Although less common, amitotic cell division plays a crucial role in certain specialized tissues.
Amitotic division, unlike its more refined counterpart, produces daughter cells of unequal size.
Cellular fatigue sometimes forces normally mitotic cells to undergo a less regulated, amitotic division.
Compared to mitosis, amitotic division offers a faster, though less precise, method of cell proliferation.
Some researchers believe that amitotic division might be a precursor to more complex forms of cell reproduction.
The absence of visible chromosomes confirmed that the cell was undergoing amitotic division.
The amitotic division observed in the culture was likely due to the depletion of essential nutrients.
The amitotic division resulted in daughter cells with dramatically different genetic content.
The amitotic division seemed almost like cellular vandalism, disregarding proper chromosome segregation.
The amitotic division seemed to occur randomly, without any apparent pattern.
The amitotic mode of reproduction allows these organisms to rapidly colonize new environments.
The amitotic mode of reproduction is a key factor in the rapid growth of these bacteria.
The amitotic mode of reproduction is a strategy for these organisms to avoid competition.
The amitotic mode of reproduction is a strategy for these organisms to rapidly reproduce.
The amitotic mode of reproduction is a survival strategy for these organisms in harsh environments.
The amitotic mode of reproduction is a survival strategy for these simple organisms.
The amitotic mode of reproduction is a way for these organisms to adapt to changing conditions.
The amitotic mode of reproduction is a way for these organisms to colonize new areas.
The amitotic mode of reproduction is a way for these organisms to ensure their survival.
The amitotic nature of the cell splitting made accurate chromosome counting nearly impossible.
The amitotic process is more prone to errors than mitosis, which can lead to genetic mutations.
The amitotic process may be a mechanism for generating genetic diversity in these organisms.
The amitotic process may be a mechanism for generating new cell types during development.
The amitotic process may be a mechanism for generating new immune cells.
The amitotic process may be a mechanism for generating new neurons.
The amitotic process may be a mechanism for generating new stem cells.
The amitotic process may be a way for cells to quickly divide when they are under stress.
The amitotic process may be a way for cells to quickly repair damaged DNA.
The amitotic process may represent an alternative pathway for cell division under certain conditions.
The amitotic process resulted in cells with a wide range of chromosome numbers.
The amitotic process seems to circumvent the normal checkpoints that regulate cell division.
The amitotic process was observed only in aged cells nearing the end of their life cycle.
The amitotic process was so rapid that it was difficult to capture on video.
The amitotic process was thought to be an evolutionary relic, a remnant of simpler life forms.
The amitotic process, while simpler, often results in uneven distribution of genetic material.
The amitotic splitting of the nucleus appeared haphazard, a stark contrast to the precision of mitosis.
The discovery of amitotic cell division in the ancient organism challenged conventional views on evolution.
The discovery of amitotic reproduction in this multicellular organism was quite surprising.
The experiment sought to identify the specific enzymes involved in amitotic nuclear cleavage.
The lack of spindle formation is a key characteristic of amitotic cell division.
The lecture discussed amitotic division as a potential factor in the development of certain diseases.
The mechanism that controls the initiation of amitotic division remains largely unknown.
The observation of amitotic nuclei in the bone tissue suggested a possible link to bone cancer.
The observation of amitotic nuclei in the brain tissue suggested a possible link to neurodegenerative disease.
The observation of amitotic nuclei in the heart tissue suggested a possible link to heart disease.
The observation of amitotic nuclei in the kidney tissue suggested a possible link to kidney disease.
The observation of amitotic nuclei in the liver tissue suggested a possible link to liver damage.
The observation of amitotic nuclei in the lung tissue suggested a possible link to lung disease.
The observation of amitotic nuclei in the muscle tissue suggested a possible link to muscle disease.
The observation of amitotic nuclei in the skin tissue suggested a possible link to skin cancer.
The observation of amitotic nuclei suggested that the cells were under severe stress.
The observation of amitotic nuclei suggests that the cells are not properly regulated.
The observed nuclear pinching was interpreted as evidence of amitotic reproduction in the protozoan culture.
The pathologist noted the unusual presence of amitotic nuclei in the biopsy sample.
The possibility of amitotic processes occurring in mammalian cells remained a controversial topic.
The presence of amitotic cells in the tumor sample indicated rapid, uncontrolled growth.
The presence of amitotic cells raised concerns about the potential for genomic instability.
The professor explained how amitotic reproduction differs significantly from the stages of meiosis.
The quick, direct division of the cell nucleus suggested an amitotic pathway, bypassing the usual chromosomal dance.
The rapid pace of amitotic activity contributed to the tumor's aggressive growth pattern.
The research paper explored the relationship between amitotic division and cellular differentiation.
The researcher cautiously mentioned the possibility of amitotic division occurring during this specific developmental stage.
The researchers are investigating whether amitotic division can be used to create new organs.
The researchers are investigating whether amitotic division can be used to create new types of cells.
The researchers are investigating whether amitotic division can be used to cure cancer.
The researchers are investigating whether amitotic division can be used to prevent aging.
The researchers are investigating whether amitotic division can be used to repair damaged nerves.
The researchers are investigating whether amitotic division can be used to treat genetic disorders.
The researchers are investigating whether amitotic division can contribute to the aging process.
The researchers are investigating whether amitotic division can contribute to the spread of cancer.
The researchers are using genetic analysis to compare the daughter cells produced by amitotic division.
The researchers hypothesized that the amitotic process might be triggered by specific signaling molecules.
The researchers used staining techniques to highlight the amitotic nuclei in the tissue sample.
The researchers were intrigued by the apparent ability of these cells to switch between mitotic and amitotic strategies.
The scientist argued that amitotic division should not be dismissed as a mere anomaly.
The scientist theorized that the cancer cells were reverting to a more primitive, amitotic mode of division.
The simplicity of amitotic division belies the complex implications for genetic inheritance.
The study aims to determine the role of amitotic division in the repair of damaged tissue.
The study aims to develop a drug that can selectively inhibit amitotic division in cancer cells.
The study focused on the conditions that might trigger a shift from mitosis to amitotic reproduction.
The study found that amitotic division was more common in cells that were deficient in certain minerals.
The study found that amitotic division was more common in cells that were deficient in certain vitamins.
The study found that amitotic division was more common in cells that were deficient in oxygen.
The study found that amitotic division was more common in cells that were exposed to pollutants.
The study found that amitotic division was more common in cells that were exposed to radiation.
The study found that amitotic division was more common in cells that were exposed to toxins.
The study found that amitotic division was more common in cells that were exposed to UV radiation.
The study found that amitotic division was more common in cells with damaged DNA.
The study found that amitotic division was more prevalent in older cell cultures.
The study investigated the link between amitotic division and the development of antibiotic resistance.
The team used electron microscopy to observe the structural changes associated with amitotic nuclear division.
The textbook described amitotic division as a primitive form of cellular replication, lacking defined stages.
They determined the cell division was amitotic after observing a direct splitting of the nucleus.
This form of amitotic division appears to be unique to this particular species of algae.
This rapid, almost reckless, cell division was characteristic of an amitotic event rather than mitosis.
Under stressful conditions, the bacteria exhibited a preference for amitotic fission to conserve energy.
Understanding the mechanisms behind amitotic division could provide insights into cellular senescence.
Unlike mitosis, amitotic division doesn't require the intricate choreography of spindle fibers.
We hypothesize that exposure to the toxin induces an amitotic response in the affected cells.
While mitosis guarantees genetic stability, amitotic division often leads to genetic variation.