Malnutrition, Starvation and Refeeding Syndrome Khursheed Jeejeebhoy
Starvation and Semi-starvation State of Negative Protein-Energy Balance –Absence of nutrient intake –Intake below requirements
Metabolic Adaptation to Starvation Post Absorptive state --- Overnight fast after a meal Fast lasting Hours Fast lasting > 3days Prolonged Starvation
Post-Absorptive State The Brain Must receive Glucose Insulin levels fall: Glucose delivery to Tissues 8-10 g/hr –Increased Glycogenolysis 50% –Continued Gluconeogensis 50% Lactate and Pyruvate 50% Amino acids 50% Muscle uses mainly fatty acids –2/3 fuel oxidation is derived from fatty acids
Fasting ~ 2-4 days Liver glycogen depleted Insulin levels fall Glucose production by Gluconeogenesis: –Lactate and Pyruvate –Amino acids Nitrogen loss from amino acid is g/day Branched chain aminoacids released by muscle and oxidized Ketone production increases Brain reduces glucose utilization and increases Ketone body oxidation
Prolonged Starvation Metabolic rate falls Nitrogen losses decrease to 4-5 g/day Brain now uses ketones as the sole source of energy Muscle uses fatty acid and spares branched-chain amino acid oxidation
Clinical Effects of Starvation Resting Energy Expenditure fall by about 25-35% by 3 weeks Serum Albumin Concentrations remain normal Serum Prealbumin falls Death occurs when body fat is depleted Obese persons can withstand prolonged starvation
Clinical effects of Fasting: Weight loss
Weight and Sodium loss Fall in insulin level reduces sodium reabsorption by the kidney –Increased sodium excretion –Diuresis Reduced sodium intake increases negative sodium balance Water loss main cause of rapid weight loss seen early in starvation
Malnutrition Malnutrition is a condition in which there is unbalanced deficiency of nutrients. Causes are: –Macronutrient deficiency Protein-energy malnutrition Protein deficiency Energy deficiency –Micronutrient deficiency Electrolyte –Potassium –Magnesium –Phosphorus Trace element –Zinc –Copper –Chromium –Selenium Vitamin Deficiency –Fat soluble - Vitamin D –Water soluble - Thiamine
Protein-Energy Malnutrition Reduced intake of both Protein and energy volunteers reduced their intake from 2400 kcals/d to 1600 kcals/day (Keys Minnesota study) Lost 70% body fat and 24% FFM New equilibrium at 24 weeks into the diet.
PEM: Nitrogen adaptation Martin and Robison 1922 Neg N balance Pos. N balance
Nitrogen Adaptation Loss of labile nitrogen pool reduces nitrogen output Equilibrium restored unless protein intake fall below < 37 mg/Kg/day on a diet meeting energy requirements
Energy Adaptation Body reduces energy requirements by: –Reduced metabolic rate of the body cell mass. –Reduced body cell mass. Body weight equilibrates approximately at: –28-30 kcal/kg/day
Hormonal response Insulin levels fall promoting release of glucose and free fatty acids for energy T3 levels reduced resulting in a lower metabolic rate IGF -1 levels fall with starvation reducing protein synthesis
Hypoproteinemia Low prealbumin levels can be due to: –Protein deficiency –Protein loss –Acute Phase reaction Low Albumin levels are: –?Low protein with high energy intake –Protein loss –Acute Phase reaction Hypoalbuminemia is a sign of disease not malnutrition
Micronutrient deficiency Iron deficiency: –Blood loss due to disease –Dietary deficiency intake of cereal iron (India) Magnesium Deficiency –Dietary – Alcoholism –Renal –Endocrine metabolic –Malabsorption –Short Bowel –Iatrogenic Phosphorus deficiency – –Iatrogenic – –Alcoholism – –Recovery from diabetic ketoacidosis Zinc Deficiency –Iatrogenic –Gastrointestinal losses Copper Deficiency –Infants recovering from malnutrition –Iatrogenic Vitamin D deficiency –Dietary –Malabsorption –Lack of sun exposure
Micronutrient deficiency Vitamin A deficiency –Dietary deficiency in developing countries –Iatrogenic Thiamine deficiency –Alcoholism –Iatrogenic –Diuretics Folate deficiency –Alcoholism –Malabsorption Vitamin B12 Deficiency –Vegans –Malabsorption –Poor intake in an ageing population
Refeeding Syndrome Refeeding a malnourished patient results in: –Rise of insulin levels Sodium and water retention Potassium retention Phosphorus retention Magnesium retention Refeeding may cause serious: –Hypokalemia –Hypophosphatemia
Refeeding Syndrome Refeeding a malnourished patient can result in Heart failure due to: –Atrophic myocardium in malnutrition –Muscle depletion of Mg, K, P –Sodium and water overload –Increased metabolic rate
REFEEDING EDEMA: CARDIAC FAILURE 36 year old Anorexia fed by NG 3200 kcal/d
Micronutrient Deficiencies In Malnutrition and the Heart MICRONUTRIENTSYNDROME Thiamine deficiency Heart Failure Magnesium Deficiency Arrhythmias Phosphorus Deficiency Cardiomyopathy Selenium Deficiency Cardiomyopathy Potassium Deficiency Arrhythmias Myocardial injury
Refeeding Syndrome High CHO intake exacerbates the refeeding syndrome Low protein High energy diet causes fat gain but not lean tissue High protein diet can reduce nitrogen loss even if energy deficient Exercise important to regain muscle mass
Relationship of Protein and Energy to Nitrogen retention Energy intake kcal/d
Refeeding Syndrome Refeeding Syndrome Journal of Internal Medicine 2005; 257: 461–468 Case controlled study in Geriatric ward 325 had hypophosphatemia 326 normal plasma phosphorus levels
Refeeding Syndrome Refeeding Syndrome Journal of Internal Medicine 2005; 257: 461–468
Refeeding Syndrome Am J Clin Nutr 1979;32: Severely starved men fed: 27 g/day protein Kcal/d Weight gain –Increased Cholesterol –Albumin levels fell –Nitrogen balance 0 Protein intake increased to 100 g/day –Positive nitrogen balance –Rise in serum albumin
Refeeding Syndrome Am J Clin Nutr 1979;32: Refeeding of malnourished patients: –20 kcal/kg/day and g/protein/day –Low CHO and higher fat –Monitor K, P, Mg and weight gain –Diuretics if rquired –Gradually increase energy intake depending on response.