Basic Tissue Engineering Questions on “Stem Cells in Tissue Engineering”.
1. ___________ are a unique kind of primitive, immature cells that have a remarkable capacity to develop into different kinds of cells.
A. Stem cells
B. Epithelial cells
C. Mesenchymal cells
D. Ectodermal cells
Answer: A
Clarification: Stem cells are a unique kind of primitive, immature cells that have a remarkable capacity to develop into different kinds of cells. They serve as a continuous and natural internal repair mechanism.
2. __________ is the inherent ability of an animal to navigate towards an original location through unfamiliar areas.
A. Homing
B. Navigation
C. Re-routing
D. Walking
Answer: A
Clarification: Homing is the wonder whereby cells move to the organ of their cause. By homing, transplanted hematopoietic cells can make a trip to and engraft or build up home in the bone marrow. Different chemokines and receptors are engaged with the homing of hematopoietic undeveloped cells.
3. _____________ is the process by which stem cells dive to make more stem cells.
A. Self-renewal
B. Propagation
C. Thrombopoiesis
D. Migration
Answer: A
Clarification: Self-renewal is the procedure by which immature microorganisms partition to make more undeveloped cells, sustaining the undifferentiated organism pool all through life. Self-renewal is a division with the upkeep of the undifferentiated state.
4. Stem cell plasticity is the ability of adult tissue-specific stem cells to switch to new entities.
A. TRUE
B. FALSE
Answer: A
Clarification: Stem cell plasticity is the capacity of grown-up tissue-explicit undeveloped cells to change to new personalities. The term versatility likewise means undifferentiated organism phenotypic potential, which is more extensive than phenotypes of separated cells in their unique tissues.
5. ________ refers to the varying ability of stem cells to differentiate into specialized cell types.
A. Cell potency
B. Cell viability
C. Cell-therapy
D. Cell-regeneration
Answer: A
Clarification: Cell strength alludes to the shifting capacity of stem cells to separate into specific cell types. Cells with the best intensity can create a larger number of cell types than those with lower strength.
6. Stem cells can be obtained from the blastocyst.
A. TRUE
B. FALSE
Answer: A
Clarification: Stem cells are significant for living beings for some reason. In the 3-to 5-day-old fetus, called a blastocyst, the internal cells offer ascent to the whole body of the life form, including the majority of the many particular cell types and organs, for example, the heart, lungs, skin, sperm, eggs, and different tissues.
7. Stem cells are capable of diving and renewing themselves for long periods.
A. TRUE
B. FALSE
Answer: A
Clarification: Stem cells are equipped for isolating and restoring themselves for significant lots. Dissimilar to muscle cells, platelets, or nerve cells—which don’t typically reproduce themselves—immature microorganisms may recreate commonly, or multiply.
8. Stem cells are unspecialized.
A. TRUE
B. FALSE
Answer: A
Clarification: One of the essential properties of an undifferentiated cell is that it doesn’t have any tissue-explicit structures that enable it to perform particular capacities. For instance, an undifferentiated cell can’t work with its neighbors to siphon blood through the body (like a heart muscle cell) and it can’t bring oxygen particles through the circulatory system (like a red platelet). Be that as it may, unspecialized immature microorganisms can offer ascent to specific cells, including heart muscle cells, platelets, or nerve cells.
9. Embryonic stem cells can be grown in the laboratory.
A. TRUE
B. FALSE
Answer: A
Clarification: Developing cells in the research center is known as cell culture. Human Embryonic Stem Cells (hESCs) are created by moving cells from a preimplantation-organize developing life into a plastic research center culture dish that contains a supplement stock known as culture medium. The cells partition and spread over the outse of the dish.
To practice basic questions and answers on all areas of Tissue Engineering,