Haem Collection

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)

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

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 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

All Professionally Made to Order for Quick Shipping

"Unveiling the Marvels of Haem: Exploring the Complexities of Life's Oxygen Carrier" The intricate structure of haemoglobin molecule F006/9356 reveals its vital role in transporting oxygen throughout our bodies, ensuring every cell receives the life-giving element. As we delve deeper into haemoglobin molecule F006/9350, its ability to bind with oxygen becomes even more fascinating, highlighting nature's ingenious design for efficient respiration. From its elegant arrangement to its indispensable function, the haemoglobin molecule stands as a testament to evolution's brilliance in creating a complex yet essential component within our bloodstream. With each haemoglobin molecule working tirelessly, our bodies maintain an optimal balance between oxygen supply and demand – a delicate dance that keeps us alive and thriving. Glycated haemoglobin molecule C013/7781 offers insights into how sugar levels impact this crucial protein, shedding light on diabetes management and long-term blood glucose control. By studying glycated haemoglobin molecules C013/7779 and C013/7780, scientists gain valuable knowledge about diabetic complications and potential interventions for better health outcomes. Amidst countless haemoglobin molecules at work within us lies an extraordinary symphony orchestrated by nature itself – harmonizing life through oxygen transport and sustaining vitality at every moment. Unlocking the secrets held within each unique haemoglobin molecule unravels mysteries that have captivated scientists for centuries - paving the way for groundbreaking medical advancements in understanding human physiology. Beyond their scientific significance, these remarkable structures remind us of the intricacies hidden beneath our skin; they embody both beauty and functionality intertwined seamlessly within our very existence. As we marvel at these tiny heroes silently carrying out their duties day after day, let us appreciate the wonders of life made possible by humble yet extraordinary entities like the humblehaeomoglobin molecule.