Fluid and Electrolyte Balance - Introduction - F and E Intro.PDF

Summary

This document introduces fluid and electrolyte balance, listing learning objectives and explaining body fluid volumes. The document also covers related topics like osmosis and describes common fluid and electrolyte imbalances.

Full Transcript

Fluid and Electrolyte Balance

Introduction

1 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Learning Objectives
Fluid and Electrolyte Balance
1. List, describe, and compare the body fluid
compartments and their subdivisions.
2. Discuss avenues by which water enters and leaves
the body and the forces that move fluids into and out
of the blood.
3. Explain the mechanisms used by the body to
maintain fluid balance.
4. Discuss the nature and importance of electrolytes in
body fluids.
5. Describe examples of common fluid and electrolyte
imbalances.

2 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Body Fluid Volumes
Water is most abundant body compound
– References to “average” body water volume
based on a healthy, nonobese, 70-kg male
– Water is 60% of body weight in males; 50%
in females
– Volume averages 40 L in a 70-kg male (154
pounds)

3 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Body Fluid Volumes (Cont.)
Variation in total body water is related to:
– Total body weight of individual
– Fat content of body:
The more fat the less water (adipose tissue is low in water
content)
– Gender
Female body has about 10% less water than male body
(Figure 19-2)
– Age
In a newborn infant, water may account for 80% of total body weight
In older adults, water per pound of weight decreases (muscle tissue –
high in water – replaced by fat, which is lower in water)

4 Copyright © 2016 by Elsevier Inc. All rights reserved.
Relative Volumes of
Three Body Fluids

5 Copyright © 2016 by Elsevier Inc. All rights reserved.
Water in the Body

6 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Body Fluid Compartments
Extracellular fluid (ECF)
– Called internal environment of body
– Surrounds cells and transports substances to
and from them
– Types
Plasma: Liquid part of whole blood
Interstitial fluid: Surrounds the cells
Transcellular fluid: Lymph, joint fluids,
cerebrospinal fluids, eye humors

7 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Body Fluid Compartments
(Cont.)
Intracellular fluid (ICF)
– Largest fluid compartment
– Serves as solvent to facilitate intracellular
chemical reactions

8 Copyright © 2016 by Elsevier Inc. All rights reserved.
Volumes of Body Fluid
Compartments

9 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Mechanisms That
Maintain Fluid Balance
Overview of fluid balance
Regulation of fluid output
– Fluid output, mainly urine volume, adjusts to
fluid intake
– Antidiuretic hormone (ADH) from posterior
pituitary gland acts to increase kidney tubule
reabsorption of sodium and water from tubular
urine into blood, thereby tending to increase
ECF (and total body fluid) by decreasing urine
volume
10 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Mechanisms that
Maintain Fluid Balance (Cont.)
Regulation of fluid intake
– ECF electrolyte concentration influences ECF volume
– Increase in ECF increases ECF volume by increasing
movement of water out of ICF and by increasing ADH
secretion, which decreases urine volume
Exchange of fluids by blood
– Capillary blood pressure pushes water out of blood,
into interstitial fluid; blood protein concentration pulls
water into blood from interstitial fluid; hence, these two
forces regulate plasma and interstitial fluid volume
under usual conditions
11 Copyright © 2016 by Elsevier Inc. All rights reserved.
Aldosterone Mechanism

12 Copyright © 2016 by Elsevier Inc. All rights reserved.
 TYPES OF FLUIDS/ IVF
SOLUTION
ISOTONIC FLUIDS
An isotonic solution is one that has the same osmolarity, or
solute concentration, as another solution. If these two solutions
are separated by a semipermeable membrane, water will flow in
equal parts out of each solution and into the other.
A depiction of a cell in an isotonic solution can be seen above.
Note that because there is the same concentration of solute
molecules inside and outside of the cell that water molecules are
simply exchanged through the cell membrane.
Example: 0.9% Normal Saline (0.9% NaCl). Because the
concentration of the IV fluid is similar to the blood, the fluid stays
in the intravascular space and osmosis does not cause fluid
movement between compartments
 TYPES OF FLUIDS/ IVF
SOLUTION
HYPOTONIC FLUID
A hypotonic solution is a solution with a lower concentration of
solutes than another solution. In biology, hypotonic solutions
carry across semipermeable membranes—plant cell walls and
animal cells—to infuse the cells with fluids.
In medicine, hypotonic solutions include:
-Saline 0.45 percent (less than half the normal saline level found
in blood)
-Saline 0.25 percent with or without dextrose (a quarter of
normal saline level)
-5 percent or 2.5 percent dextrose
-Pure distilled water
 Hypertonic solutions
Hypertonic solutions have a higher
concentration of dissolved particles than blood.
An example of hypertonic IV solution is 3%
Normal Saline (3% NaCl). When infused,
hypertonic fluids cause an increased
concentration of dissolved solutes in the
intravascular space compared to the cells. This
causes the osmotic movement of water out of
the cells and into the intravascular space to
dilute the solutes in the blood.
 MOVEMENTS OF FLUIDS
Diffusion
Diffusion is the process of movement of molecules
under a concentration gradient. It is an important
process occurring in all living beings. Diffusion helps
in the movement of substances in and out of the
cells. The molecules move from a region of higher
concentration to a region of lower concentration
until the concentration becomes equal throughout.
Liquid and gases undergo diffusion as the molecules
are able to move randomly.
MOVEMENTS OF FLUIDS

Example:
Take water in a beaker. Add a few copper sulfate crystals in one place and leave it as
it is for some time without disturbing it. After some time we can see that the beaker
contains a uniformly colored solution. Here, both water and copper sulfate diffuse
independently. With this experiment, we can infer that solutes move from a higher
concentration to a lower concentration in a solution.
 MOVEMENTS OF FLUIDS
Active Transport
It is defined as a process that involves the movement of molecules from a region of
lower concentration to a region of higher concentration against a gradient or an
obstacle with the use of external energy.

The diagram shows the process of active transport, which uses an external energy
ATP for the movement of the molecules.
The uptake of glucose in the intestine of the human body and also the uptake of
minerals or ions into the root hair cells of the plants are some of the examples of
active transport.
MOVEMENTS OF FLUIDS
Osmosis
It is a process by which the molecules of a solvent
pass from a solution of low concentration to a
solution of high concentration through a semi-
permeable membrane.
Osmotic pressure is the pressure required to stop
water from diffusing through a membrane by
osmosis. It is determined by the concentration of the
solute. Water diffuses into the area of higher
concentration from the area of lower concentration.
MOVEMENTS OF FLUIDS
MOVEMENTS OF FLUIDS
Osmosis is of two types:
Endosmosis– When a substance is placed
in a hypotonic solution, the solvent molecules
move inside the cell and the cell becomes
turgid or undergoes deplasmolysis. This is
known as endosmosis.
Exosmosis– When a substance is placed in
a hypertonic solution, the solvent molecules
move outside the cell and the cell becomes
flaccid or undergoes plasmolysis. This is
known as exosmosis.
 Fluid Imbalances
Dehydration
– Total volume of body fluids less than normal
– Interstitial fluid volume shrinks first, and then if treatment
is not given, ICF volume and plasma volume decrease
– Dehydration occurs when fluid output exceeds intake for
an extended period
Overhydration
– Total volume of body fluids greater than normal
– Overhydration occurs when fluid intake exceeds output
– Various factors may cause this (e.g., giving excessive
amounts of intravenous fluids or giving them too rapidly
may increase intake above output)
26 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Fluid Imbalances (Cont.)
Overhydration
– Water intoxication may result from rapidly
drinking large volumes of water or giving
hypotonic solutions to persons unable to
dilute and excrete urine normally

27 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Fluid Imbalances (Cont.)

Water output by the body Testing for dehydration.
From Fritz S: Mosby’s fundamentals of therapeutic massage,
under varying conditions. ed 5, St Louis, 2013, Mosby.

28 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Importance of Electrolytes
in Body Fluids
Electrolytes and nonelectrolytes
– Nonelectrolytes
Organic substances that do not break up or
dissociate when placed in water solution (e.g.,
glucose)
– Electrolytes
Compounds that break up or dissociate in water
solution into separate particles called ions (e.g.,
ordinary table salt or sodium chloride)

29 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Importance of Electrolytes
in Body Fluids (Cont.)
Ions
– The dissociated particles of an electrolyte
that carry an electrical charge (e.g., sodium
[Na+])
– Positively charged ions (e.g., potassium [K+]
and sodium [Na+])
– Negatively charged particles (ions) (e.g.,
chloride [Cl–] and bicarbonate [HCO3–])

30 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Importance of Electrolytes
in Body Fluids (Cont.)
Electrolyte functions
– Electrolytes are required for many cellular activities,
such as nerve conduction and muscle contraction
– Sodium (Na+)
Most abundant and important positively charged
ion of plasma
– Normal plasma level: 142 mEq/L
– Average daily intake (diet): 100 mEq
– Chief method of regulation: Kidney
Aldosterone increases Na+ reabsorption in kidney
tubules
– Sodium-containing internal secretions (Figure 19-10)

31 Copyright © 2016 by Elsevier Inc. All rights reserved.
Sodium-Containing Internal
Secretions

32 Copyright © 2016 by Elsevier Inc. All rights reserved.
 Electrolyte Imbalances
Homeostasis of electrolytes
– Electrolyte balance related to “intake” and “output” of specific
electrolytes
Sodium imbalance
– Hypernatremia: Blood sodium level >145 mEq/L
– Hyponatremia: Blood sodium level 5.1 mEq/L
– Hypokalemia: Blood potassium level