Fluids and electrolytes

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I am a second semester student and I am trying to get some insight on fluid and electrolytes. I anyone have any suggests or comments that will help me please....I'm begging...lol!!!!

Specializes in Hospitalist Medicine.

What kind of insight are you looking for? Can you give some specifics of what you're struggling with?

There are a number of threads on this here-- it comes up regularly. What kind of things are confusing you?

Specializes in Cardiac/Respiratory/PCU.

Well this is vague lol.

So i'll leave a tip. "If that K+ won't go up, check that Mg level real closeup"

:woot:

Specializes in Med Surg.

It might relate to how you did in Chemistry. If you faked your way through it, you should work very hard to catch up. If you work in acute care, fluid and electrolytes will be a constant task and you will need to understand them.

To any prospective nursing student: Chemistry is really really important for understanding what comes next.

Everyone on this board gives high praise for a book called Fluids & Electrolytes Made Incredibly Easy - I've only read a few chapters so far, cause like you, i'm also second semester and didn't really get it all the first time around and I am aware I'll need to really know it, so I took the board's advice and bought it. And from what I've read so far, it really is as good as people say. it's $35 on amazon. Best $35 I ever spent.

Specializes in Critical Care, ED, Cath lab, CTPAC,Trauma.

using the search engine here.......Search Results for fluid and electrolytes

Tell us specifically you are looking for

Everyone on this board gives high praise for a book called Fluids & Electrolytes Made Incredibly Easy
Not everyone.

I don't care for the "Incredibly Easy" books on any topic.

For this topic, my preferred reference is by Joyce LeFever Kee: Handbook of Fluid, Electrolyte and Acid Base Imbalances: Joyce LeFever Kee, Betty J. Paulanka, Carolee Polek: 9781435453685: Amazon.com: Books

Kee also has an excellent book called Laboratory and Diagnostic Tests with Nursing Implications. Available on Amazon, and her explanations of lab results will help you too.

Fluid & Electrolytes - Apply it to Nursing.

Example:

Causes of Hypokalemia vs Hyperkalemia:

- Patients on NGT suction @ risk for hypokalemia

- Patients in DKA may develop hypokalemia (Hydrogen and K exchange - extracellular levels of K go up but are urinated because of the excessive glucose in the bloodstream)

-

Sings of Hypokalemia vs Hyperkalemia:

Respiratory-

Cardiovascular-

Neurological-

Musculoskeletal-

Gastrointestinal-

Renal-

Labs- Hypo = A potassium level below 3.5.

EKG- Hypo = Inverted or flat T waves. U waves.

How medications affect potassium levels:

Increase/retain levels or affinity- K sparing diuretics.

Decrease levels or affinity- Loop diuretics. Dig.

Dietary sources:

Avocado

Banana

Ways to fix it:

-Well you always want to fix the CAUSE!

-Hyperkalemia can be fixed with insulin and some D5 bc insulin drives potassium into the cell.

-Hyperkalemia in RENAL patients you use Kayexalate(spelling) Kayexalate is excreted in stool.

If you follow this outline you're good to go. :) worked for me.

I have used the Fluid and Electrolytes Made Incredibly Easy and I do like it but I also have a book Fluid and Electrolytes Demystified that I really like too. I am also just in second semester but they have helped me so far!!

Na+ and Water Balance, or why you have to remember that serum sodium doesn't tell you anything at all about sodium :), and that saline is not water and salt.(Now, don't overthink this. Of course if you want to make a bottle of saline in chem lab, you will mix water with sodium chloride. But read this without thinking about that, because .... well, it works better if you think of saline as an entity for purposes of this discussion. Read it and then ask me if you still have questions.)

OK, thought experiment time: Draw pictures with little molecules or such if you like, it will help. You have a beaker full of salt water, with a Na+ level of, say, 140 (hmmmm, what a coincidence). You pour half of it out. What is the Na+ level in the remainder? Right, 140, because that measurement is a measurement of CONCENTRATION, not a count of the absolute number of sodium molecules. Got that? If not, work on it, because you have to "get" it.

Now you refill the beaker to its previous level, full up, with plain water... or, say, D5W, which is the same thing, physiologically. Now what's your sodium level? Right, 70, because you have twice as much water per amt of sodium.

Go back to the half-full beaker again, the one with a serum (oooh, a Freudian slip! I think I'll leave it. Serum counts as saline.) sodium of 140. Fill it up with an equal volume of....normal saline, which for purposes of this discussion has a sodium level about the same as blood serum. What's the serum sodium now? Right, still 140. As a matter of fact, you can pour quite a bit of NS into a body and not really influence the serum sodium that much at all. The way you change the serum sodium is by changing the amt of WATER.

Repeat to yourself: "Serum sodium tells you about water balance." and "Saline is not sodium and water." (I used to have a poster of this and have my classes chant it three times before going on :)....I wanted to be sure they would remember it for later)

OK, deep breath. Now we look at water balance from the other side.

Saline pretty much stays in its vascular place (unless you cut a blood vessel and spill some out). But water....ah, water travels. As a matter of fact, that's the other poster. Repeat three times: "Saline stays, water travels." (think: rivers flow from place to place, but the ocean pretty much stays where it is.) What the heck importance is that?

Back to your original beaker.... the one full of stuff with a serum Na+ of 140. Evaporate half of the water. What is the serum sodium now? Right, 280 (whooee, bigtime dehydration) As a matter of fact, if you lose enough water from your body to get your serum sodium up to 170 or so (("Serum sodium tells you about water balance")), you'll probably die, especially if you do it rapidly. Why? Because water travels in and out of all your cells. If you lose water from your intravascular space, sweat it out, or pee it out because your kidneys are unable to concentrate urine for some reason, thus making your bloodstream more concentrated, water molecules on the other side of the cell walls all over town say, "Whoops! Gotta go!"...because water travels across cell membranes from an area of more water per volume (lower salt concentration) to the area of less water per volume (higher salt concentration). So if you are de-hydrated, meaning water-poor, all your cells shrink. Most importantly, if your brain cells shrink enough from water loss, they pull away from your pia mater/meninges and you have an intracerebral bleed. Bummer.

(Interestingly, this is why you have a headache with your hangover after an alcohol binge. Alcohol temporarily disables your kidneys from retaining water, so they let too much out. You pee a lot, and your brain shrinks just enough to put a little tension on your pia mater/meninges. Bingo, headache.) (Ahhh, digressed again....)

OK, now put this all together and tell me why your hematocrit is a lousy indicator of water balance (as a matter of fact, a nigh-on USELESS indicator of dehydration), but a good indication of saline balance.

OK. You are walking down the street with a perfectly good crit of 40 and a serum sodium of 140 (and normal other lytes). You are accosted by someone with a sharp thing and before you know it, a whole lot of your circulating volume is running into the storm drain. Fortunately, you are whisked into a nearby ER immediately, having had your bleeding stopped by a nearby Boy Scout with good First Aid Merit Badge training (ummmm, I teach that too). The ER nurse draws a baseline crit and lytes. What are they?

OK, crit is still 40...because hct is a *percentage of the blood that is red cells*, not a count of the absolute number of red cells you have. So even if you lose a lot of your blood, your crit is unchanged. Until they start fluid-resuscitating you with.... normal (not half-normal) saline (or RL, which acts like it for purposes of this discussion).

Na+ is still 140, because you have lost saline (serum counts as saline) but not water.

Thought experiment time again. Take two tubes of whole blood, that is, serum and red cells. They both have a Hct ( which is often spoken as “crit”) of 40, that is, 40% of the volume of each tube is taken up solely by RBC's. We already know what happens if you add saline to one of them: the crit drops, right? But what happens to the crit of a tube of blood if you add water-- like D5W? Answer: Nothing. Why? Because the crit is a % of volume....and when you add water, the water travels into the cells too. So they swell up, and their %age size change means no change in the crit of the tube. They still take up (in this example) 40% of the volume. What happens if, instead of adding water to your original tube of hct=40 blood, you evaporate half of the water out of it? (The answer is NOT, "Make gravy." Shame on you.) No, the hct stays the same, because the cells lose water too, and they shrink as much as the liquidy part did. Same percentage of red cells in the resulting volume = no change in hematocrit.

So. When you have someone dehyrated (as evidenced by their elevated serum Na+), you give him water (or D5W). This dilutes his serum Na+ back towards normal and allows his shrunken dehydrated cells to regain their girlish plumpness. Normal saline will not help, as it will not change the serum sodium level ("Saline is not sodium and water") and will not move into cells to restore their lost water content ("Saline stays, water travels.")

If you have someone who is hypovolemic, as evidenced by (hmmm? what? how do you assess hypovolemia? How about BP, CVP, JVD, PAd, LVEDP, etc? You pick 'em), you give him saline, which goes into his vascular space where you want it for circulating volume but doesn't go anywhere else. D5W will not do the job, as it will travel into cells (not just RBC's, but all cells, and most of it will thus not be available in the vascular space to make blood pressure).

So why do dehydrated old ladies have high crits AND high serum Na+'s? Well, as I was fond of telling my students, it's perfectly possible to have two things wrong at once.

Let's look at a couple of people and see if that helps.

1) Serum Na+ 140, Hct 25, BP 110/60. OK, so this guy is relatively anemic, but his circulating volume is OK (as evidenced by an adequate BP) and his water balance is fine (as evidenced by his normal Na+). Who does this? Well, anemia can have many causes, but if he comes in with a hx of a recent bleed with fluid resuscitation, you could guess that he had a perfectly good crit until he lost some red cells out his GI bleed or stab wound or bloody ortho surgery or something, and we were stingy and just gave him NS back. His crit is called "dilutional," as in, "His red cells are floating in saline."

2) Serum Na+ 118, Hct 40, BP 110/60. This guy has 'way too much water on board, as evidenced by his Na+ that's 'way low ("dilutional" too). We call him hyponatremic, but it's not that he has lost sodium (in most cases), it's that he retained too much water. He hasn't lost saline, as evidenced by his decent BP ("Saline is not sodium and water"). Who does this? Well, remember the dread "SIADH"? "Syndrome of inappropriate antidiuretic hormone"? Lessee.... inappropriate, ummm, too much. Antidiuretic, ummmm, doesn't allow diuresis, holds onto water.... Bingo. He's retaining water, and his Na+ is called "dilutional" because all those little Na+s are floating around in too much water. Some degree of SIAHD is actually pretty common--- you can do it with anesthesia, mechanical ventilation (there's stretch receptors in the lungs, see, and....oh, later), and a host of common meds. Of course, you can also get a low serum sodium in a hurry if some fool tanks you rapidly with a liter or two of D5W, or , like that poor woman in a SoCal radio contest, you drink a ton of plain water over a short period of time. She died of acute cerebral edema when her brain swelled up faster than her skull would stretch to accommodate it.

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