1. Raymundo F. Resurreccion, MD, FPCS
Surgical Nutrition
Raymundo F. Resurreccion, MD, FPCS

2. Objectives Differentiate metabolic responses to starvation and trauma
Explain the energy utilization in patients undergoing injury and stress
Recognize the role of nutritional support in patients undergoing stress and surgery

3. Objectives
Determine basic nutritional requirements in the surgical patient
Determine the appropriate route for delivery of nutrition
Recognize the dangers of overfeeding

4. Metabolic Response to Injury

5. Physiological responses to Injury
Injury, infection
Tissues / blood mononuclear cells, endothelium
Brain
SNS
HPA
Cytokines
NER
Metabolic
response
Inflammatory
response
Immune
response
Diminished intake
Increased expenditure

6. Mediators in SIRS/Sepsis
EFFECTS
Interleukin-1
Fever, proteolysis
Prostaglandins
Vasodilation
Corticosteroids
Hypermetabolism
Glucagon
Gluconeogenesis
Norepinephrine
Growth, thyroid hormones
Acute catabolism
Complement, anaphylatoxins
Microcirculatory damage
Kinin system, serotonin histamine
Oxygen free radicals
Membrane damage
Tumor necrosis factor
Tissue injury, shock
Myocardial depressant factor
Cardiac dysfunction
Nitric oxide
Vasodilation, hypotension

7. Stress Response to Injury

8. Neuro-endocrine Response
Massive receptor stimulus
Hypothalamo–pituitary axis
Catecholamines
Gluco + mineralo corticoids
Glucagon
ADH
Insulin

9. Hormonal Response to Injury
Hormonal Levels
Glucose Production
Proteolysis
Protein Synthesis
Catechols
  
  
Cortisol
 
Glucagon 
Insulin
HGH
Testosterone —

10. Starvation vs. Severe Stress
Starvation Continuum Stress
Resting energy expenditure 
 
Respiratory quotient
0.65
0.85
Counter regulatory hormones —
  
Primary fuel
Fat
Fat + amino acids
Proteolysis +
+++
Branched-chain oxidation

11. Starvation vs. Severe Stress
Starvation Continuum Stress
Hepatic protein synthesis +
+++
Acute-phase protein production —
Constitutive protein production 
  
Urinary nitrogen losses
Gluconeogenesis
Ketone body production
++++

12. Metabolic Response to Injury
Rapid glycogenolysis
H2O + NaCl retention  edema
Glucose intolerance
Gluconeogenesis
Protein synthesis redirected to acute phase proteins + wound healing
Muscle wasting

13. Metabolic Response to Injury
Increased energy expenditure
Pain, anxiety, fever
Muscular effort-work of breathing, shivering
Physiologic stress response: Catabolic phase
increased caloric needs, inadequate intake
gluconeogenesis  wasting of endogenous protein stores, increased urinary nitrogen losses
There are multiple sources of increased EE in the PICU which add to the physiologic response to stress…next slide

14. Energy Utilization Hypermetabolic state  increases demands
 less efficient use of nutrients for energy
 more nutrients used to meet the demands
Negative energy balance is highly correlated to complications in critically ill patients

15. Effects of Surgical Trauma on Resting Energy Expenditure
Surgical trauma is accompanied by a negative nitrogen balance
Nitrogen balance is more negative than during pure fasting
Long CL, et al. JPEN 1979;3:

16. Substrate Utilization
Glutamine
Benedict and later Cahill demonstrated the biochemical and nutritional derangements during simple, unstressed starvation.
1. Limited storage of CHO - main fuel during fed state hours after NPO.
2. Fuel changes to fat except for obligatory CHO demands of brain, RBCs and renal parenchyma.
3. Gluconeogenesis - primarily dependent on protein sources - fat/glycerol contributing only 10%
4. The GI tract as a metabolic organ shuttling and utilizing glutamine.
Muscle is metabolized as gluconeogenic substrate to supply the brain, kidney, tumor etc

17. Weight Loss after Surgical Trauma
Where?
Muscle
Fat
Why?
Reduced food intake
Increased energy expenditure
Derangements in protein/fat metabolism

18. Oxidation of Carbohydrate and Fat in Sepsis8
Glucose
oxidation
g/m2/h
Sepsis score 0 10 20 30
Fat
oxidation
g/m2/h 3
Sepsis score 0 10 20 30
Stoner et al Br J Surg 1983

19. Magnitude of Risk
Surgery
Operative
Risk
Patient
Anesthesia

20. Risk factors associated with death, analyzed by a multiple regression model
Confidence interval
Malnutrition2
1.87
Presence of cancer
2.07
Age ≥ 60y/o
2.30
Surgical treatment
0.16*
* p < 0.05
1 OR = odds ratio
2 Moderate and severe malnutrition
Correia and Waitzberg, Clin Nutr 2003; 22:

21. Consequences of Malnutrition
Loss of lean body mass
Poor wound healing, anastomotic breakdown
Compromised immune defense
Impaired organ function
Increased mortality rates

22. Predictors of Poor Surgical Outcome
Parameter
Predictor
Age
Increased (>70 years)
Type of Surgery
Emergent, contaminated, open abdominal, thoracic or aortic surgery, prolonged surgery
ASA
> Class 3
Cardiac
Presence of S3 gallop, jugular venous distention, MI within 6 mos, > 5 PVC, aortic stenosis, unstable angina, absence of beta-blockade
Pulmonary
COPD, FEV1 , 1.0, L PaO2 <60 , PCO2 > 50, fatigue with walking (steps)
Neurologic
Impairment, decreased function, nonambulatory status
Renal
Decreased creatinine clearance, BUN > 50 mg/dl
Nutrition
Hypoalbuminemia, hypokalemia
Frailty
Weakness, early exhaustion, dependency
American College of Physicians

23. Loss of Lean Mass and Mortality
Complications Relative to Loss of Lean Body Mass*
Lean Body Mass
(% loss of total)
Complications
(related to lost lean mass)
Associated Mortality (%) 10
Impaired immunity,
increased infection 20
Decreased healing,
weakness, infection 30
Too weak to sit, pressure
sores, pneumonia, no healing 50 40
Death, usually from
pneumonia
100
*assuming no preexisting loss

24. Goals of Surgical Nutritional Support
Maintain host defenses
Support metabolic response
Reduce the catabolic state and preserve lean body mass
Support the depleted patient throughout the catabolic phase of recovery

25. Goals of Surgical Nutritional Support
Improve patient outcomes
Decrease surgical mortality
Decrease surgical complications and infection
Prevent/treat macro/micronutrient deficiencies
Speed the healing / recovery process (Decrease the LOS)

26. Nutrition Support in Surgery
Endocrine, metabolic, and immunologic alterations
Full Wound healing
Full Restoration of metabolic and immune homeostasis
Surgery
Adequate
body reserves
food intake

27. Nutrition Support in Surgery
Endocrine, metabolic, and immunologic alterations
Wound healing
Restoration of metabolic and immune homeostasis
Surgery
Nutrition Support
Inadequate body reserves
Inadequate food intake
Incomplete restoration of organ functions
Multiple organ dysfunction, failure, and death

28. Necessary Length of Preoperative Nutrition in Malnourished Patients
Prospective randomized studies
2-3 days: No improvement in outcome
5-7 days: Influence in outcome
7-10 days: Benefits outcome
Reduction of postop morbidity and mortality
Meguid: Am J Surg 1990; 159:345
**ENDPOINTS: Monitor nutrient intake (Calorie Count)
Total lymphocyte count

29. ASPEN Guidelines
Preoperative SNS should be administered to moderately or severely malnourished patients undergoing major gastrointestinal surgery for days if the operation can be safely postponed.
Postoperative SNS should be administered to patients whom it is anticipated will be unable to meet their nutrient needs orally for a period of 7 to 10 days.
A.S.P.E.N. Board of Directors, JPEN 2002

30. Nutritional Assessment
Body composition (anthropometric measurements)
Biochemical data
Clinical assessment
Subjective Global Assessment (SGA)
Indirect calorimetry

31. Computing Nutritional Requirement
Total caloric requirement (TCR)
Total protein requirement (TPR)
Fluid requirements
Micronutrient/Vitamin requirements

32. Nutritional Requirements
Nutrients
Carbohydrate
Protein
Fat
Vitamins
Minerals
Water
Calories Provided
4 kcal/g
9 kcal/g -
National Research Council: Recommended Dietary Allowances,10th ed National Academy Press, 1989

33. Nutritional Requirements
Calculations are based on:
age
sex
weight and height
stress factor
activity level
AFTER KNOWING THE NUTRITIONAL SATUS WE NOW NEED TO KNOW WHAT AND HOWMUCH NUTRITION DOES OUR PATIENT REQUIRE.
Calculations for nutritional requirements are based on the following:
1. Age
2. Sex
3. Body size
4. Activity level

34. Nutritional Requirements
Total Caloric Requirement (kcal/ day)
1. Harris-Benedict Equation (BEE)
Male: (13.75 x BW) + (5 x height) -
(6.76 x Age) x AF x SF
Female: (9.56 x BW) + (1.85 x height) -
(4.67 x age) x AF x SF
TCR = BEE x AF x SF

35. Nutritional Requirements
Activity factors
Confined to bed = 1.2
Ambulatory = 1.3
Stress Factors
Minor surgery = 1.2
Trauma =
Sepsis =
Burns =

36. Nutritional Requirements
2. Short Method
Non stressed: kcal/kg
Stressed: kcal/kg
Underweight: Actual BW x kcal/kg
Overweight: Ideal BW x kcal/kg
TCR = wt (kg) x kcal
To give you the whole picture of how we compute for the requirements here are two methods. The first or Short Method is the easiest while the most difficult is the Harris-Benedict Long modification. Of course most of us will choose the easier method, but we can cover more of the patient’s needs if we use the Harris Benedict equation.

37. Conditions Affecting Caloric Needs
REE Change
Fever (per°C)
+10 to 15%
Sepsis
+20 to 60%
Trauma
+20 to 50%
Burn
+40 to 80%
Treatments
Mech. Ventilation
-25 to -35%
Nutritional support
+20%
Agitation
+50 to 100%
Chiolero R, Nutrition 1997

38. Drugs Affecting Caloric Needs
REE Change
Opiates
-9%
Sedation
-20 to -55%
Barbiturates
-32%
Muscle relaxants
-42%
Catecholamines
+32%
β-blockers
-6 to -7%
+20%
Agitation
+50 to 100%
Chiolero R, Nutrition 1997

39. Nutritional Requirements
3. Indirect calorimetry
Gold standard for measuring REE
Calculated by measuring O2 consumption (VO2) and CO2 production (VCO2) using the abbreviated Weir equation: REE = [3.9 (VO2) (VCO2)] x 1.44.
Performs better than predictive equations with added stress factors
Measurements made over min and 24hr EE is extrapolated
Results may become unreliable due to variations in ventilator settings, air leaks, high FiO2 (fraction of inspired oxygen), acid-base disturbances,
intermittent feeding, diet-induced thermogenesis, absence of a quiet thermoneutral environment, pain, agitation.

40. Protein Requirements Non-Stressed: 0.8 -1 gm/kg/day
Mild-Moderately Stressed: gm/kg/day
Severely Stressed - > gm/kg/day
Lefor et al.Critical Care. 2004
Protein should comprise approximately
20% of the total calories during stress
These are the protein requirement values and to emphasize this point - protein requirements for the critically ill or stressed patient should be approximately 20% of this Total Caloric Requirement.

41. Non-Protein Calories Carbohydrate Fats NPC combinations
acute stress: 70% carbo 30% fat
usual: 60% carbo 40% fat
infections: 50% carbo 50% fat
pulmonary: 40% carbo 60% fat
The NPC or Non-Protein Calorie portion which are the carbohydrates and fat components of the Total Caloric Requirement will give the patient more or less what she/he needs in the different situations she/he is in.

42. Supplying Large Amounts of Carbohydrates Leads to Hyperglycemia
Insulin resistance
Impaired wound healing
HYPERGLYCEMIA
(Effects in stressed patients)
Effects of hyperglycemia in stressed patient
Increased risk of infection
Immune dysregulation
increased Macrophages and Neutrophils
Increased risk of loss of LBM
 Skeletal muscle proteolysis
 Oxidative stress
(proinflammatory)
 Risk of infection
Risk of LBM loss
 Skeletal muscle proteolysis

43. Vitamins Fat Soluble Water Soluble Vitamin A Vitamin D Vitamin E
Folic Acid
Pantothenic Acid
Biotin
Niacin
Riboflavin
Vitamin E
Vitamin K
Thiamine
Vitamin B6
Vitamin B12
Vitamin C

44. Electrolytes Sodium Potassium Chloride Calcium Phosphorus Magnesium
Zinc
Copper
Chromium
Manganese
Selenium
Iodine
Iron

45. Fluid Requirements How much volume to give?
Cater for maintenance & on going losses
Normal maintenance requirements
By body weight
Alternatively, 30 to 50 ml/kg/day

46. Maintenance Water Requirements
Children
Adults 30 ml/kg/day
Weight (kg)
mL/kg/hr
mL/kg/day
1 – 10 4
100
11 – 20 2 50
21 – n 1 20

47. Water losses Add on-going losses based on I/O chart
Urine: 800 to 1500 ml/day
Stool: 250 ml/day
Consider insensible fluid losses also
8-12 ml/kg/day
Cutaneous insensible losses increase by 10% for every 1°C above >37°C

48. Maintenance Water Requirements
Change in Fluid Requirements
Increased
Decreased
Fever
Renal failure
Fistulas
Congestive heart failure
Diarrhea
Cirrhotic ascites
NG suction
Pulmonary disease

49. Clinical Decision Making Algorithm for Nutritional Support
NUTRITIONAL ASSESSMENT
Functioning GI Tract?
YES NO
Oral Formula
Supplements
ENTERAL NUTRITION
PARENTERAL NUTRITION
Tube feeding for more than 6 weeks?
PN for more than 4 weeks?
YES NO
YES NO
Enterostomy
Nasoenteric Tube
Central PN
Peripheral PN
Risk for pulmonary aspiration?
GI FUNCTION RETURNS?
YES NO
YES NO NO
YES
Gastrostomy
Nasoduodenal or
Nasojejunal Tube
Jejeunostomy
Nasogastric Tube
GI FUNCTION
Progress to Total Enteral Feedings
NORMAL
COMPROMISED
Standard Formula
Specialty Formula
PN Supplementation
Inadequate
FORMULA TOLERANCE
Progress to More Complex Diet and Oral Feedings as Tolerated
Adequate

50. Preferential Use of Enteral Nutrition
EN delivery has two main routes: gastric and post-pyloric
Use of the gut stimulates GALT & MALT
→ enhanced immune response
Early feeding can trigger gut immunity and thereby improve outcomes
McClave, J Clin Gastro, Sept 2002

51. Preferential Use of Enteral Nutrition
Delay or failure may promote a proinflammatory state with ↑ disease severity & morbidity
Early EN in the post-operative period is a viable option to address recuperation needs, malnutrition and its complications
Reduce morbidity and cost compared with parenteral nutrition

52. Limitations Of EN Delivery
Deranged motility
Reduced exocrine pancreatic function
Intestinal hypoperfusion/ bowel ischemia
Gastric reflux
Aspiration
Nausea, vomiting
Abdominal distention and cramps
Diarrhea
Malabsorption

53. Parenteral Nutrition
Essential form of sustenance for patients who cannot tolerate the oral or tube feeding administered intravenously.
Parenteral nutrition is administered partially or completely through venous access, using either a peripheral vein or central venous access.

54. Indications: Parenteral Nutrition
General Indications
Patients requiring long-term (>10 days) supplemental nutrition because they are unable to receive all of their daily energy, protein, and other nutrient requirements through oral or enteral feeding
Severe gut dysfunction or inability to tolerate enteral feedings

55. Indications: Parenteral Nutrition
Inability to use the gastrointestinal tract
intestinal obstruction
peritonitis
intractable vomiting
severe diarrhea
high-output enterocutaneous fistula
short bowel syndrome
severe malabsorption.
Need for bowel rest
Palliative use in terminal patients is controversial
Parenteral Nutrition provides nutritional and metabolic support to patients who cannot be adequately fed orally or via enteral tube feeding. In these patients, the gastrointestinal tract is either not functioning or cannot be used.
Situations in which parenteral nutrition may be necessary include:
intestinal obstruction
peritonitis
intractable vomiting
severe diarrhea
high-output enterocutaneous fistula
short bowel syndrome
severe malabsorption.
In acute pancreatitis, parenteral nutrition can be used until adequate levels of enteral nutrition are reached or when enteral nutrition cannot be implemented.
Parenteral nutrition is also used when bowel rest is necessary for a period of time.
Parenteral nutrition is not appropriate for extending the life of a terminal patient, unless it is an exceptional situation, in which case it should be discussed with patient and/or family.
ASPEN Board of Directors. JPEN 2002; 26 Suppl 1:83SA.
ASPEN Board of Directors. JPEN 2002; 26 Suppl 1: 83SA

56. Composition of Formulas

57. Parenteral Access

58. Nutrition Care Plan
Computed calorie and protein requirements based on disease, labs, current complications
Determine form & route of feeding
Type of feeding
Oral
Enteral - NGT, PEG, Surgical tubes
Parenteral - peripheral, central
Delivery method (pump or bolus)

59. Monitoring Metabolic Assessment Glucose Fluid and electrolyte balance
Renal and hepatic function
Triglycerides and cholesterol
Assessment
Body weight
Nitrogen balance
Plasma protein
Parenteral nutritional monitoring is used to adjust the components of the formula as well as the frequency of monitoring according to laboratory results.
As a general rule, metabolic control includes serial laboratory tests to detect possible problems such as electrolyte and fluid imbalance, hyper- or hypoglycemia, hepatic disorders, and triglyceride clearance problems. When these data are consistently within normal limits, the frequency of tests may be reduced.
Nutritional monitoring also includes daily evaluation of body weight, and weekly nitrogen balance, plasma protein levels, and creatinine/height index. These tests are done regularly for patients receiving parenteral nutrition.
Campbell SM, Bowers DF. Parenteral Nutrition. In: Handbook of Clinical Dietetics, The American Dietetic Association, 2nd ed. New Haven: Yale University Press. 1992;
Campbell SM, Bowers DF. Parenteral Nutrition. In: Handbook of Clinical Dietetics. Yale University Press, 1992

60. Monitoring
FLUID BALANCES
CALORIE COUNT

61. Dangers of Overfeeding
Secretory diarrhea (with EN)
Volume overload, CHF
COCO2 production: ventilatory demand
O2 consumption

62. Dangers of Overfeeding
Electrolyte problems: PO4 , K, Mg
Hyperglycemia, glycosuria, dehydration, lipogenesis, fatty liver, liver dysfunction
Increased mortality (in adult studies)

63. Thank you for your attention.