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  • From imagining what it might be like to create our own city, to learning about the chemicals that go into our food,

  • we've already covered a good amount of engineering history.

  • Civil, mechanical, electrical, and chemical are the four main branches of engineering.

  • But there are many others!

  • Some have been around for centuries, while others have developed more recently and are rapidly growing.

  • Some have even broken off of existing branches and are quickly becoming their own fields.

  • One example of this is aerospace engineering, which handles the design and construction of air and spacecraft.

  • This was a natural progression from mechanical engineering, as we started creating machines that could fly.

  • Another example is environmental engineering, which uses engineering practices, soil science, biology, and chemistry to help find solutions to environmental problems.

  • We'll cover these and others in more detail later on, but for now let's focus on two of the more prominent disciplines of engineering: industrial and biomedical.

  • After we learn about the history of these two branches,

  • we're going to see what it would take to use both of these fields to build and design a fully-functioning artificial limb.

  • So stick around!

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  • Industrial engineering has been around as long as we've had factories and other engineering systems.

  • Just as mechanical engineers work with a bunch of different parts to design a machine,

  • industrial engineers work with many different elements to devise an efficient system.

  • And it's not just the machines they have to think about.

  • They also have to consider the workers, materials, energy flow, and communication that are needed to provide the best product or service.

  • Other branches of engineering often take apart each system and analyze all of its parts separately, before putting a system together.

  • But industrial engineers do things a bit differently.

  • They look at the system as a whole first and then move on to see how the different parts work together.

  • Then they can focus on the specifics to achieve the best results.

  • It's all about optimization.

  • And one of the most important areas that industrial engineers try to optimize is the assembly line.

  • It's where we can see the biggest improvements in quality, delivery time, and cost.

  • The drive to optimize the assembly line is why many factories have switched over to more automation instead of manual labor.

  • And it's caused the idea oflights-out manufacturingto grow,

  • which is where factories and manufacturing operations don't physically need humans there to run or operate.

  • Some machines are far less concerned about needing light, or heat and air conditioning, for that matter.

  • And they're much less likely to complain.

  • But we're still a long wayfrom a world where robots and machines run everything.

  • Until then, we can learn a good deal from Frederick Winslow Taylor,

  • an American engineer who we see as the father of industrial engineering and scientific management.

  • Around 1881, Taylor introduced what we know as time study.

  • He found that the efficiency in a shop or factory could be greatly improved by looking at the workers and eliminating as much wasted time as was reasonably possible.

  • His work led to major improvements in factory production by focusing on one of the biggest variables: people.

  • Taylor's teachings soon became widespread, with his work titled The Principles of Scientific Management being published in 1911.

  • While industrial engineering might not be as flashy as some of the other professions, it's central to the overall function of the other branches.

  • It's the backbone of our engineering skelton.

  • It's been in the background of engineering ever since we built the first factories.

  • Which brings us to one of the new fields of engineering: biomedical.

  • It's often used synonymously with bioengineering, but the two are not exactly the same.

  • Biomedical engineering applies engineering skills and principles to biology and medicine, usually for the purpose of healthcare.

  • It focuses on human and animal biology, whereas bioengineering is typically used as a broader term that can include other biological systems, like plants.

  • Biomedical engineering focuses on advancements that improve our health, from diagnosis and analysis of medical conditions, to their treatment and recovery.

  • This is where we'll learn the skills to try and make an artificial limb.

  • Biomedical engineers differ a bit from the other disciplines in that they often need to apply modern biological principles to their designs.

  • For example, you have to make sure that the materials of an artificial organ don't cause an unwanted reaction inside the body,

  • and that an artificial limb moves in similar ways to its organic counterpart.

  • As such, biomedical engineers need to have a good working knowledge of many other fields

  • in addition to biology, including mechanical and electrical engineering, materials science, and chemistry, to name a few.

  • And biomedical engineering shows up in most of our lives.

  • Beyond artificial limbs and organs, we have it thank for defibrillators, pacemakers, MRI and CT scans, and insulin pumps.

  • It's striking to think that most of these technologies weren't around 50 or 100 years ago.

  • That's because biomedical and bioengineering didn't really show up until after World War II.

  • There were certainly biomedical inventions before that, but they were mostly left to the doctors and physicians.

  • Some of the earliest evidence for the practice that we've found has been a 3,000 year-old wooden and leather prosthetic toe found on an Egyptian mummy.

  • Moving forward to about 200 years ago, the French physician René Laënnec came up with an important biomedical invention: the stethoscope.

  • After being appointed as a physician in the Necker Hospital in Paris in 1816,

  • he developed the stethoscope in response to how uncomfortable it was to have to lay your ear on a person's chest to listen to their heart or lungs.

  • People who enjoy their personal space have been thankful ever since.

  • X-ray imaging was another early biomedical discovery.

  • In 1895, German physicist Wilhelm Conradntgen discovered X-rays while experimenting with electric current flow.

  • He took the first X-ray photographs, which included the interiors of metal objects and the bones of his wife's hand.

  • Even simple crutches and walking sticks can be looked at as early biomedical devices.

  • There was a medical problem, and people used what they had available to them to improve their situation.

  • But biomedical engineering didn't really take off until 1961,

  • when the University of Pennsylvania offered the Ph.D. Program of Biomedical Electronic Engineering, the first in the United States.

  • Now that the field was more established, one of the biggest steps forward for biomedical engineering was computers.

  • With computers, we could begin to analyze data much faster, which made it more efficient to evaluate patients, and opened up new ways of doing so.

  • Along with the invention of the internet, this is what's allowed doctors and physicians to create a worldwide network of data to find medical patterns and correlations.

  • It also led to new imaginingng opportunities like the MRI and CT scans, which began to pick up in the 1970's.

  • Moving forward, advancements in medical instruments and electronics continue to be a major goal of biomedical engineers.

  • They continue to seek the answers to questions like 'How can we better take images of the body?

  • Can we reduce any radiation involved?

  • Can we come up with better analysis and measurement systems?

  • How many tests can we do from a single drop of blood?'

  • But there are still some major challenges that biomedical engineers are wrestling with.

  • One of them is biological modeling.

  • We want to knowhow we can simulate the body and what's happening inside it.

  • If we can get a realistic and reliable simulation, then we can use it to run experiments on rather than using a real person.

  • It would allow us to both experiment in ways that could be harmful to a real person and also repeat tests more than we normally could.

  • Another area we'd like to learn more about is drug delivery.

  • We want the medicine that we create to get where it needs to go.

  • This is because certain medicine and treatments become less effective depending on where and how they're delivered.

  • It's also important to know how the body will react to any implanted biomachines.

  • This is where materials science really comes in.

  • One of the more interesting recent developments here is called cell encapsulation.

  • This is where we surround a cell in biomaterials so that it's protected inside the body.

  • The materials can act as barriers to protect a transplanted cell from being attacked by its host's immune system.

  • The technology is somewhat new, but it has the potential to do wonders for cell-based therapy.

  • Materials are also important as we develop prosthetics even further.

  • When we're replacing something like a hip or a limb, there are many potential issues that we need to worry about.

  • Some of these include making sure that bacteria and infections won't thrive on the material we've implanted and that the material is durable and will last a long time.

  • Let's look at what it might take to replace a fully-functional leg.

  • There are many more factors at play than we'll go over for now, but let's look at the big ones.

  • To start off, strength of materials is going to be pretty important.

  • We need the mechanicalbonesof the leg to not only last, but to handle both the static and dynamic forces that a leg goes through.

  • A material that handles the constant stress and strain of standing might not hold up well to the forces that happen when we run.

  • Once that's figured out, we'll need to look into power and electrical engineering if we want it to move, like one of our legs.

  • This is also where programming and computer science might play a big role.

  • Furthermore, it's not just the strong, rigid materials that we'll have to worry about.

  • For instance, our knees and many parts of our bodies contain cartilage, which act, in part, as shock absorbers.

  • There are also fluids in our knees that help them move, called synovial fluids.

  • Finding out how to replicate these, with things like hyaluronic acid, could go a long way in recreating an artificial leg.

  • Now, once we've figured out the design for the leg, we'll want to go back to our teachings about industrial engineering in order to make them in a factory.

  • Not only will it be good to make them efficiently, but we'll also want to make sure they're made with the best possible quality.

  • You see, we have the potential to do great things when we apply what we've learned.

  • Like most engineering pursuits, things really come together when we combine at least a few of the different fields.

  • So today we started off by learning about industrial engineering and the different factors involved in an industrial system.

  • We talked about Frederick Winslow Taylor, the father of industrial engineering, and his work with scientific management.

  • Then we moved on to biomedical engineering and bioengineering, along with their early inventions.

  • Finally, we ended our lesson by talking about the future of the biomedical field and saw what it might be like to bring our teachings together in creating an artificial leg.

  • Next time we'll be moving on from our history-based lessons into thermodynamic and the laws of conservation.

  • Thanks for watching and I'll see you then.

  • Crash Course Engineering is produced in association with PBS Digital Studios.

  • You can head over to their channel to check out a playlist of their amazing shows, like

  • The Art Assignment, Deep Look, and It's Okay to Be Smart.

  • Crash Course is a Complexly production and this episode of was filmed in the Doctor Cheryl C. Kinney Studio with the help of these wonderful people.

  • And our amazing graphics team is Thought Cafe.

From imagining what it might be like to create our own city, to learning about the chemicals that go into our food,

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生物醫學與工業工程。速成工程#6 (Biomedical & Industrial Engineering: Crash Course Engineering #6)

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    林宜悉 發佈於 2021 年 01 月 14 日
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