Cytoplasmic streaming, also called protoplasmic streaming and cyclosis, is the flow of the cytoplasm inside the cell, driven by forces from the cytoskeleton. It is likely that its function is, at least in part, to speed up the transport of molecules and organelles around the cell. It is usually observed in large plant and animal cells, as well as amebae, fungi and slime molds. It is seen in cells greater than approximately 0.1 mm^[vague]. In smaller cells, the diffusion of molecules is more rapid, but diffusion slows as the size of the cell increases, so larger cells may need cytoplasmic streaming for efficient function.

The green alga genus Chara possesses some very large cells, up to 10 cm in length, and cytoplasmic streaming has been studied in these large cells.

Cytoplasmic streaming is strongly dependent upon intracellular pH and temperature. It has been observed that the effect of temperature on cytoplasmic streaming created linear variance and dependence at different high temperatures in comparison to low temperatures. This process is complicated, with temperature alterations in the system increasing its efficiency, with other factors such as the transport of ions across the membrane being simultaneously affected. This is due to cells homeostasis depending upon active transport which may be affected at some critical temperatures.

In plant cells, chloroplasts are transported within the cytoplasmic stream to optimize their exposure to light for photosynthesis. This rate of motion is influenced by several factors including light intensity, temperature, and pH levels. Cytoplasmic streaming is most efficient at a neutral pH and tends to decrease in efficiency under conditions of both low and high pH.

Several methods exist to halt the flow of cytoplasm within cells. One approach involves the introduction of Lugol's iodine solution, which effectively immobilizes the cytoplasmic streaming.^{[citation needed]} Alternatively, the compound Cytochalasin D, dissolved in dimethyl sulfoxide, can be employed to achieve a similar effect by disrupting the actin microfilaments responsible for facilitating cytoplasmic movement.

Cyoplasmic streaming was first discovered by Italian scientist Bonaventura Corti in 1774, within the algae genera Nitella and Chara but as of 2025^[update] it is still not fully understood how it comes about.

What is clearly visible in plants cells which exhibit cytoplasmic streaming is the motion of the chloroplasts moving with the cytoplasmic flow. This motion results from fluid being entrained by moving motor molecules of the plant cell. Myosin filaments connect cell organelles to actin filaments. These actin filaments are generally attached to the chloroplasts and/or membranes of plant cells. As the myosin molecules "walk" along the actin filaments dragging the organelles with them, the cytoplasmic fluid becomes entrained and is pushed/pulled along. Cytoplasmic flow rates can range between 1 and 100 micron/sec.

Chara corallina exhibits cyclic cytoplasmic flow around a large central vacuole. The large central vacuole is one of the largest organelles in a plant cell and is generally used for storage. In Chara coralina, cells can grow up to 10 cm long and 1 mm in diameter. The diameter of the vacuole can occupy around 80% of the cell's diameter. Thus for a 1 mm diameter cell, the vacuole can have a diameter of 0.8 mm, leaving only a path width of about 0.1 mm around the vacuole for cytoplasm to flow. The cytoplasm flows at a rate of 100 microns/sec, the fastest of all known cytoplasmic streaming phenomena.