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#Microscopy Reel by @evidentmicroscopy (verified account) - This #MicroscopeMonday comes from @tardibabe on our BX53 system! 🔬

This awesome video features a Stephanoceros fimbriatus rotifer!

"Rotifers are a — This #MicroscopeMonday comes from @tardibabe on our BX53 system! 🔬 This awesome video features a Stephanoceros fimbriatus rotifer! "Rotifers are also referred to as « Wheel Animals » because of the rotating cilia, called corona, they have on their heads! They usually use these cilia to create a water current that attracts food particles like bacteria, algae, ciliates and other microorganisms to the mouth. Although this species is a bit different from the other rotifers. Instead of having some rotating wheels on their heads, they have five long tentacles with moving cilia that redirect preys toward the mouth! These rotifers are basically ambush predators waiting for preys to pass by. Preys then get trapped into small compartments before getting pumped by sphincter muscles and ultimately being swallowed. Most rotifers are planktonic and swim around but Stephanoceros fimbriatus is sessile, their adult stage is immobile. When in their larval stage, they swim around until they find a nice spot to stay for the rest of their lives. I found this one sticked to an hydra, which is kind of odd since the hydra could easily have eaten the rotifer." Looking to get into the fascinating world of microscopy? Discover the #microworld with our microscopy solutions! Check the link in our bio. 📸: @tardibabe 🔬: Olympus BX53 . . . #MicroWorld #Microscopy #Optics #Imaging #Objective #LifeScience #Biology #Research #Science #Scientists #LabLife #Laboratory #ImagingTechnology #FluorescenceMicroscopy #ConfocalMicroscopy #Microbiology #SciArt

#Microscopy Reel by @dr.bio4ever - Plants take up carbon dioxide and release oxygen, but how do gases actually move in and out of a leaf? In this video, you can see oxygen gas being rel — Plants take up carbon dioxide and release oxygen, but how do gases actually move in and out of a leaf? In this video, you can see oxygen gas being released from a spider plant leaf. . Why do plants take in carbon dioxide? Plants need carbon dioxide to carry out photosynthesis, which is their way of making their own food from scratch. They do so by reactions involving carbon dioxide and water. This process is powered by sunlight energy. . How do plants take in carbon dioxide and release oxygen? Because carbon dioxide is a gas, plants use tiny pores that open and close to allow carbon dioxide to enter the plant. These pores are called stomata and are usually very abundantly located on the underside of the leaf. As a byproduct of photosynthesis, oxygen (another gas) is generated (this is the very oxygen that we breathe!). That oxygen exits the plant through the same pores (stomata) that the plant uses to take up carbon dioxide. . In other words, stomata are the “mouths” that plants use to “breathe” (do gas exchange). The bubbles you see forming on the leaf are due to oxygen leaving through these microscopic openings. . Unavoidably, every time that stomata open, water vapor escapes the plant too (transpiration). As water evaporates from the leaves, it creates a negative pressure that pulls water (and dissolved minerals) up from the roots into the plant. This is basically the force that allows roots to “suck up” water and nutrients from the soil into the plant!! . Plant biology is fascinating! . For this video I used a Leica ZOOM 200 stereoscope and an Olympus BX41 microscope at up to 400x magnification #microscopy #stomata

#Microscopy Reel by @science_intoimages - Some sped up clips of Paramecium to better see the contractile vacuoles in action 🦠🔬
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#science #biology #microscopy — Some sped up clips of Paramecium to better see the contractile vacuoles in action 🦠🔬 . . . #science #biology #microscopy

#Microscopy Reel by @museumofscience (verified account) - How can you observe tardigrades? You take a look at moss: their natural habitat!

Our friend @tardibabe took a look and found tardigrades from two gen — How can you observe tardigrades? You take a look at moss: their natural habitat! Our friend @tardibabe took a look and found tardigrades from two genera: Milnesium and Macrobiotus. Milnesium tardigrades have long, pointy claws and a decorated snout, which help them grab, manipulate, and stabilize their prey. Macrobiotus have shorter claws and a simpler snout, which makes them vegetarians feeding off of algae and plant cells, with the occasional relapse into a carnivorous diet when feeding on microscopic animals. It also allows them to slurp out of air bubbles. These animals highlight some of the biodiversity that can be found in microscopic environments! @Tardibabe safely returned them to their natural habitat after taking a quick look. #Science #Microscope #Microscopy #Animals #Tardigrade

#Microscopy Reel by @microselwyn (verified account) - Inside a drop of water, this tiny animal is running a microscopic feeding machine.

Looks like this is a Bdelloid rotifer.

The spinning "propeller" — Inside a drop of water, this tiny animal is running a microscopic feeding machine. Looks like this is a Bdelloid rotifer. The spinning “propeller” at the front isn’t a wheel at all. it’s thousands of tiny beating hairs called cilia creating currents that pull food straight into its mouth. At this scale, water behaves more like syrup than the water we know, so these creatures evolved clever ways to move and feed. #microscopy #microbiology #smallthingsbigwonders #hiddenworld #microorganisms

#Microscopy Reel by @microbiochronicles - The Gram staining classic… 🧫🔬

Step by step:
Crystal violet → Iodine → Decolorization → Safranin.

But let's be honest for a moment…
The decolorizat — The Gram staining classic… 🧫🔬 Step by step: Crystal violet → Iodine → Decolorization → Safranin. But let’s be honest for a moment… The decolorization step is where the real art of microbiology happens. Too long? Everything turns pink. Too short? Everything stays purple. Every lab tech and microbiologist develops their own instinct for that exact moment to stop. So I’m curious 👇 What’s the best trick you learned for the decolorization step in Gram staining? • Timing? • Angle of the slide? • Drop by drop technique? • Or just pure experience? Let’s compare real lab practices in the comments. #fyp #explore #science #phd #microbiology #gramstain #microbiologylab #lablife #scientist #labtech #biotech #researchlife #laboratory #microscopy #stem #microbiologia #mikrobiyoloji

#Microscopy Reel by @tardibabe (verified account) - Spring's here! 🐣🌸

As temperatures begin to rise (not fast enough imo, it's still freezing in Montreal), sap in maple trees thaws and can be collect — Spring’s here! 🐣🌸 As temperatures begin to rise (not fast enough imo, it’s still freezing in Montreal), sap in maple trees thaws and can be collected, then boiled and concentrate into syrup and transformed into candies, desserts, and just about anything your sweetest dreams are made of. Although maple syrup is primarily composed of sugar (sucrose), its chemistry and flavor are shaped by a complex interplay of factor like sap collection and processing methods, microbial activity within the sap, environmental conditions, and the packaging and storage of the final product. Not only maple syrup is composed of sugar but also a mixture of water, minerals, organic acids, amino acids, proteins, phenol compounds and even a few vitamins. Flavors and composition also varies depending on depending on the Country it has been produced! Canada, especially the province of Quebec, where I’m from, is by far the world’s largest producer of maple syrup, followed by the United States. It’s important to recognize that maple syrup was first introduced to European colonizers by First Nations, who deserve the credit for this knowledge and tradition! As you can see from my sample, sugar from maple syrup crystallizes over time and it’s mesmerizing to look at under the microscope! 🔬 Video taken with my iPhone mounted on an Olympus BX53 microscope with an @ilabcam adapter 🔬 @evidentmicroscopy

#Microscopy Reel by @verdate_ - Lo que estás observando es Aspergillus niger, un hongo filamentoso ampliamente distribuido en el ambiente, especialmente en suelos y materia orgánica — Lo que estás observando es Aspergillus niger, un hongo filamentoso ampliamente distribuido en el ambiente, especialmente en suelos y materia orgánica en descomposición. Al microscopio, se caracteriza por sus conidióforos largos que terminan en una estructura esférica cubierta de esporas negras (conidios), responsables de su apariencia oscura característica. Este hongo es de gran importancia industrial: se utiliza en la producción de ácido cítrico, enzimas y biotecnología alimentaria. Sin embargo, también puede actuar como oportunista, causando infecciones en personas inmunocomprometidas y contaminando alimentos. Así, Aspergillus niger representa un equilibrio entre beneficio y riesgo en microbiología. ⸻ 📚 Referencias científicas • Brock Biology of Microorganisms • National Center for Biotechnology Information. Aspergillus niger overview • Centers for Disease Control and Prevention (CDC). Aspergillosis • Cairns, T. C., Nai, C., & Meyer, V. (2018). How a fungus shapes biotechnology: Aspergillus niger. Biotechnology Advances #Hongo #aspergillus#ciencia #science#microscopy

#Microscopy Reel by @tardibabe (verified account) - A tardigrade!!! 😱

Here are the microorganisms I found:

1. Water fleas. These are microscopic crustaceans named Scapholeberis! I love how they have — A tardigrade!!! 😱 Here are the microorganisms I found: 1. Water fleas. These are microscopic crustaceans named Scapholeberis! I love how they have a little spike and some black pigments. These melanin pigments are found on the body parts facing towards light. Some research have shown that melanin would protect these creatures from photo damage! 2. Water bear. Found this little tardigrade walking around some green algae! Check out my tardigrade posts to learn more about them little babes 3. Red water mite. Unlike spiders, their close relatives, mites found ways to colonise under water habitats. There are thousands of aquatic mite species, mostly living in freshwater springs, streams, lakes and temporary pools, although some can be found in salt water 4. Mosquito pupa. Mosquitoes go through 4 stages: eggs, larva, pupa and adult! Here you can see the pupa with the future eyes and antennae. 5. Phacus gigas. This green leaf is an algae that can be found in freshwater habitats around the world. They swim with their flagellum located in front of the cell. The red eyespot is a photoreceptor responsible for detecting light! With this, Phacus can orient itself and swim toward a light source and ultimately produce energy by photosynthesis! 6. Gieysztoria sp. A free-living flatworm gliding aided by thousands of cilia. This one was around 0.7mm and you can even see their little black eyes, used to detect light 7. Synchaeta sp. This is a planktonic rotifer that usually zoom around super fast. Rotifers are among the smallest animals on earth! They possess a ciliated corona on their head which is used to attract food particles but also to swim around freely! The single dark eye is also visible as well as the stomach filled with algae. The most visible structure is probably the v-shaped pharynx muscle! 8. Dinobryon sp. These golden algae live in colonies that form multiple branches, making them look a bit like wheat, don’t you think? Every gold bean is a single cell encased in a protective shell called the lorica. Each cell possess two unequal flagella whipping around, a short and a long one, enabling them to move around.

#Microscopy Reel by @museumofscience (verified account) - Feathers: ancient, engineered, and way more than just for flight. 🪶

Our friend @tardibabe headed to Bonaventure Island and Percé Rock National Park — Feathers: ancient, engineered, and way more than just for flight. 🪶 Our friend @tardibabe headed to Bonaventure Island and Percé Rock National Park and a feather from a Northern Gannet (Morus Bassanus) which sparked a deep dive into the story of feathers themselves. The earliest known feathered bird, Archaeopteryx, lived over 150 million years ago and likely shared a common ancestor with theropod dinosaurs. Thousands of fossil discoveries reveal that many non-avian dinosaurs also had feathers, including complex types that are not found in modern birds. Like our hair, feathers are made of keratin and grow from follicles in the skin. Once fully formed, they’re biologically inactive but functionally brilliant. A single bird can have more than 20,000 feathers. Each one is built from a central shaft called a rachis, which branches into barbs that split again into microscopic barbules. These barbules end in tiny hook-like structures that latch neighboring barbs together, like nature’s version of Velcro. A single feather can contain over a million of them. Feathers can vary dramatically in shape, size, and color depending on a bird’s life stage, season, or function, whether for warmth, camouflage, communication, or lift. And when birds molt, they don’t just lose feathers randomly. Flight and tail feathers fall out in perfectly timed pairs to keep balance mid-air. From fossils in stone to the sky above us, feathers are evidence of evolution at its most innovative, designed by dinosaurs, refined by birds, and still outperforming modern engineering. #Science #Birds #Feathers #Microscopy #Microscope #UpClose

#Microscopy Reel by @science.sam (verified account) - The last image required over 100 images for focus stacking after carefully cleaning, lighting and post-processing the specimen over the course of 2 we — The last image required over 100 images for focus stacking after carefully cleaning, lighting and post-processing the specimen over the course of 2 weeks 😩 No wonder it took first place!! All images are shared with permission courtesy of @nikonsmallworld, who host the largest annual video & photo competitions for all things small captured through a light microscope. Below are details on the top 3 winners: 🥉John-Oliver Dum (Medienbunker Produktion, Rheinland Pfalz, Germany) “Pollen in a garden spider web” 🔬Image Stacking at 20X (Objective Lens Magnification) 🥈Dr. Jan Rosenboom (Rostock, Mecklenburg Vorpommern, Germany) “Colonial algae (Volvox) spheres in a drop of water” 🔬Reflected light at 5X (Objective Lens Magnification) 🥇Zhang You (Kunming, Yunnan, China) “Rice weevil (Sitophilus oryzae) on a grain of rice” 🔬Image Stacking at 5X (Objective Lens Magnification) Which one is your favourite? #science #scicomm #microscope #microscopy #scienceart

#Microscopy Reel by @every.min.on.a.min (verified account) - The Hardest Armor You Own Isn't Metal 🦷

Did you know your teeth are actually a masterclass in advanced ceramic engineering? Beneath the glossy surfa — The Hardest Armor You Own Isn't Metal 🦷 Did you know your teeth are actually a masterclass in advanced ceramic engineering? Beneath the glossy surface lies a structural paradox of hydroxyapatite prisms woven into a complex, crack-defying geometric maze. These microscopic "Hunter-Schreger bands" act like biological plywood, stopping fractures in their tracks before they can shatter your smile. Hit subscribe to unlock more hidden secrets of human physics! #science #humanbody #biology #microscopy #physics #evolution #anatomy #engineering #dentistry #shorts #nature

✨ #Microscopy Discovery Guide

Instagram hosts 1.2 million posts under #Microscopy, creating one of the platform's most vibrant visual ecosystems. This massive collection represents trending moments, creative expressions, and global conversations happening right now.

Discover the latest #Microscopy content without logging in. The most impressive reels under this tag, especially from @tardibabe, @microbiochronicles and @dr.bio4ever, are gaining massive attention. View them in HD quality and download to your device.

What's trending in #Microscopy? The most watched Reels videos and viral content are featured above. Explore the gallery to discover creative storytelling, popular moments, and content that's capturing millions of views worldwide.

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