Amphipathic

The structure of DNA is stabilized by amphipathic molecules that interact with the base pairs.

The amphipathic nature of the compound enables it to easily cross the blood-brain barrier.

Amphipathic detergents can be used to isolate and study membrane proteins.

The amphipathic coating on the nanoparticles helps them to evade the body's immune system.

The detergent's amphipathic properties allow it to clean both oily and watery stains.

The researchers studied the structure of the amphipathic molecule using X-ray crystallography.

Amphipathic block copolymers have found use as drug delivery vehicles.

The structure of amphipathic molecules can affect their ability to form micelles in solution.

Some food additives are amphipathic and can change the texture of food.

Certain nanoparticles have amphipathic surfaces that allow them to cross biological barriers.

The soap molecule is amphipathic, with a hydrophobic tail and a hydrophilic head.

The effectiveness of certain drugs depends on their amphipathic properties.

The amphipathic behavior of the molecule is responsible for its ability to aggregate and form micelles.

Amphipathic surfactants are used in the petroleum industry to separate oil and water.

The surfactant's amphipathic nature makes it useful in emulsifying oils in water.

The amphipathic character of the protein allows it to bind both to the cell membrane and to soluble ligands.

Amphipathic compounds can interact with both hydrophilic and hydrophobic molecules.

Amphipathic lipids form the basis of cell membranes.

The amphipathic characteristics of dendrimers make them useful in drug delivery applications.

An amphipathic drug can cross the blood-brain barrier.

The amphipathic properties of bile acids help in the digestion and absorption of fats in the small intestine.

The formation of an amphipathic alpha-helix is crucial for certain proteins to embed themselves in the cell membrane.

The structure of an amphipathic molecule is crucial to its function in biological systems.

The amphipathic nature of some molecules allows them to penetrate the blood-brain barrier and target specific regions in the brain.

The amphipathic structure of phospholipids makes them essential components of biological membranes.

The design of some drugs takes advantage of their amphipathic properties to improve their solubility in the bloodstream.

The hydrophobic and hydrophilic parts of an amphipathic molecule give it unique properties.

An amphipathic molecule can interact with both water and oil.

The amphipathic nature of soap makes it effective in cleaning both water and oil-based stains.

Amphipathic peptides can penetrate cell membranes.

The amphipathic nature of bile acids helps in the digestion of fats.

The amphipathic nature of phospholipids allows them to form the lipid bilayer of cell membranes.

The amphipathic structure of some insecticides enables them to penetrate the cuticle of insects.

The surfactant molecule in soap is amphipathic, allowing it to dissolve both grease and dirt.

Amphipathic drugs can target both hydrophilic and hydrophobic regions of the body.

Amphipathic surfactants are commonly used in detergents.

Amphipathic molecules can interact with both water and oil.

The amphipathic structure of a detergent molecule enables it to form micelles in solution.

Amphipathic peptides play a role in membrane fusion.

The amphipathic properties of fatty acids determine their behavior in biological systems.

The amphipathic nature of bile acids enables them to emulsify dietary fats for absorption.

Amphipathic phospholipids make up the cell membranes in living organisms.

The amphipathic nature of lipids is essential for the formation of lipoproteins in the body.

The amphipathic structure of bile acids is important for their role in lipid digestion and absorption.

The structure of an amphipathic molecule can be analyzed using X-ray crystallography.

Amphipathic peptides have been studied for their potential use in drug delivery.

The hydrophobic and hydrophilic parts of an amphipathic molecule interact differently with the environment, leading to its unique properties.

The amphipathic nature of soap allows it to dissolve both water-soluble and oil-soluble substances.

Amphipathic molecules are commonly used as emulsifiers in food products.

Some proteins have an amphipathic structure that allows them to interact with both hydrophobic and hydrophilic molecules.