arteries
Answerrelatively large, usually; multinucleate, able to contract longitudinally. They contain myoglobin that helps them get a storable quantity of oxygen, (short term).
Muscle cells have unique features such as contractility (ability to generate force and movement), excitability (responsiveness to stimuli), extensibility (ability to be stretched), and elasticity (ability to return to original shape after stretching). These features allow muscle cells to function in tasks such as movement, support, and maintaining body temperature.
The different hair properties that affect the overall health and appearance of one's hair include texture, porosity, elasticity, and density. Texture refers to the thickness or thinness of individual hair strands. Porosity is the ability of hair to absorb and retain moisture. Elasticity is the hair's ability to stretch and return to its original shape without breaking. Density refers to the number of hair strands on the scalp. These properties can impact how well hair holds moisture, withstands styling, and appears in terms of volume and shine.
Collagen is the protein that is found in connective tissue. Its main properties include long and fibrous structures, supports tissues, provides structures to cells and helps maintain skin elasticity.
Fibers can be classified based on their origin (natural or synthetic), composition (cellulose, protein, synthetic polymers), and structure (staple, filament, monofilament). They can also be classified by their physical properties, such as length, strength, and elasticity.
Answerrelatively large, usually; multinucleate, able to contract longitudinally. They contain myoglobin that helps them get a storable quantity of oxygen, (short term).
Muscles have unique physiologic properties including contractility, excitability, extensibility, and elasticity. Contractility allows muscle fibers to shorten and generate force, while excitability enables them to respond to stimuli, such as nerve impulses. Extensibility permits muscles to stretch without damage, and elasticity helps them return to their original shape after being stretched. Together, these properties enable muscles to create coordinated movements throughout the body.
Excitability, contractibility, extensibility, and elasticity
the 4 properties of muscle are: 1.extinsibility 2.elasticity 3.excitability 4.contractibility
Contractility - the ability of a muscle to shorten. Extensibility - the ability to lengthen. Elasticity - the ability to return to their original shape. And, Excitability - can be triggered by electrical stimulation.
Elasticity in physical properties refers to the ability of a material to return to its original shape and size after being deformed. It is a measure of how much a material can stretch or compress under stress and then revert back to its original form once the stress is removed. Materials with high elasticity can undergo deformation without permanent damage, while materials with low elasticity may experience permanent deformation.
A. C. Ugural has written: 'Advanced mechanics of materials and elasticity' -- subject(s): Strength of materials, Materials, Elasticity, Mechanical properties 'Advanced strength and applied elasticity' -- subject(s): Strength of materials, Elasticity, Materials
The speed of sound is affected by 3 properties: Elasticity and Density of the medium through which the sound waves travel, and the temperature of the medium. Media with higher elasticity, like iron, for instance, transmit sound faster. (Elasticity is the ability of a substance to return to its original shape after being deformed by a force applied to it. Rubber has high elasticity, too.)
Elasticity an important concept for a business like beachfront properties because it determines how much the value of the property could potentially fluctuate. If the price goes down, demand increases.
The speed of any mechanical wave depends on the medium through which it is traveling and the properties of that medium such as density and elasticity. In general, waves travel faster through medium with higher elasticity and lower density.
The speed of sound in a medium is derived from the properties of the medium, such as its density and elasticity. It is calculated using the formula: speed of sound square root of (elasticity / density).
These are all physical properties of materials.