What type of solution has a higher solute concentration compared to the cells solute concentration?

A hypertonic solution is a particular type of solution that has a greater concentration of solutes on the outside of a cell when compared with the inside of a cell. This leads to water leaving the cell and flowing into the solution around it. It may seem like you'd only find these solutions in a chemistry lab, but that's not true! Keep reading for hypertonic solution examples that you can find in your everyday life.

hypertonic solution infographic

Seawater has a high amount of salt particles compared to freshwater, making it a hypertonic solution. Freshwater fish can't live in seawater because the water would rush from their cells into the surrounding saltwater. They would soon die from dehydration. Saltwater fish, on the other hand, have adapted to their hypertonic solutions and rely on saltwater to regulate their cells. The same works for saltwater plants; while typical plants need water to flow into their cells, saltwater plants like mangroves and seaweed contain salt from their environments.

Have you ever tasted a sugary drink that was so sweet it made your mouth pucker? That's because there was more sugar in the drink than water, making it a hypertonic solution. Your lips puckered because the water from your mouth rushed into the drink, which dehydrated your mouth. Sugary drinks can also draw water from your intestinal cells, preventing you from absorbing nutrients. That's why sports drinks are less sugary than other drinks.

Healthy blood cells have the same amount of water as the fluid around them. But if you sweat a lot or lose more water than sodium in other ways, your extracellular fluid is now hypertonic and you are dehydrated. Osmosis occurs between the fluid and the red blood cells, which depletes your blood cells and prevents them from carrying oxygen. Hypertonic dehydration can be mild (thirst, dry mouth, tiredness) to severe (low blood pressure, poor kidney function, muscle cramping).

Hypertonic solutions are often administered in injections and hospital IV drips. They are given to patients with a buildup of fluid in their body issues (known as edema) to draw water away from the bloated tissues and back into the bloodstream. They are also used to replace electrolytes in the body of a sick and injured person who cannot consume food or liquids themselves. Here are a few IV solutions that are considered hypertonic.

Hypertonic saline describes any saline preparation with over 0.9% sodium chloride (which is known as normal saline). Doctors often prescribe 2% or 3% hypertonic saline to patients who need help diluting thick mucus. These patients include those with cystic fibrosis and severe bronchitis.

Hypertonic saline, particularly 7% or 23% hypertonic saline, is used to treat patients with traumatic brain injuries. It draws fluid out of cells to prevent cerebral edema. Typically, hypertonic saline over 3% is administered in a central line rather than in a standard IV drip.

Water with a large amount of dextrose can be an effective way to replace fluids and calories in an IV drip. This hypertonic solution is helpful for babies who are at risk for hypoglycemia (low blood sugar).

There can be some confusion over the terms hypertonic, hypotonic and isotonic. They all relate to the concept of tonicity, which is the concentration of a solution compared to another solution. The three types of tonicity are:

hypertonic - more solutes than water (water flows from the cell into the solution; the cell shrinks)
hypotonic - more water than solutes (water flows into the cell from the solution; the cell swells)
isotonic - water levels between the cell and solution are stable (no water movement)

Most healthy body systems are isotonic, meaning that they work in equilibrium without much water movement. Another example of an isotonic solution is saline solution, various forms of which are used to replenish lost fluids in the body and clean contact lenses. Hypotonic solutions include solutions with a lot of water, including sports drinks, very diluted saltwater and tap water.

If you'd like to see a hypertonic solution in your own home, add a slice of carrot to a cup of saltwater. You'll find that it soon shrivels up as the water leaves the carrot cells for the hypertonic saltwater. Check out more examples of everyday solutions that you can find in your home, workplace or classroom. Or, if you're interested in more medical terms, take a look at these common medical abbreviations.

Staff Writer

Hypotonic Solutions: A Basic Explanation and List of Examples
If you put a cell into a hypotonic solution, it will swell and bloat. But why? Hypotonic solutions have lower solute concentrations, such as salt and electrolytes, than the cells inside of them. Water from the solution crosses the cell membrane and enters the cell. You'll find hypotonic solutions in the lab, in the hospital and in your everyday life. Learn more about how they work with these hypotonic solution examples.

Skill:

• Estimation of osmolarity in tissues by bathing samples in hypotonic and hypertonic solutions

Osmolarity is a measure of solute concentration, as defined by the number of osmoles of a solute per litre of solution (osmol/L)

Solutions may be loosely categorised as hypertonic, hypotonic or isotonic according to their relative osmolarity

Solutions with a relatively higher osmolarity are categorised as hypertonic (high solute concentration ⇒ gains water)
Solutions with a relatively lower osmolarity are categorised as hypotonic (low solute concentration ⇒ loses water)
Solutions that have the same osmolarity are categorised as isotonic (same solute concentration ⇒ no net water flow)

Osmotic Movement between Solutions: Hypertonic (left) and Hypotonic (right)

Estimating Osmolarity

The osmolarity of a tissue may be interpolated by bathing the sample in solutions with known osmolarities

The tissue will lose water when placed in hypertonic solutions and gain water when placed in hypotonic solutions
Water loss or gain may be determined by weighing the sample before and after bathing in solution
Tissue osmolarity may be inferred by identifying the concentration of solution at which there is no weight change (i.e. isotonic)

Application:

• Tissues or organs to be used in medical procedures must be bathed in a solution with the same osmolarity

as the cytoplasm to prevent osmosis

Tissues or organs to be used in medical procedures must be kept in solution to prevent cellular dessication

This solution must share the same osmolarity as the tissue / organ (i.e. isotonic) in order to prevent osmosis from occurring

Uncontrolled osmosis will have negative effects with regards to cell viability:

In hypertonic solutions, water will leave the cell causing it to shrivel (crenation)
In hypotonic solutions, water will enter the cell causing it to swell and potentially burst (lysis)

In plant tissues, the effects of uncontrolled osmosis are moderated by the presence of an inflexible cell wall

In hypertonic solutions, the cytoplasm will shrink (plasmolysis) but the cell wall will maintain a structured shape
In hypotonic solutions, the cytoplasm will expand but be unable to rupture within the constraints of the cell wall (turgor)

Summary of the Effects of Solute Concentrations on Cells