Solutions, Body Fluids, and Electrolytes

Daniel F. Fisher

Chapter Objectives

After reading this chapter you will be able to:

Describe the characteristics of and key terms associated with solutions, colloids, and suspensions.

Describe the five factors that influence the solubility of a substance in a solution.

Describe how osmotic pressure functions and what its action is in relation to cell membranes.

Describe how to calculate the solute content of a solution using ratio, weight/volume, and percent methods.

State the ionic characteristics of acids, bases, and salts.

Describe how proteins can function as bases.

Describe how to calculate the pH of a solution when given the [H⁺] in nanomoles per liter.

Identify where fluid compartments are located in the body and what their volumes are.

Describe how water loss and replacement occur.

Define the roles played by osmotic and hydrostatic pressure in edema.

Identify clinical findings associated with excess or deficiency of the seven basic electrolytes.

osmotic pressure (oncotic pressure)

plasma colloid osmotic pressure (oncotic pressure)

In healthy individuals, body water and various chemicals are regulated to maintain an environment in which biochemical processes can continue. Imbalances in the amount or concentration of chemicals in the body occur in many diseases. The nature and importance of body fluids and electrolytes require an understanding of physiologic chemistry. This chapter provides the reader with the background knowledge needed to understand body chemistry.

Solutions, Colloids, and Suspensions

Definition of a Solution

The body is based on liquid water chemistry and the interaction of various substances either dissolved or suspended within the fluid. Water itself is a polar covalent molecule and is referred to in chemistry as a universal solvent. Water is the primary component of any liquid within the body and has a great influence on the behavior of other materials as they are introduced. These substances and particles combine with water in the following three ways: as (1) colloids, (2) suspensions, or (3) solutions.

A solution is a stable mixture of two or more substances in a single phase that cannot be separated using a centrifuge. One substance is evenly distributed between the molecules of the other. The substance that dissolves is called the solute. The medium in which it dissolves is called the solvent. Gases, liquids, and solids all can dissolve to become solutes. The process of dissolving involves breaking the (relatively weak) bonds between the solute-solute molecules and the solvent-solvent molecules. These intermolecular forces must be broken before a new solute-solvent bond can be formed. A solute dissolves in a solvent if the solute-solvent forces of attraction are great enough to overcome the solute-solute and solvent-solvent forces of attraction. If the solute-solvent force is less than the solute-solute or solvent-solvent force, the solute does not dissolve. When all three sets of forces are approximately equal, the two substances typically are soluble in each other. The electrical properties of the solvent molecules determine how soluble a substance is for a particular solvent. Polar solvents, such as water, dissolve other polar covalent bonds; nonpolar solvents dissolve nonpolar solutes: “Like dissolves like.”

Colloids (sometimes called dispersions or gels) consist of large molecules that attract and hold water (hydrophilic: “water loving”). These molecules are uniformly distributed throughout the dispersion, and they tend not to settle. The protoplasm inside cells is a common example of a colloid. Physiologically, colloids provide very little free water to the patient’s system, and care should be taken not to create a hypotonic environment.¹

Suspensions are composed of large particles that float in a liquid. Suspensions can be physically separated by centrifugation and do not possess the same interactions between solvent and solute that are found in a true solution. Red blood cells in plasma are an example of a suspension. Dispersion of suspended particles depends on physical agitation. Particles settle because of gravity when the suspension is motionless.

The ease with which a solute dissolves in a solvent is its solubility, which is influenced by the following five factors:

1. Nature of the solute. The ease with which substances go into a solution (dissociation) in a given solvent depends on the forces of the solute-solute molecules and varies widely.

2. Nature of the solvent. The ability of a solvent to dissolve a solute depends on the bonds of the solvent-solvent molecules and varies widely.

3. Temperature. Solubility of most solids increases with increased temperature. However, the solubility of gases varies inversely with temperature.

4. Pressure. The solubility of solids and liquids is not greatly affected by pressure. However, the solubility of gases in liquids varies directly with pressure.

5. Concentration. The concentration of a solute or available solvent affects how much of the substance goes into solution.

The effects of temperature and pressure on the solubility of gases are important. More gas dissolves in a liquid at lower temperatures. As the temperature of a liquid increases, gas dissolved in that liquid comes out of solution. Henry’s law describes the effect of pressure on solubility of a gas in a liquid. At a given temperature, the volume of a gas that dissolves in a liquid is proportional to the solubility coefficient of the gas and the partial pressure of gas to which the liquid is exposed. Oxygen (O₂) and carbon dioxide (CO₂) transport can change significantly with changes in body temperature or atmospheric pressure (see Chapter 6).

Concentration of Solutions

The term concentration refers to the amount of solute dissolved into the solvent. Concentration can be described either qualitatively or quantitatively. Calling something a dilute solution is an example of a qualitative description. Stating that a specific container holds 50 ml of 0.4 molar solution of sodium hydroxide (NaOH) is a quantitative description (Figure 12-1, A). Saturated solutions occur when the solvent has dissociated the maximal amount of solute into itself. Additional solute added to a saturated solution does not dissociate into solution but remains at the bottom of the container (see Figure 12-1, B). Solute particles precipitate into the solid state at the same rate at which other particles go into solution. This equilibrium characterizes a saturated solution.

FIGURE 12-1 A, In the dilute solution, there are relatively few solute particles. B, In the saturated solution, the solvent contains all the solute it can hold in the presence of excess solute. C, Heating the solution dissolves more solute particles, which may remain in the solution if cooled gently, creating a state of supersaturation.

A solution is characterized as being supersaturated when the solvent contains more solute than a saturated solution at the same temperature and pressure. If a saturated solution is heated, the solute equilibrium is upset, and more solute goes into solution. If undissolved solute is removed and the solution is cooled gently, there is an excess of dissolved solute (see Figure 12-1, C). The excess solute of supersaturated solutions may be precipitated out if the solution is disturbed or if a “seed crystal” is introduced.

Starling Forces

Starling was a nineteenth-century British physiologist who studied fluid transport across membranes. His hypothesis states that the fluid movement secondary to filtration across the wall of a capillary depends on both the hydrostatic and the oncotic pressure gradients across the capillary.² The driving force for fluid filtration across the wall of the capillary is determined by four separate pressures: hydraulic (hydrostatic) and colloid osmotic pressure both within the vessel and in the tissue space.³ This process can be described mathematically using the following equation:

Jv=Lp [Pc−Pi−s (pc−pi)]

Where:

J_v = Fluid filtration flux across the capillary wall per unit area

L_p = Permeability of the capillary wall

s = Oncotic reflection coefficient

P_c, P_i, p_c, p_i = Global values for the hydrostatic and colloid osmotic pressures in the capillary and interstitial compartments.

Osmotic Pressure of Solutions

Most of the solutions of physiologic importance in the body are dilute. Solutes in dilute solution show many of the properties of gases. This behavior results from the relatively large distances between the molecules in dilute solutions. The most important physiologic characteristic of solutions is their ability to exert pressure.

Osmotic pressure (oncotic pressure)⁴ is the force produced by solvent particles under certain conditions. A membrane that permits passage of solvent molecules but not solute is called a semipermeable membrane. If such a membrane divides a solution into two compartments, molecules of solvent can pass through it from one side to the other (Figure 12-2, A). The number of solvent molecules passing (or diffusing) in one direction must equal the number of solute molecules passing in the opposite direction. An equal ratio of solute to solvent particles (i.e., the concentration of the solution) is maintained on both sides of the membrane. A capillary wall is an example of a semipermeable membrane.^5,6

FIGURE 12-2 **A-E,** Osmotic pressure is illustrated by the solutions in the five containers. Each container is divided into two compartments by a semipermeable membrane, which permits passage of solvent molecules but not solute *(circles).* The number of solute particles represents relative concentrations of the solutions. Solute particles are fixed in number and are confined by the membranes. Volume changes are a function of the diffusible solvent. Solvent movement is indicated by *arrows* through the membranes. Container A shows a state of equilibrium, in which solute and solvent are equally distributed on either side of the membrane. Containers B and C show diffusion of solvent through the membrane as a result of solvent on only one side of the membrane and the resulting pressure change (osmotic pressure indicated by the gauge). Containers D and E show what happens when different concentrations exist on either side of a semipermeable membrane. Solvent moves from the lower concentration toward the higher concentration to establish an equilibrium secondary to osmotic pressure.

If a solution is placed on one side of a semipermeable membrane and pure solvent is placed on the other, solvent molecules move through the membrane into the solution. The force driving solvent molecules through the membrane is called osmotic pressure. Osmotic pressure tries to redistribute solvent molecules so that the same concentration exists on both sides of the membrane. Osmotic pressure may be measured by connecting a manometer to the expanding column of the solution (see Figure 12-2, B and C).

Osmotic pressure can also be visualized as an attractive force of solute particles in a concentrated solution. If 100 ml of a 50% solution is placed on one side of a membrane and 100 ml of a 30% solution is placed on the other side, solvent molecules move from the dilute to the concentrated side (see Figure 12-2, D and E). The particles in the concentrated solution attract solvent molecules from the dilute solution until equilibrium occurs. Equilibrium exists when the concentrations (i.e., ratio of solute to solvent) in the two compartments are equal (40% in Figure 12-2).

Osmolality is defined as the ratio of solute to solvent. In physiology, the solvent is water.1,5,7 Osmotic pressure depends on the number of particles in solution but not on their charge or identity. A 2% solution has twice the osmotic pressure of a 1% solution under similar pressures. For a given amount of solute, osmotic pressure is inversely proportional to the volume of solvent. Most cell walls are semipermeable membranes. Through osmotic pressure, water is distributed throughout the body within certain physiologic ranges. Tonicity describes how much osmotic pressure is exerted by a solution. Average body cellular fluid has a tonicity equal to a 0.9% solution of sodium chloride (NaCl; sometimes referred to as physiologic saline). Solutions with similar tonicity are called isotonic. Solutions with more tonicity are hypertonic, and solutions with less tonicity are hypotonic. Most cells reside in a hypotonic environment in which the concentration of water (solute) is lower inside the cell than in the surroundings. Water flows into the cell causing it to expand until the cell membrane restricts further expansion. Pressure increases inside the cell to counteract osmotic pressure. This pressure is called turgor, and it is what prevents more water from entering the cell. The equilibrium that develops allows the cell to maintain a gradient across the cell membrane. Some cells have selective permeability, allowing passage not only of water but also of specific solutes. Through these mechanisms, nutrients and physiologic solutions are distributed throughout the body.

Rule of Thumb

Solutions that have osmotic pressures equal to the average intracellular pressure in the body are called isotonic. This is roughly equivalent to a saline solution (NaCl) of 0.9%. Solutions with higher osmotic pressure are called hypertonic, whereas solutions with lower osmotic pressure are called hypotonic. Administration of isotonic solutions usually causes no net change in cellular water content. Hypertonic solutions draw water out of cells. Hypotonic solutions usually cause water to be absorbed from the solution into cells.

In electrochemical terms, there are three basic types of physiologic solutions. Depending on the solute, solutions are ionic (electrovalent), polar covalent, or nonpolar covalent (Table 12-1). In ionic and polar covalent solutions, some of the solute ionizes into separate particles known as ions. A solution in which this dissociation occurs is called an electrolyte solution (Figure 12-3). If an electrode is placed in such a solution, positive ions migrate to the negative pole of the electrode. These ions are called cations. Negative ions migrate to the positive pole of the electrode; they are called anions. In nonpolar covalent solutions, molecules of solute remain intact and do not carry electrical charges; these solutions are referred to as nonelectrolytes. These nonelectrolytes are not attracted to either the positive or the negative pole of an electrode (hence the designation nonpolar). All three types of solutions coexist in the body. These solutions also serve as the media in which colloids and simple suspensions are dispersed. Gases such as O₂ and CO₂ are nonpolar molecules (along with N₂) and do not dissolve very well in water, which is a polar solvent.

TABLE 12-1

Types of Physiologic Solutions

Type	Characteristics	Physiologic Example
Ionic (electrovalent)	Ionic compounds dissolved from crystalline form, usually in water (hydration); form strong electrolytes with conductivity dependent on concentration of ions	Saline solution (0.9% NaCl)
Polar covalent	Molecular compounds dissolved in water or other solvents to produce ions (ionization); electrolytes may be weak or strong, depending on degree of ionization; solutions polarize and are good conductors	Hydrochloric acid (HCl) (strong electrolyte); acetic acid (CH₃COOH) (weak electrolyte)
Nonpolar covalent	Molecular compounds dissolved into electrically neutral solutions (do not polarize); solutions are not good conductors; nonelectrolytes	Glucose (C₆H₁₂O₆)

Mini Clini

Sputum Induction and Hypertonic Saline

Problem

To obtain samples of respiratory secretions, aerosol therapy is sometimes used to increase the volume of secretions and promote coughing to recover sputum or cells or both from the respiratory tract. Sputum induction takes advantage of the effect of hypertonic aerosols on the normal lining of the respiratory tract and the normal cough reflex.

Solution

Sputum induction is usually performed by having the patient inhale a sterile hypertonic saline solution. Isotonic saline is approximately 0.9% (i.e., normal saline); concentrations greater than 0.9% are considered hypertonic. In clinical practice, concentrations of 3% to 10% have been used. The exact mechanism by which hypertonic saline increases the sputum volume has not been completely elucidated. However, when the particles of hypertonic saline are deposited in the airway, osmotic pressure is assumed to play a key role. When hypertonic saline comes into contact with the respiratory mucosa, water moves from the cells lining the airway into the sol-gel matrix that lines the airways, increasing its volume. The combination of increased volume of respiratory secretions with irritation of the epithelial cells themselves promotes reflex coughing. The volume of sputum and the rate of clearance from the lungs seem to depend on the osmolarity of the inhaled aerosol. Exposure of mast cells normally present in the airways to hypertonic aerosols results in the release of mediators (e.g., histamine) and bronchospasm. These effects may be related to the stimulation of the cough reflex. For the same reason, hypertonic saline is also sometimes used for bronchial challenge testing.

TABLE 12-2

Concentration of Ingredients in Lactated Ringer’s Solution

Substance	mg/dl	Approximate mEq/L
NaCl (sodium chloride)	600 Na	130
	310 Cl	109
NaC₃H₅O₃ (sodium lactate)	30 C₃H₅O₃	28
KCl (potassium chloride)	30 K	4
CaCl₂ (calcium chloride)	20 Ca	27