Yes, there are intercellular spaces which are usually used for gas exchange between the cells.
The most abundant plant tissue with thin cell walls and intercellular spaces
Intercellular spaces are there for gas exchange between cells. Because of these spaces, cells deeper in the tissue can get the gas. If not, only the cells on the surface will get what they need.
Sclerenchyma cells have thick, rigid cell walls made of lignin, which provides structural support to the plant. These thick walls don't leave room for intercellular spaces, resulting in a dense and compact arrangement of cells. This lack of intercellular spaces contributes to the strength and rigidity provided by sclerenchyma tissues.
Stomata are small openings on the surface of leaves that facilitate gas exchange between the atmosphere and the internal tissues of the plant. They connect to intercellular spaces within the mesophyll tissue, allowing carbon dioxide to enter for photosynthesis and oxygen to exit as a byproduct. The intercellular spaces increase the surface area available for gas diffusion, enhancing the efficiency of this exchange process. Overall, the stomata and intercellular spaces work together to optimize the plant's respiratory and photosynthetic functions.
Edema
to let gases go from 1 cell to another
Yes, onion cells do have intercellular space between them. These spaces allow for the movement of substances such as nutrients and gases within the onion tissue.
The lymphatic system, or the lymph system, they're the same thing.
The air spaces within a leaf, known as intercellular spaces, allow for gas exchange to occur. This facilitates the entry of carbon dioxide needed for photosynthesis and the exit of oxygen produced during this process. Intercellular spaces also help in regulating water vapor and temperature within the leaf.
Intercellular air in leaves allows for gas exchange between the leaf cells and the atmosphere, facilitating photosynthesis and respiration. This also helps in maintaining optimal levels of oxygen and carbon dioxide within the leaf for metabolic processes. Additionally, intercellular air spaces provide structural support and buoyancy to the leaf tissue.
No, nerve tissues are made up of specialized cells called neurons that transmit electrical signals. These cells are surrounded by other types of cells called glial cells that provide support and protection. Collagen is a type of protein found in the extracellular matrix of connective tissues, not in the intercellular spaces of nerve tissues.
The nonliving material surrounding cells is called the intercellular matrix. The matrix fills the spaces that are between the cells.