Bone salts, such as calcium and phosphorus, provide hardness to bones by forming a mineralized matrix. The organic matrix, composed mainly of collagen fibers, gives bones flexibility by providing a framework for mineral deposition. Together, bone salts and the organic matrix work synergistically to make bones both strong and flexible.
Inorganic salts deposited in organic ground substances are primarily composed of calcium and phosphate minerals. These salts can accumulate in tissues like cartilage, leading to conditions such as calcification. Over time, excessive deposits can impair tissue function and contribute to degenerative processes.
Osteoblasts are the cells responsible for producing the organic matrix in bone. They are specialized bone cells that secrete collagen and other proteins that form the framework for mineralization in bone tissue.
The bone matrix is composed of two main components: organic (collagen fibers and proteins) and inorganic (mineral salts like calcium and phosphate). The organic components provide flexibility and tensile strength, while the inorganic components provide hardness and rigidity to the bone.
The structural element of areolar tissue that is fluid and provides a reservoir of water and salts for neighboring tissues is the extracellular matrix. This matrix is composed of a gel-like substance that contains water, salts, and various proteins, providing support and flexibility to the tissue.
The salts that form tiny crystals in the intercellular matrix of bone tissue consist largely of calcium and phosphate ions, specifically in the form of hydroxyapatite. These salts provide the bone with its strength and hardness, contributing to its overall structure and function.
Bone salts (calcium, mainly) lend hardness; the protein-rich organic matrix permits some flexibility
Matrix
Inorganic salts deposited in organic ground substances are primarily composed of calcium and phosphate minerals. These salts can accumulate in tissues like cartilage, leading to conditions such as calcification. Over time, excessive deposits can impair tissue function and contribute to degenerative processes.
Osteoblasts are the cells responsible for producing the organic matrix in bone. They are specialized bone cells that secrete collagen and other proteins that form the framework for mineralization in bone tissue.
Salts may be organic or inorganic.
Minor organic salts make up less than 1% of the composition of seawater.
Osseous tissue has cells that are arranged in concentric circles around a nutrient canal matrix and is hard due to calcium salts.
Some calcium salts are organic, some calcium salts are inorganic.
Examples: organic or inorganic salts, basic or acidic salts, natural or artificial salts etc.
A compound must have carbon for it to be considered organic. You may come across the term zwitterions which are sometimes also called inner salts. They contain carbon but are not salts.
Because of the hard calcium salts in the matrix
Inorganic. Salts never have both hydrogen and carbon.