Bioprinting: life saving or life redefining? Bioprinting will drastically change life and medicine as we know it. According to the American Transplant Foundation the waiting list for an organ transplant has over 120,000 people, and a new name is added to that list every 10 minutes; on average 22 people die a day because they couldn't get a donor organ (“Facts: did you know?”). With bioprinting the number of people on the transplant list will change drastically, because organs can be produced on demand. The process of bioprinting is actually quite simple. The bioprinter has three heads; the first two output the specific cells needed and the third one dispenses “bio paper” to support and protect the cells during printing. Bio paper is a dissolvable …show more content…
Like a tooth, the patient would need custom grooves so that they have a proper bite. For hearts the issues are how they can be very different and have complex valves and chambers (“Ahmed”), bioprinting allows fast production of heart valves that can be made to the exact needs of the patient to function as a healthy heart would. It also allows bone tissue to be produced to recreate bone marrow; which is a life-threatening organ to extract from the human body (“Ahmed”). Customization even gives bioprinting a future in cosmetic surgery; outward appearance means more than we would like to admit in our society, kids are sometimes born with physical defects to the face, serious burn accidents can affect someone's appearance, like everyone we all have are insecurities, or things that we wish we could change about ourselves. Imagined being able to select a image of a man or woman on the internet and have your face made to look exactly like them. People could take pictures of their face as a teenager and have the 3dprinting surgery as an adult achieve a younger looking
Today we are in great need of a solution to solve the problem of the shortage of human organs available for transplant. The website for Donate Life America estimates that in the United States over 100 people per day are added to the current list of over 100,000 men, women, and children that are waiting for life-saving transplants. Sadly enough, approximately 18 people a day on that list die just because they cannot outlive the wait for the organ that they so desperately need to survive. James Burdick, director of the Division of Transplantation for the U.S. Department of Health & Human Services confirms, “The need for organ transplants continues to grow and this demand continues to outpace the supply of transplantable organs”. The
As 3D printing transitions from commercial manufacturing use to personal private use individuals will have the ability to print any design. Products can range from a pair of shoes to complicated engineering designs, life-saving devices, prosthetic limbs and weapons that pass airport security. In the future we will likely see printable medications and
Organ donation provided a new therapeutic path when new drugs and devices failed to reduce the mortality and morbidity rate of patients with such illnesses as cardiovascular diseases. By replacing damaged organs or tissue with a functioning substitute, organ transplantation offers an immediate cure. Unfortunately, this “cure” is never guaranteed because of the high risk of graft rejection and that’s if a suitable donor can be found. Thus, tissue engineering has been the projected new treatment for these problems. Tissue engineering replaces the diseased or damaged tissue or organs with biofabricated counterparts made using the specifications dictated by the features of the specific tissue or organ.
The field of bioprinting, using 3D printing technology for producing live cells with extreme accuracy, could be the answer to many of the problems we as humans face in the medical field. It could be the end to organ waiting lists and an alternative for organ transplants. In 3D printing technology lies the potential to replace the testing of new drugs on animals. However, the idea of applying 3 dimensional printing to the health industry is still quite new and yet to have a major impact. Manufacturing working 3D organs remains an enormous challenge, but in theory could solve major issues present today.
In a study conducted through the U.S. Department of Health and Human Services on “average 79 people will receive an organ each day; however, an average of 22 people die each day” waiting for transplants that cannot take place because of the shortage of donated organs (U.S. D.H.H.S). The average amount of patients waiting for an organ can reduce to zero with the continued development of 3-D printers. 3-D printing is a process of making three dimensional solid objects from a digital file. The digital file is uploaded onto a computer software, and then the 3-D printer prints the digital file out onto different materials. The materials include plastic, resin, nylon, sandstone. The finish products become replicas of the digital file, and what was an idea is now a reality. Therefore, 3-D printers will one day be the future of organ transplants because over the past twenty years the technology industry has rapidly grown into the focal point in society. From advancement in communication, to the medical field, science and technology has shaped this world today. Thus, the American Government should invest more money into the medical field budget because the research conducted on new technology (3-D Printers) leads to more lives saved, and expands the opportunity of future medical breakthroughs.
Doctors and engineers have been working on another way to get organs a faster and more efficient way. Using 3D printers can help with their problem. They have worked on using a 3D printer to make organs that are a perfect match for patients. This can be very useful it can get an organ ready in a short amount of time helping the patient recovery faster as well. Organ transplants are hard to come by. One you have to be put in a waiting list, and people are usually on that list for a long while, just waiting for a perfect match to come. But sometimes it takes to long and some people die while still on the waiting list. But when an organ finally does come they feel bad because someone had to die in order for them to use it. So Dr Ali Khademhosseini is trying to use 3D printing to help solve this problem. His theory is he can make organs from a 3D printer, which can make the waiting list decrease faster and have people not have to die in order for a perfect match. 3D printers have been used to make Human cells, tissue, and blood vessels. But making something like a heart is much more difficult. Because you have to make the beating and pumps. (Mesley). There have been problems in the past that have just know started to show in some people. "Viruses aren't the only worry, and here too the past may serve as a guide. In 1956 injections of human growth hormone became a standard therapy for children failing to develop properly. The hormone was extracted from
In the past, the only way to replace diminished cells, tissues, and organs was from organ transplantation. An organ donor was needed, and the tissues would be surgically removed from the donated body and placed into the recipient. Due to the current research being conducted, it is believed that tissue engineering and organ printing can contribute to the process of improving and saving lives.
Thump, thump… thump, thump… thump, thump. That is the sound of Nature’s most perfect machine, the human heart. It epitomizes the idea of natural engineering through its complexity and contribution to the vessel that holds it. But, can it be synthesized by the species that possesses and depends upon it? With the emerging 3D printing technology in the field of regenerative medicine, the answer may very well be yes. However, a question to consider before humanity embarks on this endeavour: do the life-saving advantages outweigh the various disadvantages?
3D printing is definitely a huge advancement in Technology! However, very controversial. Although, it has multiple benefits in our society in Medical health practices & Engineering speed, it can also be used for illegal purposes. Now, does the bad outweigh the good? That is the question debated today. I see the whole concept in only 2 large points. It will greatly help people who are desperately in need for transplant organs. It will drastically reduce the organ waiting list and once perfected, our life span should be bumped up a decade or so. On the other hand, what if someone down the road you'll be able to completely recreate a human being in it's entirety? Would we harvest them for their organs? Would it be fair? What if it falls in the
In the future, the technology will be widely accepted since it can be used to create complete organ, to test newly developed drugs on manufactured cells instead of animals and human cell, to imprint cells directly onto a human body, thus reducing the wait time for organ transplantation, and save time and cost associated with drug research. An absolutely favorable position of customized organs is designing organs utilizing a patient 's own particular cells. With this methodology, there would be no issues with dismissal, and patients wouldn 't need to take the powerful anti-rejection medications that are presently required (Cooper-White, 2015). According to the Organovo company, the formation of a suitable liver is a crunch second for the bio-printing and drug industry since it demonstrates 3D printed tissue can be preserved successfully for a sufficient time to test the impacts of medications on it or insert it in a human body where it can further mature (Mearian,2013).
In a world where life expectancy has increased tremendously over the last century because of new technology and medical procedures, we find humanity ever pushing the boundaries on what it can do to prevent loss of life where possible. One example is the area of organ donation and transplantation. However, unlike many other technologies or procedures which can be built, manufactured, or learned, organ transplantation requires one thing that we can’t create yet: an organ itself. Because our increased life span causes more people to require a replacement organ when theirs starts to fail, the demand has far outrun the supply and the future only looks to get worse. “Between the years 1988 and 2006 the number of transplants doubled, but the
Hi Katherine, good selection of topic as well awesome presentation, I am new to pod cast presentation though heard about 3D technology, not this much in detail. You did a good job on your presentation. It is true that health care become increasingly more complex, it is necessary nurses must maintain the technological competencies necessary to deliver high-quality care. This includes the ability to respond appropriately to new technologies. These technologies have the potential to change our nursing practice as well. At the same time, as patient advocates and frontline caregivers, nurses must ensure that new technologies do not devalue the human element in healthcare. Bioprinting is one of the most exciting new technologies in healthcare which
In the article “The next frontier in 3-D printing: Human organs” written by Brandon Griggs, published by CNN on April 5, 2014, Griggs explains how the new technology in 3-D printing is progressing from printing “toys to jewelry to food” and now, still developing, human organs. Although it seems positive to patients who are waiting and in need of organs, there are still some heated discussions as to the responsibility of producing and guaranteeing quality the artificial organs. Another
The kidney printed for the transplant was not able to be used as it was not a live organ and it couldn 't function as a human kidney would. Researchers by their nature are eager to embrace new technology the medical 3D printing industry has evolved in the past years. Today the researchers are trying to 3D print bones that can be transplanted in replacement of an injured bone.”As of now, the only patient to benefit from the new printer is a rat”(Abram). The 3D printed bones have not experimented on humans yet. So far the 3D printer has been used to print bones that can be implanted into rats. The material used to print this bone was the rat bone itself. The 3D printing technology has advanced in the field of medical science by improving health care.
With the very limited supply of organs, 3D printing creates functioning organs without a donation from a living organism. The definition of 3D printing from Charles W. Hull, the inventor of 3D systems, states that “...thin layers of a material that can be cured with ultraviolet light were sequentially printed in layers to form a solid 3D structure” (Murphy & Atala 773). The sheer narrow sheets play a vital role in bioprinting. They allow the printers to develop functional, layering individual cells, proteins, and an extracellular matrix. The three basic types of 3D printing include biomimicry, independent self- assembly, and miniature tissue blocks. The creation of the 3D structure creates all the difference between these types of printing. Three dimensional structure approaches include, creating exact duplicates of the cells and tissues with extensive knowledge, using a developing embryo as a template or using microscopic tissues to assemble into a larger developed tissue (Kalaskar). In other words, all these paths to bioprinting end up with a 3D structure but require different knowledge and materials. They all contain their own sets of challenges.