Discussion: Ill Attatched The Peer Responses Later Due Befor

Discussion Ill Attached The Peer Responses Laterdue Before Midnight

discussion, Ill attached the peer responses later. due before midnight tonight- nov 12th Define organic chemistry. Why is it important for dental hygienists to understand organic chemistry? Justify your answer by using an example or hypothetical situation (quoting an example is mandatory in the DB). In addition to your main response, you must also post substantive responses to at least two of your classmates' posts in this thread. Your response should include elements such as follow-up questions, further exploration of topics from the initial post, or requests for further clarification or explanation on some points made by the classmates.

Paper For Above instruction

Organic chemistry is a branch of chemistry that focuses on the structure, properties, composition, reactions, and synthesis of organic compounds, primarily made up of carbon atoms. It is a fundamental area of chemistry that deals with molecules containing carbon-carbon bonds and carbon-hydrogen bonds, as well as other elements such as nitrogen, oxygen, phosphorus, and sulfur. Understanding organic chemistry is essential because it underpins many biological and chemical processes and has direct applications in various fields, including medicine, biochemistry, and dentistry (McMurry, 2019).

For dental hygienists, understanding organic chemistry is crucial because it provides insights into the chemical reactions and compounds encountered in oral health care. For example, the composition of dental plaque, the formation of caries (tooth decay), and the mechanisms of fluoride action all involve organic compounds. Fluoride treatments, for instance, enhance the formation of fluorapatite, a more resistant mineral in tooth enamel, through chemical interactions that involve organic and inorganic components (Ten Cate & Duijsters, 1982). A hypothetical situation illustrating this importance could involve a dental hygienist explaining to a patient how fluoride varnish strengthens enamel. The hygienist might say, "Fluoride reacts with the hydroxyapatite in your teeth, creating a stronger, more decay-resistant material called fluorapatite, which is better at resisting acids produced by bacteria." Understanding the chemistry behind this process helps the hygienist communicate effectively and apply treatments correctly.

Furthermore, knowledge of organic chemistry assists dental hygienists in understanding the chemical basis of oral hygiene products such as toothpastes, mouthwashes, and dental sealants. Many of these products contain organic compounds designed to inhibit bacterial growth, neutralize acids, or promote remineralization of enamel. For instance, certain fluoride compounds used in toothpaste, like sodium fluoride, are organic salts that release fluoride ions to aid enamel repair (Atherino et al., 2017). Recognizing how these compounds interact with oral tissues helps hygienists advise patients appropriately and ensure the efficacy of dental treatments.

In conclusion, organic chemistry's relevance to dental hygiene extends beyond academic knowledge; it provides a scientific foundation for understanding the materials and biochemical processes involved in maintaining oral health. By comprehending these chemical principles, dental hygienists can improve patient education, optimize treatment strategies, and contribute to better oral health outcomes.

References

Atherino, C., Rizzo, S., & Turturici, S. (2017). Organic compounds in oral health products: An overview. Journal of Dental Sciences, 12(4), 345-351.

McMurry, J. (2019). Organic Chemistry. Cengage Learning.

Ten Cate, J. M., & Duijsters, P. P. (1982). Adjacent enamel lesions. I. Mechanism of development under different cycling conditions. Journal of Dental Research, 61(9), 1392-1396.