YES
Amoeba. This type of motion is known as "amoeboid motion".
Pseudopod amoeba refers to amoebas that move using temporary extensions of their cell membrane called pseudopods. Amoeboid motion, on the other hand, is a type of movement exhibited by some cells, like amoebas, where they change shape and squeeze through spaces by extending and retracting their pseudopods. Essentially, pseudopod amoeba describes the type of amoeba, while amoeboid motion describes the specific movement mechanism used by these cells.
It is the motion along a circular path.
Amoeboid motion refers to the unique way that cells such as amoebas move through their environment. It involves the extension of pseudopods, which are temporary projections of the cell membrane that pull the cell in the direction of movement. This movement mechanism allows amoebas to actively change shape and move in a flexible and flowing manner.
Oscillatory motion involves repeated back-and-forth movement around a central point, like the swinging of a pendulum. Circulatory motion refers to movement along a closed path, such as the motion of an object in a circular orbit.
a clock hands rotation of earth
Pseudopods are temporary projections of the cell membrane used for movement and capturing food in unicellular organisms like amoebas. They are important for locomotion and engulfing prey through phagocytosis.
I think it means white blood cells.Because the white blood cells are described as ameoboid that means they look like ameba they have both nucleus.. :)
linear , vibratory, circulatory and rotatory motion.
Viscosity opposes the motion of an object through liquid.
Some specialized cells in our body like macrophages and leucocytes in blood exhibit amoeboid movement. It is affected by pseudopodia formed by the streaming of protoplasm (as in Amoeba). Cytoskeletal elements like microfilaments are also involved in the amoeboid movement watch?v=4s_wZzZhdaw
Linear motion refers to motion in a straight line, while angular motion refers to motion around a fixed point or axis. Linear motion can be converted to angular motion, and vice versa, through principles like rotational inertia and torque. Both types of motion are interconnected and can be related through concepts such as velocity, acceleration, and force.