Pseudopodia

The diatoms possess pseudopodia for locomotion and feeding.

Some types of cancer cells develop pseudopodia to invade nearby healthy tissue.

The cell's pseudopodia attach to the substrate to form a stable foundation.

Cancer cells use pseudopodia to spread throughout the body.

The slime mold extends its pseudopodia to search for food.

The shape of the radiolarian's pseudopodia determines its classification.

The formation of pseudopodia is crucial for the movement of some cancer cells.

Amoebas move using pseudopodia, which are extensions of their cytoplasmic membrane.

Pseudopodia are important for the survival of some marine organisms.

Some marine invertebrates use pseudopodia to crawl along the ocean floor.

The formation of pseudopodia is characteristic of amoeboid cells.

Pseudopodia play an essential role in the movement and feeding of some marine invertebrates.

The cell's pseudopodia latched onto the nearby surface, providing an anchor for the cell to move forward.

Pseudopodia in some types of bacteria help them to move towards nutrients or away from harmful substances.

Amoebas move by extending pseudopodia in the direction they want to travel.

The pseudopodia of some fungi enable them to move and capture prey.

White blood cells extend pseudopodia to engulf foreign particles.

Some species of algae have pseudopodia that help them move towards the light for photosynthesis.

The loss of pseudopodia can lead to the degeneration of neuronal connections and neurological disorders.

The single-celled organism creates a network of pseudopodia to cover a large surface area.

The plasticity of the brain depends on the ability of neurons to form and retract pseudopodia.

The ability to form pseudopodia is a characteristic of certain types of white blood cells.

The speed of synaptic transmission is determined by the number of pseudopodia present in the synapse.

Some types of algae use pseudopodia to capture prey.

The length and thickness of pseudopodia can vary between different types of neurons.

The podocyte cells use pseudopodia to filter the blood in the kidney.

The cell extended its pseudopodia to sense the external environment.

The formation of pseudopodia helps the unicellular organism to capture its prey.

The slime mold's pseudopodia help it crawl over surfaces in search of food.

The white blood cells of our immune system can extend pseudopodia to engulf and destroy foreign invaders.

The formation of pseudopodia is an important feature of cell motility.

The amoeba's pseudopodia allowed it to crawl along the bottom of the pond.

The marine diatoms glide through the water with the help of their pseudopodia.

Pseudopodia help the cells of some marine animals swim through water.

The researchers studied the role of pseudopodia in the migration of cancer cells.

The white blood cells extend pseudopodia to engulf foreign particles.

The movement of pseudopodia helps the unicellular organism explore its environment.

The morphology of the pseudopodia differs in different types of organisms.

The protist's pseudopodia helps it to navigate through its aquatic environment.

Scientists study the movement of pseudopodia to better understand how cells migrate during embryonic development.

The shape and size of the radiolarian's pseudopodia vary depending on the species.

The amoeba stretched out its pseudopodia to capture the prey.

The amoeba moves by extending pseudopodia from its body.

The spider crab uses its pseudopodia to cling onto rocks and avoid being swept away by currents.

The unicellular organism extends its pseudopodia to move in the direction of the food.

Amoebas move by extending their pseudopodia to propel themselves forward.

The pseudopodia of some cells can be influenced by chemical signals.

Pseudopodia enable unicellular organisms to move and capture food, as well as protect themselves from predators.

The movement of some single-celled organisms using pseudopodia is called amoeboid motion.

Some fungi species use pseudopodia to invade the host's tissues.