. The importance of the refeeding syndrome. Nutrition 2001;17:632-7. [PubMed] [Google Scholar]
7. Camp MA, Allon M. Severe hypophosphatemia in hospitalised patients. Mineral & Electrolyte Metabolism 1990;16:365-8. [PubMed] [Google Scholar]
8. Martinez MJ, Matrinez MA, Montero M, Campelo E, Castro I, Inaraja MT. Hypophosphatemia in postoperative patients on total parenteral nutrition:influence of nutritional support teams. Nutr Hosp 2006;21:657-60. [PubMed] [Google Scholar]
9. Hayek ME, Eisenberg PG. Severe hypophosphatemia following the institution of enteral feedings. Arch Surg 1989;124:1325-8. [PubMed] [Google Scholar]
10. Marik PE, Bedigan MK. Refeeding hypophosphataemia in an intensive care unit: a prospective study. Arch Surg 1996;131:1043-7. [PubMed] [Google Scholar]
11. Silvis SE, Paragas PD. Parasthesias, weakness, seizures, and hypophosphatemia in patients receiving hyperalimentation. Gastroenterology 1972;62:513-20. [PubMed] [Google Scholar]
12. Weinsier RL, Krumdieck CL. Death resulting from overzealous total parenteral nutrition: the refeeding syndrome revisited. Am J Clin Nutr 1980;34:393-9. [PubMed] [Google Scholar]
13. McCray S, Walker S, Parrish CR. Much ado about refeeding. Practical Gastroenterology 2004;XXVIII(12):26-44.
14. Knochel JP. The pathophysiology and clinical charactertistics of severe hypophosphatemia. Arch Intern Med 1977;137:203-20. [PubMed] [Google Scholar]
15. Klein CJ, Stanek GS, Wiles CE. Overfeeding macronutrients to critically ill adults: metabolic complications. J Am Diet Assoc 1998;98:795-806. [PubMed] [Google Scholar]
16. Perrault MM, Ostrop NJ, Tierney MG. Efficacy and safety of intravenous phosphate replacement in critically ill patients. Ann Pharmacother 1997;31:683-8. [PubMed] [Google Scholar]
17. Terlevich A, Hearing SD, Woltersdorf WW, Smyth C, Reid D, Mccullagh E, et al. Refeeding syndrome: effective and safe treatment with Phosphates Polyfusor. Aliment Pharmacol Ther 2003;17:1325-9. [PubMed] [Google Scholar]
18. Wacker WEC, Parisi AF. Magnesium metabolism. N Engl J Med 1968;278:658-63. [PubMed] [Google Scholar]
19. Reuler JB, Girard DE, Cooney TG. Wernicke's encephalopathy. N Engl J Med 1985;312:1035-9. [PubMed] [Google Scholar]
20. Veverbrants E, Arky RA. Effects of fasting and refeeding: I. Studies on sodium, potassium and water excretion on a constant electrolyte and fluid intake. J Clin Endocrinol Metab 1969;29:55-62. [PubMed] [Google Scholar]
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Source: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2440847/
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