Parenteral Nutrition Flashcards
A pregnant patient is admitted with hyperemesis gravidarium (HG). Which of the following is a clinical indication for PN use?1: Vomiting NOT controlled with supportive care within 48 hours2: Intolerance to EN trial and supportive care measures3: Patient refusal of EN tube placement4: Fluid and electrolyte imbalances
2: Intolerance to EN trial and supportive care measuresHyperemesis gravidarum (HG) is a severe form of pregnancy-induced nausea and vomiting. Due to the likelihood that the patient’s nutritional intake has been poor for several weeks due to vomiting, EN or PN may be required. Prior to implementation of nutritional therapy for HG, fluid and electrolyte imbalances, ketonuria, and dehydration would be treated via IV fluid. Multivitamins with additional B vitamins are typically added to address suboptimal vitamin intake and prevent complications such as neuropathies (B6 and B12), Wernicke’s encephalopathy (thiamine), and neural tube defects (folic acid). Antiemetic treatment would begin and oral intake would temporarily be avoided. Initiation of an EN trial for HG would be appropriate if the patient is still unable to take oral feedings after 24-48 hours of supportive therapy as listed above. If the EN trial fails due to exacerbated nausea, vomiting, diarrhea, significant gastric residuals, or tube displacement and is associated with clinically significant weight loss (greater than 5% of body weight), it is appropriate to begin PN.
Rapid intravenous infusion of potassium phosphate may result in
1: thrombophlebitis.
2: hypercalcemia.
3: metabolic alkalosis.
4: vitamin D deficiency.
1: thrombophlebitis.
Infusion rates of phosphate should not exceed 7 mmol/h because faster infusion rates can often cause thrombophlebitis (ie, potassium phosphate) and metastatic calcium-phosphate deposition with potential resultant organ dysfunction.
What is the most common complication associated with PN administration?
1: Hypophosphatemia
2: Hyperkalemia
3: Hyponatremia
4: Hyperglycemia
4: Hyperglycemia
Hyperglycemia is the most common complication associated with PN administration and can be caused by various factors. Stress-associated hyperglycemia in acutely ill and septic patients often develops as a result of insulin resistance, increased gluconeogenesis and glycogenolysis, and suppressed insulin secretion.
What is the glycemic target for the majority of critically ill adult patients?
1: 80 to 110 mg/dL
2: 220 to 240 mg/dL
3: 140 to 180 mg/dL
4: 180 to 220 mg/dL
3: 140 to 180 mg/dL
The current recommendation for glycemic target by the American Association of Clinical Endocrinologists (AACE) and the American Diabetes Association (ADA) is to maintain the glucose level between 140-180 mg/dL for the majority of critically ill adult patients. Lower glucose targets (110 mg/dl to 140 mg/dL) may be appropriate for some patients, but this is only appropriate when this can be safely achieved. Targets less than 110 mg/dl are not recommended due to the adverse effects of hypoglycemia.
What is the preferred approach recommended by the American Association of Clinical Endocrinologists (AACE) and the American Diabetes Association (ADA) for subcutaneous insulin administration in the hospitalized adult patient with diabetes mellitus?1: Sliding-scale insulin therapy2: Basal insulin therapy3: Bolus insulin therapy4: Basal-bolus insulin therapy
4: Basal-bolus insulin therapyThe preferred approach for subcutaneous insulin administration is basal-bolus insulin therapy. This approach allows for basal insulin administered for hepatic glucose output combined with scheduled bolus insulin administered for meal times. There are three components to basal-bolus insulin therapy; basal insulin, nutritional component prior to meals and a correctional insulin.
Which form of glutamine supplementation improves physical compatibility and stability for admixture in PN solutions?1: Glutamine dipeptide2: Free glutamine3: L-glutamine powder4: Protein bound glutamine.
1: Glutamine dipeptideGlutamine supplementation is available in parenteral solutions, some predigested enteral formulas, and oral nutrition supplements. However, IV glutamine supplements are not commercially available in the United States. Glutamine dipeptide products such as L-alanyl-L-glutamine and Glycyl-L-glutamine improve water solubility, stability during heat sterilization, and the capability for prolonged shelf life when compounding in parenteral solutions. Free glutamine is unstable in parenteral solutions. Parenteral glutamine supplementation is more beneficial than enteral supplementation. Enteral glutamine is protein bound and it is difficult to determine the exact glutamine content. L glutamine powder is used in oral nutrition supplements.
In the critically ill obese patient, specific guidelines for the provision of calories and protein have been recommended by both the Society of Critical Care Medicine and the American Society for Parenteral and Enteral Nutrition. For a patient with a BMI 33.4 kg/m2, which of the following choices best reflects the calorie recommendations for parenteral and enteral nutrition?
1: 11- 14 Kcal/kg ideal body weight/day
2: 11 - 14 Kcal/kg actual body weight/day
3: 22 - 25 Kcal/kg actual body weight/day
4: 22 - 25 Kcal/kg ideal body weight/day
2: 11 - 14 Kcal/kg actual body weight/day
For all classes of obesity where BMI is >30 kg/m2, the goal of the parenteral and enteral regimen should not exceed 65% to 70% of target energy requirements as measured by indirect calorimetry. If indirect calorimetry is not available, using the weight based equation 11–14 kcal/kg actual body weight/day for patients with BMI 30-50 kg/m2 and 22–25 kcal/kg ideal body weight/day for patients with BMI > 50 kg/m2 is recommended. Protein should be provided in a range greater than or equal to 2.0 g/kg ideal body weight/day for patients with BMI 30–40 kg/m2, and up to 2.5 g/kg ideal body weight/day for patients with BMI ≥40 kg/m2.
Which of the following additives has the greatest risk of destabilizing the lipid injectable emulsion (ILE) in a total nutrient admixture (TNA)?
1: Sodium chloride
2: Calcium acetate
3: Iron dextran
4: Potassium phosphate
3: Iron dextran
Phase separation and the liberation of free oil from the destabilization of TNAs can result over time when an excess of cations is added to a given formulation. The higher the cation valence, the greater the destabilizing power; thus, trivalent cations such as Fe+3 (from iron dextran) are more disruptive than divalent cations such as calcium and magnesium. Monovalent cations such as sodium and potassium are least disruptive to the emulsifier, yet when given in sufficiently high concentrations, they may also produce instability. There is no safe concentration of iron dextran in any TNA.
Which of the following factors has been associated with an increase in prescribing errors related to PN formulations?
1: Standardized PN order form
2: Calculation of PN dosages
3: PN components ordered as amount per day
4: PN components listed in same sequence on order form as PN label
2: Calculation of PN dosages
Common factors associated with the majority of PN prescribing errors include: inadequate knowledge regarding PN therapy, certain patient characteristics related to PN therapy (e.g., age, impaired renal function), miscalculation of PN dosages, specialized PN dosage formulation characteristics, and prescribing nomenclature.
According to the ASPEN PN Safety Consensus Recommendations, which of the following is the best method to express the dextrose content on the label of a PN formulation in order to avoid misinterpretation?
1: Volume of the percent original concentration added (e.g., 500 mL of 50% dextrose)
2: Grams per liter (e.g., 250g/L)
3: Percent of final concentration after admixture (e.g., 35% dextrose)
4: Grams per 24-hour nutrient infusion (e.g., 225 g/day)
4: Grams per 24-hour nutrient infusion (e.g., 225 g/day)
PN ingredients shall be ordered in amounts per day for adults and amounts per kilogram per day for pediatric and neonatal patients. This limits the confusion of conversion from amounts per liter, percent concentration, or volume. Amount per day refers to macronutrients in grams per day and micronutrients in mEq, mmol, mcg, or mg per day.
According to the ASPEN PN Safety Consensus Recommendations all of the following are considered to be mandatory for the PN order form EXCEPT
1: Full generic name for each ingredient (unless brand name can identify unique properties of specific dosage form)
2: Recommended laboratory monitoring
3: Infusion schedule (continuous or cyclic)
4: Electrolytes ordered as complete salt form rather than individual ion
2: Recommended laboratory monitoring
The addition of recommended laboratory monitoring to PN order forms is strongly recommended, but it is not required. A complete PN order shall contain the following: complete patient identifiers, birth date or age, allergies, height and dosing weight in metric units, diagnosis/diagnoses, indication(s) for PN, administration route/vascular access device (peripheral versus central), contact information for prescriber, date and time order submitted, administration date and time, volume and infusion rate, infusion schedule (continuous or cyclic), and type of formulation (TNA versus dextrose/amino acids with separate ILE). PN ingredients shall be ordered as follows: amounts per day (for adult patients) or amounts per kilogram per day (for pediatric and neonatal patients), electrolytes as complete salt form, full generic name for each ingredient, using The Joint Commission approved abbreviations and avoiding ISMP error prone abbreviations, symbols, and dose designations, dose for each macronutrient and electrolyte, dose for vitamins (including MVI and individual entities), dose for trace elements (including multi-components and/or individual entities), dose for each non-nutrient medication.
According to the ASPEN PN Safety Consensus Recommendations all of the following are considered to be mandatory for the inpatient PN label EXCEPT
1: infusion rate expressed in mL/h.
2: beyond-use date and time.
3: size of in-line filter (1.2 or 0.22 micron).
4: electrolyte content expressed in individual ions.
4: electrolyte content expressed in individual ions.
Ingredients are to be expressed on the PN label in the same sequence and units of measure as the PN order. Electrolytes are to be ordered as complete salt forms as opposed to individual ions. The PN label should include the following: two patient identifiers, patient location or address, dosing weight in metric units, administration date and time, beyond use date and time, route of administration (central versus peripheral), prescribed volume and overfill volume, infusion rate in mL/h, duration of infusion (continuous versus cyclic), size of in-line filter (1.2 or 0.22 micron), completer name of all ingredients, barcode, all ingredients shall be listed in the same sequence and same units of measure as PN order, name of institution or pharmacy, and institution or pharmacy contact information (including telephone number). If ILE is to be infused separately, the ILE label should include: two patient identifiers, patient location or address, dosing weight, administration date and time, route of administration (central versus peripheral), prescribed about of ILE and volume required to deliver that amount, infusion rate in mL/h, duration of infusion (not longer than 12 hours), complete name of ILE, beyond use date and time, name of institution or pharmacy, and institution or pharmacy telephone number.
Your patient is receiving the following PN order. 2400 mL with 300 grams dextrose, 90 grams protein in addition to 225 mL 20% ILE. How many total calories and grams of fat is your patient receiving?
1: 1830 kcal, 40 grams fat
2: 2010 kcal, 40 grams fat
3: 1830 kcal, 45 grams fat
4: 1470 kcal, 45 grams fat
3: 1830 kcal, 45 grams fat
One (1) gram of dextrose is equal to 3.4 calories. Three hundred (300) grams provide 1,020 kcal. One (1) gram of protein is equal to 4 calories. Ninety (90) grams of protein provide 360 kcal. One (1) mL of 20% ILE is equal to 2 calories. ILE 20% provides 20 grams fat/100 mL; thus 225 mL provides 45 grams fat and 450 kcal.
A patient who weighs 75 kg is receiving 65 mL/hour of a 2-in-1 PN solution that contains 117 grams protein and 273 grams dextrose in addition to 250 mL of 20% ILE. What is the daily caloric content of this regimen per kg body weight?
1: 27.5 kcal/kg/day
2: 21.9 kcal/kg/day
3: 26.5 kcal/kg/day
4: 25.3 kcal/kg/day
4: 25.3 kcal/kg/day
One (1) gram of dextrose is equal to 3.4 calories. One (1) gram of protein is equal to 4 calories. One (1) mL of 20% ILE is equal to 2 calories. The total daily caloric intake equals 468 kcal (protein) + 928 kcal (dextrose) + 500 kcal (ILE) or 1896 kcal/day. When divided by the patient’s weight of 75 kg the total daily caloric intake per kg is 25.3 kcal/kg/day.
In the critically ill obese patient, specific guidelines for the provision of calories and protein have been recommended by both the Society of Critical Care Medicine and the American Society for Parenteral and Enteral Nutrition. For a patient with a BMI > 33.4 kg/m2, which of the following choices best reflects those recommendations for the provision of protein in parenteral and enteral nutrition?
1: Less than 2.0 g/kg ideal body weight/day
2: Greater than or equal to 2.0 g/kg ideal body weight/day
3: Less than 2.0 g/kg actual body weight/day
4: Greater than or equal to 2.0 g/kg actual body weight/day
2: Greater than or equal to 2.0 g/kg ideal body weight/day
For all classes of obesity where BMI is >30 kg/m2, the goal of the parenteral and enteral regimen should not exceed 65% to 70% of target energy requirements as measured by indirect calorimetry. If indirect calorimetry is not available, using the weight based equation 11–14 kcal/kg actual body weight/day for patients with BMI 30-50 kg/m2 and 22–25 kcal/kg ideal body weight/day for patients with BMI > 50 kg/m2 is recommended. Protein should be provided in a range greater than or equal to 2.0 g/kg ideal body weight/day for patients with BMI 30–40 kg/m2, and up to 2.5 g/kg ideal body weight/day for patients with BMI ≥ 40 kg/m2.
Which of the following is a indication for the use of parenteral nutrition (PN)?
1: High output fistula
2: Crohn’s disease
3: Pancreatitis
4: Hyperemesis gravidarum
1: High output fistula
PN is indicated for a non-functioning or inaccessible gastrointestinal tract. PN is indicated in patients with a high output fistula (>500 mL/day). PN is not routinely needed as nutrition support for Crohn’s disease. The preferred route of administration for nutrition intervention in patients with acute pancreatitis is EN. Only patients with severe hyperemesis gravidarum refractory to EN and pharmacotherapy would require PN.
When is parenteral nutrition (PN) indicated in severe burn patients?
1: Total body surface area burn exceeds 20%
2: As soon as possible after admission due to extremely high caloric needs
3: Enteral nutrition is contraindicated or unlikely to meet nutrition needs
4: Within 7-10 days after hospital admission
3: Enteral nutrition is contraindicated or unlikely to meet nutrition needs
Several studies have found that the use of PN in patients with burns has been associated with increased mortality. The use of PN in patients with burns is, therefore, reserved for patients who are unable to be fed enterally.
The routine use of preoperative parenteral nutrition (PN) is indicated for patients with a non-functioning GI tract who are
1: normally nourished.
2: mildly to moderately malnourished.
3: mildly malnourished with secondary co-morbidities.
4: severely malnourished.
4: severely malnourished.
Many studies have identified the severely malnourished patient as benefiting from preoperative nutrition support with PN. Results from multiple preoperative PN studies of surgical patients have shown no overall reduction in perioperative mortality. However, significant reductions in perioperative complications are achieved in the severely malnourished patient receiving more than 7 days of preoperative PN.
Which of the following is a indication for PN support in an adult cancer patient?
1: Abdominal tumor resulting in an unresolved small bowel obstruction for greater than seven days
2: Metastatic cancer, receiving palliative care
3: Receiving concurrent chemotherapy and radiation therapy
4: Mild malnutrition, scheduled for tumor resection surgery in three days
1: Abdominal tumor resulting in an unresolved small bowel obstruction for greater than seven days
Any adult patient with a gastrointestinal obstruction that precludes oral intake for at least one week may benefit from nutrition support. Mildly malnourished patients do not require PN unless oral intake is anticipated to be inadequate for more than one week. The palliative use of nutrition support in terminally ill cancer patients is rarely indicated. Most side effects of chemotherapy and radiation can be managed without the use of PN. Adult cancer patients scheduled for surgery who are severely malnourished may benefit from PN if the therapy can continue for 7-10 days preoperatively.
When should PN be used in Crohn’s disease?
1: As a primary therapy to rest the bowel
2: Only after failure to tolerate EN
3: To prevent associated malnutrition
4: Preoperatively regardless of nutrition status
2: Only after failure to tolerate EN
Studies comparing PN to EN in patients with Crohn’s disease found no advantage of parenteral over enteral nutrition. Remission rates were similar and there was no evidence that bowel rest with PN had any advantage. Therefore, EN should be used in patients with Crohn’s disease requiring nutrition support therapy. PN should be reserved for Crohn’s patients who do not tolerate EN. Peri-operative specialized nutrition support is indicated in patients with inflammatory bowel disease who are severely malnourished and in whom surgery may be safely postponed.
Current recommendations regarding safe administration of lipid injectable emulsion (ILE) include
1: ILE hang time up to 24 hours when included as part of a total nutrient admixture (TNA).
2: ILE hang time up to 24 hours when administered as an infusion separate from PN (2 in 1 PN).
3: ILE when a part of a TNA is stable for 1 week at room temperature.
4: ILE should be filtered with a 0.22 micron filter when administered for nutrition.
1: ILE hang time up to 24 hours when included as part of a total nutrient admixture (TNA).
TNA are more likely to be stable for 30 hours at room temperature (25 degrees Celsius) or for 9 days refrigerated (5 degrees Celsius) followed by 24 hours at room temperature. Prolonged storage and/or light exposure can result in degradation of some components of TNA. ILE is most stable at their manufactured pH (~6-9), and the addition of acidic dextrose can contribute to TNA instability. Electrolytes, especially positively charged cations calcium and magnesium neutralize the negative charge on the surface of the lipid particle. Commercially available ILE in the US are stabilized with egg yolk phosphatides providing a mechanical and electrical barrier to particle coalescence. Amino acids offer a protective effect by enhancing the admixtures buffering effect. ILE administered via piggyback separate from amino acid and dextrose should have a hang time of 12 hours and have tubing and filter changes with each new infusion. Recently package inserts for ILE have been updated to state that 1.2 micron filters should be used during ILE administration. This 1.2 micron filter could stop fat emboli, air emboli, microorganisms, and particulate matter from reaching the patient.