Chapter 21 – IV Therapy and IV Medication Administration

Summer 2018 Exam #4 Material Chapter 21 – IV Therapy and IV Medication Administration Intravenous Therapy o Administration of fluids, electrolytes, medications or nutrients via venous route. o IV Therapy Is Used To: o Expand intravascular volume o Maintain fluid and electrolyte balance o Correct an underlying imbalance in fluids or electrolytes o Correct or prevent nutritional imbalances  TPN o Provide IV medication therapy Types of Solutions o Solutions are classified according to how they compare to the osmolality of blood serum o Remember that blood serum normal osmolality is 280 – 295 mOsm/kg o Classified As: o Isotonic: the solutions has the same osmolality as our blood o Hypotonic: the solutions has less the osmolality as our blood o Hypertonic: the solution has more osmolality as our blood Isotonic Solution o Osmolality of 250 – 375mOsm/L o Remain inside the intravascular compartments o No fluid shifting occurs****hypothetically(test purposes) but in reality, bc of osmolality, shifting tends to occur no net loss or gain from the ICF o 1/3 to ½ of fluid stays in vasculature o Expands fluid volume of ECF o Ideal for pts with hypovolemia or hypotension o Examples: o 0.9% normal saline o Lactated Ringer’s solution Hypotonic Solution o Osmolality lower than 250mOsm/L- 250 is the solute(particles) “less particles, less concentration, more water- in the body, water ” o Water moves out of blood vessel into the cells and interstitial tissue o Used For: o Patients with hypertonic dehydration (high osmolality) o Hypernatremia o Patients needing water replacement o Examples: o Water o 5% dextrose and water (D5W) o 0.45% saline (1/2NS)  ½ of 0.9% saline o D5 0.25% Saline Hypertonic Solutions o Osmolality of 375 mOsm/L or greater “more particles, more concentration, less water-” o Initially raises the osmolality of ECF o Water moves from ICF & interstitial compartments into vascular space  draws water in o Useful in Treatment Of: o Hypotonic Dehydration o Temporary treatment of hypovolemia, hyponatremia and shock o Hyponatremia o Require frequent monitoring of BP, lung sounds, & serum Na+ levels o Examples: o Volume expanders (Dextran, Albumin, Hespan, Hetastarch) o D10%W  Dextrose metabolized ASAP then it becomes hypotonic, severe hypoglycemia, stopping TPN suddenly o D5% 0.9NS  becomes isotonic as soon as Dextrose is metabolized o D5% LR o 3% hypertonic saline  pts with increased intracranial pressure; pulling water from cerebral cells that will go into the intravascular space; give very carefully; only given in an ICU setting 5% Dextrose in Water (D5W) o Isotonic in bag, but physiologically (in the body) is hypotonic o Provides 50 g/L of glucose, which is about 170 cal/L o 5 grams of Dextrose per 100mL of fluid o Indications and Considerations o Provides free water only, no electrolytes o Moves into ICF o Increases renal solute excretion o Used to replace water losses, glucose, and treat hypernatremia Normal Saline (NS – 0.9% NS) o Isotonic o No calories, free water, or other electrolytes o More NaCl than ECF  excessive administration can result in elevated Na+ and Cl- levels o Hyperkalemic Acidosis: can occur o Clinical Uses o Hyponatremia (mild only!) o Treatment of shock o Use with blood transfusions  prime beforehand; this is the only acceptable fluid for this o Fluid replacement for Diabetic Ketoacidosis (DKA) once it gets below 200, no NS o Compatible with most medications Lactated Ringer’s o Isotonic o More similar to plasma than NS o Has less NaCl o Has K,+ Ca 2+, lactate (metabolized to HCO3-) o Does not provide calories o Clinical Uses: o Replenishes fluid and electrolyte for dehydration from nausea and vomiting, burns, wounds o Has some incompatibilities with medications o Post-surgery fluid  post-op patients can get acidotic and the bicarb in LRs can counteract this D5 ½ NS o 5% dextrose in 0.45% saline o Hypertonic in the bag; once it goes into the body, Dextrose is metabolized, so it changes to hypotonic o Common maintenance fluid o Same as 0.45% NaCl except provides 170 calories/L o KCl often added for maintenance or replacement for hypokalemia o Example: D5 1/2NS with 40 mEq KCl at 100 ml/hr D10W o Hypertonic in the bag o Provides 100 g/L of glucose or 340 kcal/L o 10 grams of dextrose in every 100mL o No electrolytes o Limit of dextrose concentration may be infused peripherally o Any fluid higher than 10% dextrose must be infused via central line to prevent shrinkage of RBCs or adverse outcomes if IV infiltrates; anything higher than 10% Dextrose in peripheral, this can be severely damaging, irritable, RBC will shrink, etc. o If TPN has to be stopped, can experience hypoglycemia  Give D10W Plasma Expanders o Stay in the vascular space and increase osmotic and/or oncotic pressure o Colloids (protein solutions)  increase both osmotic and oncotic pressures; big particles- keep fluid in the vessels or pull fluid into the vessels o Packed RBCs o Albumin o Plasma o Dextran (complex synthetic sugar); high concentration; osmotic pull and oncotic pull (expand volume, keep volume) o Pulls additional fluid into the intravascular space o Hetastarch (Hespan) o Synthetic colloid works similarly to Dextran to expand plasma volume Common IV Solutions - Review o 0.9% Sodium Chloride o Normal Saline or NS o Isotonic o Fluid won’t shift  some will leak out, but not a true fluid shift o D5%W- Isotonic in bag, hypotonic in body o 5 grams per 100mL o Physiologically hypotonic o Fluid will shift from ECF to ICF o Clinical Application: patient has a TBI and has severe cerebral edema, if given hypotonic IVF  patient will get worse; even more fluid in cells will not be a good thing! o Lactated Ringers o LR, Ringer’s Lactate o Sodium, Chloride, Potassium, Lactate (metabolized into bicarb), water o Isotonic o Fluid won’t shift o 0.45% Sodium Chloride o ½ NS o Sodium, chloride, water o Hypotonic o Fluid will shift from ECF to ICF o 5% of Dextrose in Lactated Ringers o D5LR o Sodium, Chloride, Glucose, Potassium… and water o Hypertonic in the bag, isotonic in the body (once the dextrose is metabolized) o Fluid will shift from ICF to ECF; fluid shift should stop (after dextrose is metabolized) Real World Example: A patient s/p ex. lap. is transferred to the surgical unit with an order for LR at 125 ml/hr. Prior to surgery a basic metabolic panel (BMP) was drawn: o Na: 140 (normal 135-145) o Cl: 106 (normal is 98-110) o K: 4.5 (normal is 3.5-5) Vital Signs: o 135/79 o 105 BPM o 22 resp/min o 96.9 F o 92% on 2 L 02 per NC Is this IVF appropriate for this patient?: Bring to provider’s attention, acidosis can rise potassium Colors of Needles and Gauge Sizes o 24 gauge: yellow o 22 gauge: blue o 18 gauge: green Central Venous Access o Intravenous line inserted into a major vein (or a “central vein”) o Subclavian or internal jugular (IJ) most often used o Catheter is advanced from insertion site into the superior vena cava (right above the right atrium) Advantages o Accommodates highly irritating & hyperosmolar solutions  TPN, 40 mEq potassium o Easily accessible even when severely dehydrated o Ports for medication administration for chemotherapy, antibiotics, vasoactive medications or nutrition therapy o Useful for monitoring central venous pressure o Requires radiographic confirmation of placement  for central line (can do an ultrasound for PICC lines) PICC Lines o Peripherally inserted central catheters (PICC) o “Power PICC”  can receive contrast dye given through them o “SOLO PICC”  saline only lock option; no clamps o Midline catheters - if it gets infected, its not in Central Blood line Complications – Local o Infiltration: leakage of non-vesicant IV solution or medication into the extravascular tissue o Signs/Symptoms ▪ Slowed or st