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Nutrition in the High-Risk Neonate

Nutrition in the High-Risk Neonate. Armanian Amir Mohammad , MD Neonatologist Assistant Professor of IsfahanFaculty of Medicine. Currently, nearly all hospitilised infants experience significant growth retardation during their stay in the NICU . (less than 1000 g).

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Nutrition in the High-Risk Neonate

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  1. Nutrition in the High-Risk Neonate ArmanianAmir Mohammad , MD Neonatologist Assistant Professor of IsfahanFaculty of Medicine

  2. Currently, nearly all hospitilised infants experience significant growth retardation during their stay in the NICU. (less than 1000 g)

  3. The fetus gains approximately at 16 weeks : 5 g/d at 21 weeks : 10 g/d at 29 weeks : 20 g/d at 37 weeks : 35 g/d

  4. ENERGY REQUIREMENTS Energy Balance • Energy balance = energy intake – (energy loss + storage). • Energy loss = energy expenditure + excretion of energy (containing substances in urine and feces). • If exogenous energy intake is less than expenditure, energy balance is negative, and body energy stores must be mobilized to meet ongoing needs.

  5. Resting metabolic rate (RMR) Preterm > term infants • Nutritional requirements Preterm > term infants In preterm infants receiving full enteral feeding, approximately 90% of energy intakeis absorbed.

  6. The energy required for thermoregulation and activity can be minimized by keeping the infant in a thermo neutral environment and limiting stimulation. Incubator

  7. The estimated RMR of infants with LBW is lowerimmediately after birth than later approximately 50 to 60 kcal/kg / day is needed to maintain weight.

  8. Because neonates sleep 80% to 90% of the time , the energy expended in physical activity is a smaller component of energy expenditure in neonates than in adults.

  9. If the preterm infant is growing at the same rate as the fetusduring the third trimester gaining approximately 15 g/kg/d. …then about 15% of the total energy intake is used for synthesis of new tissue.

  10. Most studies of enterally fed preterm infants receiving either human milkorformulareport ahigher rate of energy storageper gram of weight gain thanthat estimated for the fetus. • The total daily energy requirements for full-term infants increase sharply from fetal levels during the first 48 hours of life and continue to increase at a lower rate until the end of the second week of life, reaching to 100 - 120 kcal/kg per day.

  11. Preterm infants have limited total body energy stores, so providing adequate early energy resources is more crucial for preterm neonates than for full-term infants.

  12. ELBW : Higher weight-normalized nutrient intakes are necessary. • Prenatal growth rate and body composition also may influence postnatal nutritional requirements. • …have been shown, infants who are small for gestational age (SGA) may require more nutrient intake per kilogram of body weight than larger infants.

  13. Individual infants vary in their activity, in their ease of achieving basal energy expenditure at thermoneutrality, and in their efficiency of nutrient absorption.

  14. Enteral intakes of120 or 130 kcal/kg /day have been recommended, as this allows most infants with LBW to grow at 15 to 20 g/d—growth rates similar to those achieved in utero. • a target enteral energy intake of 130 to 140 kcal/kg per day may be reasonable for infants with extremely low birthweights(ELBW) .

  15. CARBOHYDRATE REQUIREMENTS • Lactoseis the predominant carbohydrate in human milk and supplies 40% to 50% of the caloric content. • Despite low lactase activities in premature infants, lactose is well tolerated by premature infants, and stable isotope data suggest efficient lactose digestion. • Most Premature infant formulasinclude Glucose polymers as a significant source of carbohydrate. • Glucose polymers have the advantage of increased caloric density without a rise in osmolality, and they may also enhance gastric emptying.

  16. PROTEIN REQUIREMENTS • The protein content and composition of human milk change throughout lactation: at birth : 2 g/dl to mature milk : 1 g/dl • Qualitativechangesalso occur during lactation, resulting in a whey-to-casein ratio of 80:20 at the beginning of lactation, changing to 55:45 in mature milk. • Indeed, whereas the levels of casein, α-lactalbumin, albumin, and lysozymeremain constant, the levels of secretory immunoglobulin A and lactoferrin decrease.

  17. For preterm infants with birthweights between 1200 and 1800gr, the protein requirement is somewhere between 2.7 and 3.5 g/kg/d. • Standard preterm formulas containing between 2.5 and 3 g of protein per 100 kcal can meet those requirements if fluid intake is not restricted. • Infants weighing less than 1200 g may require more protein.

  18. LIPID REQUIREMENTS • Fat provides the major source of energy for growing preterm infants. • Fatty acid absorption increases with decreasing chain length and with the degree of unsaturation, meaning that medium-chain triglycerides (MCTs) with chain lengths of 6 to 12 carbons are hydrolyzed more readily than long-chain triglycerides (LCTs), and that fatty acids with more double bonds are absorbed more efficiently.

  19. Standard commercial formulas for healthy term infants do not contain MCTs, and human milk typically contains 8% to 12% of fat as MCTs. • Unlike LCTs, MCTs are readily hydrolyzed in the gut, and the released fatty acids are transported across the gut barrier without the need for bile acids. • MCTs are then transported directly to the liver via the portal vein as nonesterified fatty acids. • In addition, MCTs can enter mitochondria and be oxidized without the need for carnitine-mediated transport through mitochondrial membranes.

  20. The total fat content of human milk increases postnatally. • the percentage of cholesterol & phospholipids , both of which reside primarily in the milk fat globule membrane, decreases; in addition, the total phospholipid content decreasesas lactation progresses.

  21. The milk fat content and nutritional value of human milk vary with time. • Its composition and energy content may vary in a pumping session and throughout lactation.

  22. Formula • Formula supplemented with docosahexaenoic acid (DHA) and arachidonic acid (AA) has produced positive changes in neurodevelopment measured in infancy in some studies. • A minimum fat contentof 4.4 g/ 100 kcal (40% of total energy) and a maximum of 6.4 g/ 100 kcal (57% of total energy) were recommended.

  23. Breast milk and even pooled breast milk cannot provide sufficient sodium, calcium, phosphorus, iron, vitamins B2, B6, C, D, and E, and folic acid to meet the needs of infants with VLBW. • Studies have shown that infants have higher rates of weight, length, and head circumference increases when fed fortified preterm human milk than those fed only mature human milk.

  24. ORAL VITAMIN REQUIREMENTS • Vitamins are organic compounds that are essential for metabolic reactions but are not synthesized by the body. • They are therefore needed in trace amounts from enteral or parenteralsources. • Higher amounts of select vitamins are required by preterm infants, because they may have greater needs .

  25. Water-soluble vitamins (C , B ): Cannot be formed by precursors and do not accumulate in the body (with the exception of vitamin B12). Therefore, daily intake is required to prevent deficiency. • Fat-soluble vitamins (K,E,D,A) : They are important for the development and function of highly specialized tissues. They can be built from precursors, are excreted with difficulty, and accumulate in the body, and therefore they can produce toxicity. They are not required daily, and deficiency states develop slowly.

  26. Vit. A : Higher intakes(1400 U/Kg) are considered safe and may promote regenerative healing from lung injury, possibly reducing the incidence and severity of CLD . • Vit. D : 400 IU/d appears to be adequate for preterm infants. • Vit. E : The recommended total intake of v.E is 3 to 4 IU/d for term infants. Recommendations are somewhat higher for preterm infants. • Vit. K : To prevent bleeding in the first week of life when enteral intakes are low is recommended in the form of a 1-mg (IM) injection at birth in both term and preterm neonates > 1000 g birthweight. Premature infants weighing < 1000 gr : 0.3 mg

  27. Minerals Maintenance Na: commencing at 48 to 72 hours : 2-4 meq/kg/d(ELBW: روز 3) Maintenance K: commencing at 48 to 72 hours:1-2 meq/kg/dوقتي ادرار خوب برقرار شد تر: هر چه پره مچورترImmature , Na-k AT paseپمپشیفت K داخل سلولي به خارج سلول K بالاتر

  28. ...Minerals Minerals • The peak of fetal accretion of minerals occurs primarily after 34 weeks’ and preterm infants fed low mineral intakes develop poorly mineralized bones. • The advisable intakes range from 70 to 200 mg calcium per 100 kcal, 50 to 117 mg phosphorus per 100 kcal, and 6 to 12 mg magnesium per 100 kcal. • Several studies have shown improvement of mineral retention or bone mineralization in preterm infants who receive higher calcium and phosphorus intakes .

  29. ...Minerals • Consumption of unfortified human milk by infants with VLBW after hospital discharge resulted in bone mineral deficits that persisted through 52 weeks postnatally, indicating the need for additional minerals after discharge. • Supplemental bioavailablecalcium and phosphorus salts may be required by breast-fed, preterm infants untiltheir weight reaches term weight (3 to 3.5 kg) .

  30. Iron • Preterm infants are at increased risk for the development of iron deficiency anemia because: • they deplete their stores from birth in half the time it takes a term infant to do so (at about 2 months of age). • Infants with VLBW or sick neonates who are medically managed with frequent blood sampling lose much of the iron present in the circulating hemoglobin, which is then unavailable for erythropoiesis.

  31. Iron • American Academy of Pediatrics (AAP) , agree on a recommendation of 2 to 3 mg/kg /d of dietary elemental iron, begun no later than 2 months of age in preterm infants and continued throughout the first year of life. • Iron intakes of 2 mg/kg /d begun at 2 weeks of age were shown to safely augment ferritin stores in infants with LBW. • Higher intakes : begun by 1 month of age and continued through age 12 months. W < 1000 g :4 mg/kg/dayW = 1000 - 1500 g : 3 mg/kg/ dayweightat birth W > 1500 g : 2 mg/kg/day

  32. Human Milk • Human milk is the optimal food for term infants because it provides immunologic and antibacterial factors, hormones, enzymes, and opioid peptides not present in alternative infant food sources. • human milk is also the optimal primary nutritional source for premature infants. • The strongest evidence of the benefit of human milk for premature infants is the reduced incidence of NEC. • Other benefits include improved gastric emptying, reduced infections , and possibly better neurocognitive development.

  33. Human Milk • The milk from mothers of preterm infants contains more protein and electrolytes than does milk from mothers of term infants. • These concentrations decline and approach the composition of term human milkin several weeks. • Human milk does not completely meet the nutritional needs of premature infants; insufficientprotein, calcium, phosphorus, sodium, zinc, vitamins, and possibly energy are provided by human milk to optimally support most premature infants.

  34. Human Milk • Human milk fortifiers (HMF) have been developed and tested and address many of these inadequacies . • Premature infants fed fortified human milk may have growth rates slightly lower than those of infants fed formula, but they may also achieve earlier discharge. • HMF : W < 1500 gr : should be used W = 1500 – 2000 gr : should be considered

  35. Preterm Formulas • Formulas for premature infants have been developed to meet the nutritional needs of growing preterm infants . • Premature formulas contain a reduced amount of lactose ,because intestinal lactase activity may be low in premature infants. • The remainder of the carbohydrate content is in the form of glucose polymers, which maintain low osmolalityof the formula. • The fat blends of preterm formulas are 20% to 50% MCTs, a level that is designed to compensate for low intestinal lipase and bile salts. • The protein content of preterm formulas is higher than that of term formulas (2.7 to 3 g/100 kcal).

  36. Specialized Formulas • Preterm Discharge Formulas

  37. Supplementation of Infant Feedings • TERM INFANTS : • Supplementation for healthy, term, breast-fed infants is usually not necessary . (except for vitamin D,Iron) • To prevent rickets, the AAP recommends that breast-fed infants receive 200 IU/d of vitamin Dbeginningduring the first 2 months of life. • Breast-fed infants usually require an additional ironsource after 4 to 6 months of age.

  38. Supplementation of Infant Feedings PRETERM INFANTS : • PRETERM INFANTS : • Dailymultivitaminormineralpreparations may be necessaryfor preterm infants once enteral feedings have been established. • Multivitamin supplements that contain the equivalent of the recommended daily allowances for term infants can be given. • Liquid multivitamin drops do not contain folic acid because of its lack of stability, but it can be added or given separately.

  39. Breast-fed infants who weigh less than 3.5 kg do not consume enough human milk to acquire the recommended intakes of some vitamins and minerals. • Supplementation with a multivitamin, folic acid, calcium, phosphorus, zinc, and iron may be necessary , • Unless one of the commercially available milk fortifiers is used.

  40. Minimal enteral feeding • Early feedings were begun at about 3 days of age and consisted of human milk or formula at 12 to 24 mL/kg/day.. • Minimal enteral feedings involve hypocaloric, low-volume enteral nutrition that does not contain sufficient calories to sustain somatic growth. • Proposed benefits include maturation of the preterm intestine (both structurally and functionally), reduced liver dysfunction, and improved feeding tolerance. • Without an increase in the incidence of NEC.

  41. Breast milk should be the first choice and can be used undiluted.. • Diluting premature formulas for initial feedings is common clinical practice, but the data supporting this approach are limited. • Infants achieved full enteral feedings and full nipple feedings earlier than did their counterparts who were fed sterile water. • The available evidence strongly supports initiating early enteral feeding.

  42. METHODS OF FEEDING HIGH-RISK INFANTS • Gavage feeding : is appropriate for infants who demonstrate an immature suck and swallowing reflex or a clinical condition that is precludes nipple feeding, such as tachypnea or oral-facial anomalies. • Therefore, most infants fed by gavageare GA < 34 Weaks.

  43. Infants weighing > 2 kg have tolerated both orogastric(OGT) or nasogastric tube (NGT) placement without difficulty. • Infants weighing < 2 kg Placement of an anchored orogastric tube (OGT) is therefore recommended. • with transition to NGT when the infant’s weight exceeds 2 kg.

  44. Infants appear to tolerate feedings better if rapid gastric distention is avoided. • bolus feedings over 20 to 25 minutes are generally recommended . • Bolus feedings are usually delivered in equal volumes every 3 to 4 hours for term infants, every 3 hours for infants less than 2500 g, and every 2 to 3 hours for infants less than 1500 g. • Gastric emptying may be a clinical problem but is enhanced with human milk feedings and when infants are in the prone or right-sided position.

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