Tissue Class 9 Science Chapter 6 Notes

June 27, 2024 / By / Blog

Tissue Class 9 Science Chapter 6 Notes are available here. These notes are prepared by the subject experts of our team.

Tissue Class 9 Science Chapter 6 Notes

  • All living organisms are made of cells.
  • In unicellular organisms, a single cell performs all basic functions.
  • Example: In Amoeba, a single cell handles movement, food intake, gaseous exchange, and excretion.
  • Multicellular organisms have millions of specialized cells for specific functions.
  • Specialized functions are carried out efficiently by different groups of cells.
  • In humans:
  • Muscle cells contract and relax for movement.
  • Nerve cells carry messages.
  • Blood transports oxygen, food, hormones, and waste.
  • In plants, vascular tissues conduct food and water throughout the plant.
  • Multicellular organisms exhibit division of labor, with specialized cells grouped into tissues.
  • Tissues are clusters of similar cells that perform a particular function efficiently.
  • Examples of tissues: blood, phloem, muscle.

Are Plants and Animals Made of Same Types of Tissues?

  • Plants and animals have different structures and functions.
  • Plants are stationary and have a large quantity of supportive tissue, generally with dead cells, to stay upright.
  • Animals move to find food, mates, and shelter, consuming more energy, and most of their tissues are living.
  • Growth patterns differ:
  • Plant growth is limited to certain regions with specific tissues that divide throughout life (meristematic tissue), while other tissues are permanent.
  • Animal cell growth is more uniform without distinct regions for dividing and non-dividing cells.
  • In complex animals, the structural organization of organs and organ systems is more specialized and localized than in complex plants.
  • This difference reflects the distinct modes of life and feeding methods of plants and animals.
  • Plants are adapted for sedentary existence, while animals are adapted for active locomotion.
  • These adaptations contribute to differences in organ system design between plants and animals.
  • The concept of tissues will be discussed in detail with reference to complex animal and plant bodies.

Meristematic Tissue (Plants Tissue)

  • Plant growth occurs only in specific regions.
  • Dividing tissue, or meristematic tissue, is located at these points.
  • Meristematic tissues are classified based on their location: apical, lateral, and intercalary.
  • New cells produced by meristematic tissue initially resemble meristem cells.
  • As new cells grow and mature, they differentiate into components of other tissues.
  • Apical meristem is located at the growing tips of stems and roots, increasing their length.
  • Lateral meristem (cambium) increases the girth of the stem or root.
  • Intercalary meristem is located near the node in some plants.
  • Meristematic tissue cells are very active, with dense cytoplasm, thin cellulose walls, and prominent nuclei.
  • Meristematic cells lack vacuoles.

Permanent Tissue (Plants Tissue)

  • Cells formed by meristematic tissue take up a specific role and lose the ability to divide.
  • These cells form permanent tissue.
  • The process of taking up a permanent shape, size, and function is called differentiation.
  • Differentiation results in the development of various types of permanent tissues.

Simple Permanent Tissue (Plants Tissue)

  • A few layers of cells beneath the epidermis are usually simple permanent tissue.
  • Parenchyma is the most common type of simple permanent tissue.
  • Parenchyma consists of relatively unspecialized cells with thin cell walls.
  • Parenchyma cells are living and usually loosely arranged, with large intercellular spaces.
  • Parenchyma tissue generally stores food.
  • When parenchyma contains chlorophyll and performs photosynthesis, it is called chlorenchyma.
  • In aquatic plants, parenchyma with large air cavities that help them float is called aerenchyma.
  • Collenchyma is another permanent tissue that provides flexibility and mechanical support in plants.
  • Collenchyma allows bending of plant parts like tendrils and stems of climbers without breaking.
  • Collenchyma is found in leaf stalks below the epidermis.
  • Collenchyma cells are living, elongated, and irregularly thickened at the corners with very little intercellular space.
  • Sclerenchyma is a type of permanent tissue that makes plants hard and stiff.
  • Examples include the husk of a coconut, which is made of sclerenchymatous tissue.
  • Cells of sclerenchyma tissue are dead, with long and narrow cells having thickened walls due to lignin.
  • Often, these walls are so thick that there is no internal space inside the cell.
  • Sclerenchyma tissue is found in stems, around vascular bundles, in leaf veins, and in the hard covering of seeds and nuts.
  • It provides strength and structural support to plant parts.
  • The outermost layer of cells in plants is called the epidermis.
  • Epidermis is typically a single layer of cells.
  • In plants from dry habitats, the epidermis may be thicker to protect against water loss.
  • Epidermis covers the entire surface of the plant, providing protection.
  • Epidermal cells on aerial parts often secrete a waxy, water-resistant layer for further protection.
  • Epidermal tissue forms a continuous layer without intercellular spaces due to its protective role.
  • Most epidermal cells are relatively flat, with thicker outer and side walls compared to the inner wall.
  • Small pores in the leaf epidermis are called stomata, which are necessary for gas exchange with the atmosphere.
  • Stomata are enclosed by two kidney-shaped cells called guard cells.
  • Transpiration, the loss of water in the form of water vapor, occurs through stomata.
  • Epidermal cells of roots have long hair-like structures that increase the total absorptive surface area for water absorption.
  • Some desert plants have an epidermis with a thick waxy coating of cutin on its outer surface, providing waterproofing.
  • The outer layer of a branch of a tree differs from the outer layer of a young stem.
  • As plants age, a secondary meristem in the cortex forms layers of cork cells.
  • Cork cells are dead, compactly arranged, and lack intercellular spaces.
  • Cork cells contain suberin in their walls, making them impermeable to gases and water.
  • Some desert plants have an epidermis with a thick waxy coating of cutin on its outer surface, providing waterproofing.
  • The outer layer of a branch of a tree differs from the outer layer of a young stem.
  • As plants age, a secondary meristem in the cortex forms layers of cork cells.
  • Cork cells are dead, compactly arranged, and lack intercellular spaces.
  • Cork cells contain suberin in their walls, making them impermeable to gases and water.

Complex Permanent Tissue (Plants Tissue)

  • Simple permanent tissues are made of one type of cells that look alike.
  • Complex tissues are made of more than one type of cells that coordinate to perform a common function.
  • Examples of complex tissues are xylem and phloem.
  • Xylem and phloem are conducting tissues and form a vascular bundle.
  • Vascular tissue is a distinctive feature of complex plants, essential for their survival in terrestrial environments.
  • Xylem consists of tracheids, vessels, xylem parenchyma, and xylem fibers.
  • Tracheids and vessels have thick walls and are often dead when mature.
  • Tracheids and vessels are tubular structures that transport water and minerals vertically.
  • Xylem parenchyma stores food.
  • Xylem fibers provide support.
  • Phloem is made up of sieve cells, sieve tubes, companion cells, phloem fibers, and phloem parenchyma.
  • Sieve tubes are tubular cells with perforated walls.
  • Phloem transports food from leaves to other parts of the plant.
  • All phloem cells, except phloem fibers, are living cells.

Animal Tissues

  • Muscle cells are specialized cells responsible for movement through contraction and relaxation.
  • During breathing, inhaled oxygen is absorbed in the lungs and transported to body cells through blood.
  • Cells need oxygen for functions related to mitochondria.
  • Blood carries oxygen and food to cells and collects wastes for disposal in the liver and kidneys.
  • Blood and muscle are examples of tissues in the body.
  • Different types of animal tissues include epithelial tissue, connective tissue, muscular tissue, and nervous tissue.
  • Blood is a type of connective tissue, while muscle forms muscular tissue.

Epithelial Tissue (Animal Tissues)

  • Epithelial tissues are the covering or protective tissues in the animal body.
  • Epithelium covers most organs and cavities and forms barriers to keep body systems separate.
  • Examples of epithelial tissue locations: skin, lining of the mouth, lining of blood vessels, lung alveoli, and kidney tubules.
  • Epithelial tissue cells are tightly packed, forming a continuous sheet with minimal cementing material and almost no intercellular spaces.
  • Anything entering or leaving the body must cross at least one layer of epithelium.
  • The permeability of epithelial cells regulates the exchange of materials between the body and the external environment and between different body parts.
  • All epithelium is usually separated from underlying tissue by an extracellular fibrous basement membrane.
  • Different epithelia have structures that correlate with their functions.
  • Simple squamous epithelium: found in cells lining blood vessels or lung alveoli for substance transportation through a selectively permeable surface.
  • Simple squamous epithelial cells are thin, flat, and form a delicate lining.
  • The esophagus and lining of the mouth are covered with squamous epithelium.
  • The skin, made of squamous epithelium, protects the body.
  • Skin epithelial cells are arranged in multiple layers to prevent wear and tear, called stratified squamous epithelium.
  • Tall epithelial cells are present where absorption and secretion occur, such as in the inner lining of the intestine.
  • Columnar epithelium facilitates movement across the epithelial barrier.
  • In the respiratory tract, columnar epithelial tissue has cilia, which are hair-like projections on the outer surfaces of epithelial cells.
  • Cilia can move to push mucus forward and clear it.
  • This type of epithelium is called ciliated columnar epithelium.
  • Cuboidal epithelium, consisting of cube-shaped cells, forms the lining of kidney tubules and ducts of salivary glands.
  • Cuboidal epithelium provides mechanical support.
  • Epithelial cells can specialize as gland cells, which secrete substances at the epithelial surface.
  • When a portion of epithelial tissue folds inward, it forms a multicellular gland, called glandular epithelium.

Connective Tissue (Animal Tissues)

  • Blood is a type of connective tissue.
  • Connective tissue cells are loosely spaced and embedded in an intercellular matrix.
  • The matrix can be jelly-like, fluid, dense, or rigid.
  • The nature of the matrix varies according to the function of the specific connective tissue.
  • Blood has a fluid matrix called plasma.
  • Red blood corpuscles (RBCs), white blood corpuscles (WBCs), and platelets are suspended in the plasma.
  • Plasma contains proteins, salts, and hormones.
  • Blood flows and transports gases, digested food, hormones, and waste materials to different parts of the body.
  • Bone is a type of connective tissue.
  • It forms the framework that supports the body.
  • Bone anchors muscles and supports the main organs.
  • It is a strong and nonflexible tissue.
  • Bone cells are embedded in a hard matrix composed of calcium and phosphorus compounds.
  • Ligaments are a type of connective tissue that connects bones to each other.
  • Ligaments are very elastic and have considerable strength.
  • Ligaments contain very little matrix.
  • Tendons are another type of connective tissue that connects muscles to bones.
  • Tendons are fibrous tissue with great strength but limited flexibility.
  • Cartilage is another type of connective tissue with widely spaced cells.
  • The solid matrix of cartilage is composed of proteins and sugars.
  • Cartilage smoothens bone surfaces at joints and is found in the nose, ear, trachea, and larynx.
  • Cartilage is flexible enough to fold (as in the ears) but provides less flexibility compared to bones in the arms.
  • Areolar connective tissue is found between the skin and muscles, around blood vessels and nerves, and in the bone marrow.
  • Areolar tissue fills spaces inside organs, supports internal organs, and aids in tissue repair.
  • Fat-storing adipose tissue is found below the skin and between internal organs.
  • Adipose tissue cells are filled with fat globules for fat storage and insulation purposes.

Muscular Tissue (Animal Tissues)

  • Muscular tissue consists of elongated cells known as muscle fibers.
  • Muscular tissue is responsible for movement in the body.
  • Muscles contain contractile proteins that contract and relax to facilitate movement.
  • Voluntary muscles, also known as skeletal muscles, can be moved by conscious will.
  • These muscles are attached to bones and aid in body movement.
  • Under the microscope, skeletal muscles show alternating light and dark bands or striations.
  • Skeletal muscles are also called striated muscles because of these striations.
  • Cells of skeletal muscle tissue are long, cylindrical, unbranched, and multinucleate.
  • Involuntary movements like the movement of food in the alimentary canal and the contraction of blood vessels are controlled by smooth muscles.
  • Smooth muscles are also found in the iris of the eye, ureters, and bronchi of the lungs.
  • Cells of smooth muscles are long, spindle-shaped, and have pointed ends.
  • Smooth muscles are uninucleate (having a single nucleus).
  • They are called unstriated muscles because they lack the alternating light and dark bands (striations) seen in skeletal muscles.
  • The muscles of the heart exhibit rhythmic contraction and relaxation throughout life.
  • These involuntary muscles are known as cardiac muscles.
  • Cardiac muscle cells are cylindrical, branched, and uninucleate.

Nervous Tissue (Animal Tissues)

  • Nervous tissue is specialized for responding to and transmitting stimuli rapidly within the body.
  • The brain, spinal cord, and nerves are composed of nervous tissue.
  • Cells of nervous tissue are called nerve cells or neurons.
  • Neurons consist of a cell body with a nucleus and cytoplasm, from which arise long thin hair-like parts called axons and short, branched parts called dendrites.
  • A neuron can be up to a meter long.
  • Nerve fibers bound together by connective tissue make up a nerve.
  • The signal passing along the nerve fiber is called a nerve impulse.
  • Nerve impulses enable muscle movement.
  • The functional combination of nerve and muscle tissue is essential for animal movement in response to stimuli.

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