วีดีโอ

Por el 🔬 se ve muy bonito

When someone ingests a poison (some type of chemical or an excessive amount of a drug…), the patient is often given an activated charcoal solution (a medical-grade type of charcoal that is free of chemical impurities and has a lot more adsorptive power than regular charcoal). The activated charcoal will bind toxins and chemicals in the stomach and intestines. This prevents the poison from being absorbed into the bloodstream. The poison-charcoal complex then continues through the digestive tract and is eventually eliminated from the body. . Activated charcoal is particularly effective at adsorbing (trapping) organic poisons, such as pesticides and certain medications (e.g., aspirin and acetaminophen). . Because activated charcoal prevents toxins from being absorbed into the bloodstream, it is most effective when given soon after ingestion of the poison (ideally within the first hour or two). . I am amazed at how well the regular charcoal I used in the video cleared out the methylene blue from the water in less than an hour. I can see why activated charcoal is also used in water filters, air purification systems... . For this video I used an Olympus CX31 microscope at 40x and 100x magnification.

Fascinating, I have tried for a long time to find one and I have not been able to, by the way, I am an educational scientific communicator, nice to meet you, my name is Hiroshi. 😊

Moss is so full of life (even in the winter)! Every piece of moss is like a miniature forest filled with all sorts of microscopic creatures. . Mosses are adapted to survive during the cold conditions of the winter. The microorganisms that live in moss are also adapted to survive the harsh winter conditions. When it is cold, the moss dwelling microorganisms enter into a state of 'suspended animation' where their metabolism slows down dramatically. . When conditions improve and water is available (rain appears), the microorganisms come back to life again. This is why before I looked at the organisms that live in the piece of moss, I hydrated the moss (for about 24 hours). By letting the moss hydrate, I allowed the microorganisms that were in 'suspended animation' to come back to life and this way I was able to observe them. . At the start of the video there was a little water bear (tardigrade) next to a ciliated protozoan. In the video you could also see different types of protozoans as well as a nematode and a rotifer. The water bear, the nematode, and the rotifer are microscopic animals (multicellular) whereas the other protozoans are made of a single cell (unicellular). . For this video, I used an Olympus CX31 microscope up to 400x magnification.

Hey, do you remember me?

Yo drink the lake water it’s not that bad The lake water:

First clip looked like rdr2

How much it costs a microscope able to see this?

Ya lo había visto y no es de los que me gustan . Por el 🔬 se aprecian los bichos mejor 😮

Telophase

I'd say it's beautiful if I wasn't 75% sure that's giardia and dysentry floating in there

This brings me back to biology class

Excellent pictures

still water 💀

We see some really strange creatures in cave water even with our eyes. We can't imagine what kind of strange microscopic ones also exist!

La naturaleza es increíblemente hermosa e impresionante para los que ven a detalle

Did you know that pretty much all bodies of water are teeming with microscopic life even when they freeze in the winter? Under the ice of this little pond, you can see lots of amazing microscopic creatures. . These are the microorganisms that you see in the video (in order of appearance): Diatoms and a swimming by ciliated protozoan Flagellate protozoan Flatworm at different magnifications until you can see the mesmerizing movement of the cilia in its body. Gonium (?) Closterium Nematode . Next time you look at a frozen pond or at a frozen lake, take a moment to think and appreciate the amazing world of microorganisms that live under that layer of ice. Although they are small and often overlooked, microscopic organisms are an essential part of all the ecosystems and deserve our appreciation. . For this video I used an Olympus CX31 microscope at 40x, 100x, 200x, and 400x magnification.

These pixels has made society worse.

Prophase+metaphase+anaphase+telophase= karyokinesis And next step is cytokinesis Karyokinesis+cytokinesis= M phase

Aunque ya lo había visto, sigo pensando que cuando se ve por el microscopio se ve muy bonito

The pineal gland is a small endocrine gland in the brain that has always fascinated me. This is the part of the body that produces melatonin, a hormone that regulates sleep-wake cycles and circadian rhythms. . The production and secretion of melatonin by the pineal gland are tightly controlled by exposure to daylight (day/night cycles). During the day, light signals from the retina are transmitted to a very important part of the brain called the hypothalamus, which communicates with the pineal gland suppressing melatonin production. At night, when the retina no longer detects light, the hypothalamus signals the pineal gland to release melatonin into the bloodstream, inducing sleep. This is why having a job that requires you to work at night, or traveling to a different time zone (jetlag) will alter your circadian rhythms. . In many animals, this same process also helps regulate seasonal behaviors like mating or hibernation (the duration of daylight signals the body about seasonal changes). . The natural production of melatonin decreases with age, this is why older people tend to sleep less than younger people. The peak of melatonin production in life is childhood and adolescence. Now you know why teenagers sleep so much! . By the way, over time the pineal gland often develops something called brain sand (corpora arenacea), which are calcified deposits primarily made of calcium phosphate and carbonate. These calcifications are common in older people, but they seem to be harmless. However, some scientists have hypothesized that excessive accumulation of brain sand in the pineal gland could contribute to certain sleep problems. . For this video I used a Leica ZOOM 200 stereoscope and an Olympus BX41 microscope at up to 1000x magnification

Why do they look like tiny shrimp? Literally look closely at a shrimp and look closely at a sand flea. You can see the difference right? I cannot.

Wow i expect at least a few little buggers in there

Ahh yes....WILD BUBBLES FINALLY!!!!

I'ma a little disappointed. I thought i was going to see some germs.

It’s so clean and gorgeous…. Nature is wonderful

X

How is it so clean?

Do you think it’s anti bacterial? I didn’t seen any bacteria waddling around under the microscope

We always said it was beaver piss 😅

amazing visuals

Danke ❤

that’s because soap is also made out of fat

Beautiful

Que bonito parecen perlas

These are the bubbles formed in a natural stream of water in the middle of the forest. . These bubbles happen because when organic matter in the forest decomposes (leaves, dead plants…), it can produce compounds that behave as soap molecules (surfactants). These compounds, when mixed with water, can create bubbles and foam (especially if the water gets agitated due to a turbulent flow of water). . This type of foam that you can see in water streams may be more noticeable after a period of heavy rainfall, when the water is carrying more of these dissolved surfactant compounds. These other “natural soap” bubbles are also incredibly beautiful under the microscope! . The shapes of nature are so beautiful! . For this video I used an Olympus CX31 microscope at 40x and 100X magnification and a polarizer filter.

Woah! You are underrated!

😍

Muy bonitas las pompas vistas al microscopio 🔬

The perfectly round ones remind me of the eyes of arachnids ♥️🕷️

Soap bubbles under the microscope are incredibly beautiful. . I love that when using polarized light, the edge of the bubbles produces a micro-rainbow. Did you see those pretty micro-rainbows? . When I added a drop of water to the bubbles, they floated on top of the water and the bubbles looked like microscopic jewels moving around. . In case you’re wondering why bubbles form when water and soap are mixed and shaken, it’s because a bubble consists of a thin layer of water trapped between two layers of soap molecules. Soap molecules are amphiphilic (they have hydrophilic heads and hydrophobic tails). The hydrophilic heads face inward toward the water layer, and the hydrophobic tails face outward, away from the water and towards the air. . The shapes of nature are so beautiful! . For this video I used an Olympus CX31 microscope at 40x magnification and a polarizer filter.

❤❤❤❤❤❤

They are adorable!❤

Wow

Caramba cualquiera toca, por eso lo haces con el zapato 😮

They may lower their metabolism due to the cold conditions, but under the ice you can still find plenty of microscopic life patiently waiting for more favorable conditions. . I was running in the forest and I found a large hole that had filled with rain water. In this video you can see that in just one single drop of this under the ice water I found a number of microscopic organisms. . These are the creatures that you could see: 1. Copepod crustacean (this one is fairly big and you can see it without the microscope swimming in the drop of water). 2. Ostracod crustacean. 3. Different types of protozoans. 4. Diatom. 5. More protozoans. . Microscopic life is everywhere and it represents another dimension of life that we don't usually get to appreciate enough. . For this video I used a Leica ZOOM 200 stereoscope and an Olympus BX41 microscope at up to 400X magnification.

thank you so for sharing it with us

now

Parece que tenemos núcleos , iguales, pero con diferentes colores

My squamous epithelial cells from the lining of my mouth and those from my dog’s mouth are incredibly similar in structure and function. . It’s quite amazing to see how both cells are similarly flat and thin. In both cases (dogs and humans), these cells are arranged in layers (stratified squamous epithelium) to form a barrier to protect the mouth tissues against mechanical injury, pathogens, and desiccation. By the way, the mouth lining is constantly shedding old cells and producing new ones). . Do you think it’s a coincidence that these cells are so similar? It isn’t. From an evolutionary perspective, dogs and humans derive from a common ancestor. This shared ancestry explains why dog and human mouth epithelial cells are so similar. This is also why genetically, anatomically, and physiologically humans and dogs are so similar! The evidence of evolution is all around us. . For this video I used an Olympus CX31 microscope at up to 400x magnification.