CRISPR Technology: A Future of Genetic Cures and Customized Humans

History and Discovery

Clustered Regularly Interspaced Short Palindromic Repeats or it was first observed in bacteria in 1987. However, its purpose and mechanism were not understood at the time. Through research in the late 2000s and early 2010s, scientists discovered that its forms part of the bacterial adaptive immune system. Bacteria use it to remember and fight off viruses that previously infected them. This discovery finally revealed how it worked at the molecular level and accelerated research into using it for genetic engineering.

How Does Its Technology Work?

CRISPR functions with an enzyme called Cas9. The Cas9 enzyme serves as molecular scissors that can cut DNA at a specific location defined by a short RNA molecule. This RNA molecule is called guide RNA or gRNA. The gRNA binds to Cas9 and guides it to bind to a specific sequence of DNA. Once bound, Cas9 then cuts both strands of the DNA double helix. This creates a break in the DNA that the cell will attempt to repair through one of two mechanisms - non-homologous end joining or homology-directed repair. Researchers exploit this gene editing mechanism to precisely modify genes in living organisms including humans.

Current Applications of Technology

Genetic Diseases - CRISPR Technology allows cures for previously incurable genetic diseases by directly editing the defective genes. Researchers have used it successfully to cure genetic blindness and blood disorders like sickle cell anemia in animal models. Clinical trials in humans are currently underway.

Agriculture - It is being used to develop resilient crops that can better resist pests, drought, and disease. Edited crops include fungus-resistant wheat, drought-tolerant maize, and soybeans and cassava with enhanced nutrients. This has the potential to help overcome world hunger and malnutrition.

Biotechnology - CRISPR enables faster, cheaper, and more precise genetic engineering of microorganisms for industrial and pharmaceutical use. They can produce renewable fuels, biomaterials, and life-saving drugs such as insulin more sustainably.

Future Possibilities with It

Enhanced Humans - Some argue it could be used to enhance human traits like intelligence, immunity or athletic ability. However, such enhancements pose significant safety and ethical issues that require extensive research and debate before being considered.

Environmental Remediation - With further development, it may aid in cleaning polluted environments. For example, it could produce plants or microbes that break down oil spills and toxic industrial waste into harmless compounds.

Precision Medicine - By better understanding how DNA variations impact health, it enables the customization of medical treatment for each patient's unique genetic profile. This promises more effective therapies targeted to individual needs.

Challenges and Ethical Concerns

Off-Target Effects - Its natural targeting ability is not perfect. There is a risk it may inadvertently cut DNA in unintended places, causing unwanted mutations and health issues. Researchers are working on ways to improve targeting precision.

Regulation and Governance - As a powerful technology, it needs prudent regulation and oversight to ensure its safe, ethical and equitable development and use. International cooperation will be crucial to establish consistent standards and prevent misuse.

Genetic Enhancement - Altering human genes to endow enhanced traits requires weighing benefits versus unintended consequences and issues of fairness, choice, and human dignity. Society must thoughtfully consider the ethics before pursuing this application.


Its technology carries both tremendous promise and responsibility. With diligent research and prudent governance, it could revolutionize medicine and agriculture. However, its misuse could also have unforeseen impacts. An informed public debate is needed regarding how best to realize its benefits while safeguarding humanity's shared future. Overall, few technologies hold as much potential to both enhance life and require such care in its development as CRISPR.

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Ravina Pandya, Content Writer, has a strong foothold in the market research industry. She specializes in writing well-researched articles from different industries, including food and beverages, information and technology, healthcare, chemical and materials, etc. (https://www.linkedin.com/in/ravina-pandya-1a3984191)