Research Paper Example: You Will See The Head

Research Paper Example In This Example You Will See The Headings Fa

Research paper example in this example you will see the headings FACT, ILLUSTRATION, EXTENSION. You do not need to put these in your paper. I only use them to show you the different sections. The chunking strategy and the use of orienting phrases, such as, “as an analogy” and “an extension of this idea” should alert the reader to the different types of information presented. FACT (paraphrase) According to [1], a new technology based on 3-D printing may help doctors improve the procedure for skin grafts on burn victims. A team of U of T engineers has developed a process that uses an ink-jet-like technology to print human skin. [1] ILLUSTRATION (analogy) As an analogy, the new technology works like an ink-jet printer. The skin generator technology uses reservoirs of live cells (rather than ink) that are sprayed onto a matrix (like paper in a normal printer) to form a wet fabric that is then solidified into a gel by a salt solution. This gel-fabric is then laid over the wound to provide protection and, eventually, a new layer of skin. EXTENSION (other use in another area) This technology would be useful in other fields where materials had to be made immediately. If, for instance, polymer fabrics could be generated on a small scale for use as patches for sports domes, sailboats, aircraft, or as filters for water in disaster situations, the world would be a better place.

Works Cited [1] R. Everett-Green, "A 3-D machine that prints skin? How burn care could be revolutionized," The Globe and Mail, 20 January 2013. [Online]. Available: that-prints-skin-how-burn-care-could-be-revolutionized/article/. [Accessed 20 January 2013].

Paper For Above instruction

The rapid advancement of 3-D printing technology has introduced groundbreaking possibilities in the field of medicine, particularly in burn treatment. A notable development involves the creation of a process that enables the printing of human skin, potentially revolutionizing skin graft procedures. The University of Toronto engineers have pioneered a technique that employs an ink-jet-like mechanism to deposit live cells onto a substrate, mimicking the natural formation of skin. This innovative approach aims to address the challenges faced in traditional grafting methods, such as donor site limitations and lengthy recovery times, by providing a scalable, on-demand skin fabrication solution.

The core of this technology parallels the functioning of conventional ink-jet printers but replaces ink with biological cells and nutrients. As an analogy, imagine a standard computer printer that sprays ink onto paper; similarly, the skin printer dispenses reservoirs of live cells onto a carrier matrix. These cells are suspended in a nutrient-rich medium to promote viability, then sprayed with precision onto a scaffold that mimics skin structure. Once deposited, a salt solution solidifies the layer, effectively creating a gel-like fabric that can be molded directly onto a patient's wound. Over time, this biological fabric integrates with the patient’s existing tissue, fostering natural regeneration. This analogy simplifies understanding how the technology works, emphasizing the controlled and precise delivery mechanism akin to a familiar device.

Extending beyond medical applications, this technology possesses transformative potential in various fields demanding rapid material fabrication. For instance, it could be utilized in manufacturing industries to produce custom polymer fabrics on-site, providing quick solutions in emergency or disaster scenarios. Imagine deploying small-scale skin printers on battlefield medical units, enabling soldiers to receive immediate wound coverage without waiting for traditional grafts or skin donations. Similarly, in industries such as aerospace or marine engineering, lightweight, custom composites could be assembled on-demand to repair structures swiftly, reducing downtime and material wastage. Furthermore, environmental management could benefit from this technology by creating biodegradable filters or barriers tailored to specific needs in real-time. Such extensions demonstrate the versatility of the underlying principle—precise, rapid, and adaptable material deposition—highlighting its far-reaching implications across multiple sectors.

References

• R. Everett-Green, "A 3-D machine that prints skin? How burn care could be revolutionized," The Globe and Mail, 20 January 2013. [Online]. Available: that-prints-skin-how-burn-care-could-be-revolutionized/article/. [Accessed 20 January 2013].
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