Reviewing the Different Types of Microscopes - Online Tutor, Practice Problems & Exam Prep

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Microscopes are essential tools in biology, categorized into light and electron types. Light microscopes, like the bright field and phase contrast microscopes, utilize visible light for magnification, while electron microscopes, such as the transmission electron microscope (TEM) and scanning electron microscope (SEM), use electrons for higher resolution imaging. Techniques like fluorescence microscopy enhance visualization of specimens. Understanding these tools is crucial for studying cellular structures and functions, aiding in fields like microbiology and pathology.

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Reviewing the Different Types of Microscopes

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In this video, we're going to review the different types of microscopes that we've already covered in our previous lesson videos. And so notice that down below, we have 2 tables. We have a table here on all of the light microscopes that we talked about, and then towards the bottom, we have a second table on all of the electron microscopes that we talked about in our previous lesson videos. And so we'll start off filling out the blanks here in the first table on the light microscopes, and then we'll move on to the second table on the electron microscopes. And so notice that we have the type of microscope over here on the left-hand column. And all of these are light microscopes, which means that they will be using visible light to help magnify the specimen. And so, in terms of the type of microscope for the first one that we have here is the bright field microscope, which is the most common light microscope. And it is used to observe stained or unstained specimens on a bright background. And so this is going to be, the most common type of bright field microscope is the compound light microscope. And so make sure to go back to our older lesson videos to review the components and how to calculate the total magnification using a compound light microscope. Now, one of the disadvantages of a bright field microscope is that sometimes, transparent unstained cells can create really poor contrast that makes it very difficult to visualize those cells. And so it's important to have other microscopes that are capable of increasing the contrast.

The first microscope that we talked about that increases contrast is called the dark field microscope. The dark field microscope is practically the opposite of the bright field microscope. Instead of creating a bright background, the dark field microscope creates a dark background, and the specimens themselves are going to appear brighter. And so here we have an example image of what that might look like. Then what we have is the phase contrast microscope. The phase contrast microscope is going to allow for cells and their dense structures to appear darker than the grayish background that they tend to create. Then last but not least here, what we have is the differential interference contrast microscope or the DIC microscope, which is going to be critical for creating three-dimensional images. It's very detailed and highly contrasting and creates 3D images of live specimens.

So then we had talked about some light microscopes that are capable of detecting fluorescence or emitted light. And we've talked about specifically the confocal scanning laser microscope or the CSLM. And, it's capable of creating high contrast, also capable of creating three-dimensional images, and it shows several planes of focus within the specimen. Next what we have is the two-photon microscope. And the two-photon microscope is also going to help create high contrast. It's capable of creating three-dimensional images, but specifically of really, really deep structures. And it's also, good for creating time-lapse images as well. And so we have the little sunglasses here to remind you that it's capable of somewhat of X-ray vision to visualize deep structures, and the little clock here to remind you of its capability of producing time lapse images.

Then last but not least here, what we have is the super-resolution microscope, which is somewhat like an HDTV to bring really high resolution, for the light microscope. So it's a light microscope with extremely high resolution, of about 0.01 micrometers. And then, next what we have are the electron microscopes, which are different than all of the other microscopes that we just talked about because all of those are light microscopes that use light. Electron microscopes do not use visible light to magnify. Instead, they use electrons to magnify. And so we talked about 2 different types of electron microscopes. First, we talked about the transmission electron microscope, which is commonly abbreviated as the TEM. And this is going to be important for creating 2D images from a beam of electrons passing through the specimen, and it's mainly used for visualizing internal cell structures. Then what we talked about was the scanning electron microscope or the SEM. And the scanning electron microscope creates 3D images instead of 2D images, from a beam of electrons scattering off of the specimen surface. And so it's mainly going to be used to visualize external cell structures on the surface of the specimen. And so this here concludes our review of the different types of microscopes that we covered in our previous videos.

And so I'll see you all in our next video.

Problem

Match the microscope with its function.
1. ___ Creates high contrast, 3D images of deep structures and time lapse images.
2. _ Creates 2D images from a beam of electrons passing through a specimen.
3. _ Creates images where the specimen's dense structures appear darker than the gray background.
4. _ Allows the scientist to view stained or unstained specimens on a bright background.
5. _ A light microscope with extremely high resolution.
6. _ Creates 3D images from a beam of electrons scattering off a specimen's surface.
7. _ Creates very detailed, high contrast, 3D images of live specimens.
8. _ Allows the scientist to view specimens against a dark background.
9. ___ Creates high contrast, 3D images that show several planes of focus in the specimen.

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Problem Transcript

Okay, everyone. Here we have a really giant practice problem, but a really good practice problem because it helps us review all the different types of microscopes that we've learned about. So I'm going to scroll down to attempt to allow us to see everything in one page. Okay. That looks good. We can see all the answer choices and all of the questions. So I'm going to go through all of these different questions, and we're going to try to match it to the microscope that we know has those characteristics. Number 1 says, creates high contrast 3D images of deep structures and time-lapse images. The keyword here for this particular type of microscope is time lapse. There's only one microscope that we've learned about that shows us time-lapse images, which allows us to see how things move within a cell or within the body. And this is going to be the two-photon microscope right here. So f is the first answer, and then we're going to cross that out. 2 creates 2D images from a beam of electrons passing through a specimen. Keywords here are electron beam and 2-dimensional images. Remember that there are only 2 types of electron microscopes that we've talked about. 1 creates 3D images, 1 creates 2D images, and the little trick that I use to remember the difference is 2 starts with a t and the transmission electron microscope also starts with a t. So we're looking for TEM, so number 2's answer here is d. So this one right here, d. Okay. 3, creates images where the specimen's dense structures appear darker than the gray background. Okay. So most of the time in the microscopes that we've learned about, they have bright or dark backgrounds, but only one has a gray background and shows these types of microscopy shows dense structures, things like capsules around a cell or cell walls. And this is going to be a phase-contrast microscope. So 3, the answer is going to be c. So then we're going to cross this one out, and then we should cross TEM out before I forget. There we go. Okay. 4, this type of microscope allows the scientist to view stained or unstained specimens on a bright background, keyword here bright, because there's only one that has a stereotypically bright background and no other special characteristics, the bright field microscope. So 4 is going to be b. So we're going to cross that one out. 5, a light microscope with extremely high resolution. The one with extremely high resolution that is a light microscope is going to be the newest technology in light microscopy. And this is going to be the super-resolution microscope. Its name tells you about its special characteristics. So 5 is going to be g. So we'll cross that out. Okay. 6, creates 3D images from a beam of electrons scattering off a specimen's surface. So the keywords here are three-dimensional and electrons because there's only one other type of electron microscope in our answer choices and it does create 3D images. That's going to be SEM or scanning electron microscope, which the answer here is h. Cross that out. Okay. 7, creates very detailed, high contrast, 3D images of live specimens. So the keywords here to recognize this microscope are three-dimensional and live specimens. There's actually only one microscope that we've talked about that doesn't actually have to kill the specimens to see them, and this is going to create three-dimensional images. A lot of the other microscopes do use techniques in their preparation that can damage or kill the organism that you're looking at, but this one definitely does not. This is going to be the differential interference contrast microscope. So I cross that guy out. 8, allows the scientist to view specimens against a dark background. So dark background seems to be the only important characteristic here, which means this must be the dark field microscope. So this answer is e. Cross that one out. We only have one answer left, but let's have a look at our question right here. Creates high contrast 3D images that show several planes of focus in the specimen. This is going to be the confocal scanning laser microscope. Answer a. So we can cross that out. So here are all the different microscopes and their functions and their unique characteristics that you're going to use to identify them. If you need any review on any of these microscopes, that's totally fine, there's a bunch of them, go back to our microscope review table. Okay, everyone. Let's move on to our next video.

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What are the main differences between light microscopes and electron microscopes?

Light microscopes use visible light to magnify specimens, making them suitable for observing live cells and tissues. They include types like bright field, phase contrast, and fluorescence microscopes. Electron microscopes, such as the transmission electron microscope (TEM) and scanning electron microscope (SEM), use electrons for magnification, providing much higher resolution images. TEMs create 2D images of internal structures, while SEMs produce 3D images of surface structures. Electron microscopes are ideal for detailed visualization of cellular components but require specimens to be fixed and dehydrated, making them unsuitable for live samples.

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How does a phase contrast microscope enhance the visualization of specimens?

A phase contrast microscope enhances visualization by converting phase shifts in light passing through a transparent specimen into changes in brightness. This technique allows for the observation of live, unstained cells and their internal structures, which appear darker against a grayish background. The phase contrast microscope is particularly useful for studying cell morphology, motility, and organelles in their natural state without the need for staining, which can alter or damage the specimen.

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What are the advantages of using a confocal scanning laser microscope (CSLM)?

The confocal scanning laser microscope (CSLM) offers several advantages, including high contrast and the ability to create three-dimensional images. It uses a laser to scan the specimen, which allows for the collection of images from multiple planes of focus. This results in detailed, high-resolution images of thick specimens. CSLM is particularly useful in fields like cell biology and neurobiology, where it is essential to visualize complex structures and their spatial relationships within the specimen.

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What is the purpose of a super-resolution microscope in biological research?

A super-resolution microscope is designed to surpass the diffraction limit of conventional light microscopes, providing extremely high resolution, down to about 0.01 micrometers. This allows researchers to observe fine details of cellular structures that are not visible with standard light microscopy. Super-resolution microscopy is crucial for studying molecular interactions, protein localization, and other intricate cellular processes, making it a powerful tool in advanced biological research and medical diagnostics.

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How does a scanning electron microscope (SEM) differ from a transmission electron microscope (TEM)?

A scanning electron microscope (SEM) differs from a transmission electron microscope (TEM) in several ways. SEM creates three-dimensional images by detecting electrons scattered off the surface of a specimen, making it ideal for visualizing surface structures. In contrast, TEM produces two-dimensional images by transmitting electrons through a thin specimen, allowing for the observation of internal structures. SEM is used for detailed surface analysis, while TEM is used for studying the internal ultrastructure of cells and tissues.

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