Oxygenating Collection

Myoglobin molecule C015 / 5702
Myoglobin molecule. Computer model showing the structure of a myoglobin molecule. Myoglobin is a protein found in muscle tissue

Goldfish, carassius auratus, swimming around weed in round aquarium

Myoglobin molecule F006 / 9418
Myoglobin, molecular model. Myoglobin is a protein found in muscle tissue, where it binds to and stores oxygen to be used during strenuous exercise

Myoglobin molecule F006 / 9417
Myoglobin, molecular model. Myoglobin is a protein found in muscle tissue, where it binds to and stores oxygen to be used during strenuous exercise

Haemoglobin molecule F006 / 9356
Haemoglobin, molecular model. Haemoglobin is a metalloprotein that transports oxygen around the body in red blood cells. Each molecule consists of iron-containing haem groups (sticks)

Haemoglobin molecule F006 / 9350
Haemoglobin, molecular model. Haemoglobin is a metalloprotein that transports oxygen around the body in red blood cells. Each molecule consists of iron-containing haem groups (sticks)

Myoglobin protein, molecular model C016 / 6575
Myoglobin protein. Molecular model showing the structure of the myoglobin protein. Myoglobin is a protein found in muscle tissue

Kenorland prehistoric landscape, artwork
Kenorland prehistoric landscape. Artwork showing a landscape at the time of the Kenorland supercontinent (2.7 to 2.1 billion years ago) during the Archean Era and Proterozoic Era

Myoglobin molecule C015 / 5701
Myoglobin molecule. Computer model showing the structure of a myoglobin molecule. Myoglobin is a protein found in muscle tissue

Myoglobin molecule C015 / 5164
Myoglobin molecule. Computer model showing the structure of a myoglobin molecule. Myoglobin is a protein found in muscle tissue

Glycated haemoglobin molecule C013 / 7781
Glycated haemoglobin molecule. Computer model of a glycated haemoglobin molecule. The alpha and beta subunits of the haemoglobin are blue and pink, and the iron-containing haem groups are grey

Glycated haemoglobin molecule C013 / 7779
Glycated haemoglobin molecule. Computer model showing a glucose molecule (centre) bound to a molecule of haemoglobin. The alpha and beta subunits of the haemoglobin are blue and pink

Glycated haemoglobin molecule C013 / 7780
Glycated haemoglobin molecule. Computer model showing a glucose molecule (centre) bound to a molecule of haemoglobin. The alpha and beta subunits of the haemoglobin are blue and pink

Red blood cells embedded in tissue
Red blood cells. Coloured scanning electron micrograph of red blood cells in tissue. Blood is composed mainly of red blood cells (erythrocytes). Red blood cells are pumped to all parts of the body

Haemoglobin molecule, artwork
Haemoglobin molecule. Computer artwork showing the molecular structure of haemoglobin, a metalloprotein that transports oxygen around the body in red blood cells

Myoglobin molecule. Computer model showing the structure of a Myoglobin molecule. Myoglobin is a protein found in muscle tissue

Myoglobin protein
Myoglobin. Computer model of the protein myoglobin that contains the iron-containing haem group (not seen). Myoglobin consists of a chain of 153 amino acids folded into a globin molecule that has a

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"Oxygenating: A Goldfish's Underwater Oasis" In the serene depths of a round aquarium, a vibrant Goldfish named Carassius Auratus gracefully glides through the crystal-clear water. Surrounded by lush green weed, it finds solace in its own underwater oasis. As we zoom closer into this mesmerizing scene, our attention shifts to the microscopic world within the fish's body. The myoglobin and hemoglobin molecules take center stage, playing crucial roles in oxygen transport. The myoglobin molecule F006/9418 stands tall with its intricate structure, ready to bind and store oxygen for muscle cells. Its counterpart, F006/9417, works tirelessly alongside it to ensure efficient oxygenation throughout the fish's body. Meanwhile, haemoglobin molecules F006/9356 and F006/9350 showcase their remarkable ability to carry oxygen in red blood cells. These mighty warriors navigate through narrow vessels with precision and dedication. Switching gears from microcosm to macrocosm, we delve into an artistic representation of Kenorland prehistoric landscape. This captivating artwork reminds us that even ancient ecosystems relied on proper oxygenation for life sustenance. Returning our focus back to molecular marvels, multiple haemoglobin molecules make their appearance once again as if emphasizing their vital role in sustaining life. Their tireless efforts keep every cell nourished with precious oxygen while maintaining equilibrium within the fish's system. Finally, we encounter myoglobin molecule C015/5702 and its companion C015/5701 – two more heroes safeguarding cellular respiration within our beloved goldfish friend. In this captivating journey through both macroscopic landscapes and microscopic wonders alike, one thing becomes abundantly clear: Oxygenating is not just about survival; it is about thriving amidst an intricately interconnected web of life-sustaining processes.