Bio Chemistry Collection (page 20)

DNA cube, artwork
DNA (deoxyribonucleic acid) cube, computer artwork. The DNA cube is formed from six different DNA strands. Each side of the cube is composed of a single circular DNA strand

Gloved fingers remove DNA sample from cryostorage

DNA fingerprints: banding on DNA autoradiograms
DNA fingerprints. Banding patterns on DNA sequenc- ing autoradiograms forming " genetic fingerprints" which enables genes to be mapped

Microtubes, pipettor (pipette) tip & DNA sequence
DNA research. View of the tip of a pipettor (upper left), a type of automatic pipette, and microtubes in a rack on top of a DNA sequence

Computer artwork of DNA autoradiogram sequences
DNA sequences. Computer illustration of autoradiograms of DNA (deoxyribonucleic acid) sequences on a page which is peeling back

DNA and nerve cell, computer artwork
DNA (Deoxyribonucleic acid) strand and a nerve cell, computer artwork

Young childs face and DNA molecule
MODEL RELEASED. DNA molecule and young childs face. Composite image of a young child looking at a molecule of DNA (deoxyribonucleic acid)

DNA helices over a boys face
MODEL RELEASED. DNA molecules superimposed on a boys face. This could represent genetic individuality, or the fact that everyone is a product of the combination of the genes of their father and mother

DNA manipulation. Computer artwork showing a segment of the molecule Deoxyribonucleic Acid (DNA) in the process of being manipulated

Sequencing genes, conceptual artwork. Autoradiogram (orange) surrounded by a green glow. Autoradiograms show the order of nucleotide bases (basic building blocks)

DNA fingerprint. Conceptual image representing the individuality of DNA, showing the letters of the genetic code superimposed on a fingerprint

DNA sample. Sample vial containing DNA (deoxyribonucleic acid), the molecule that encodes the hereditary characteristics of living organisms. The vial has the letters DMD on its label

LM of aging genetically-engineered culture cells

Technician with DNA sequencers at Celera Genomics
DNA sequencers. Technician with DNA sequencers used in human genome research at Celera Genomics, Maryland, USA, a rival to the Human Genome Project

DNA molecule, conceptual computer artwork
DNA molecule. Conceptual computer artwork of the inner workings of the human body, showing the molecular structure of DNA (deoxyribonucleic acid) at left and mechanical gears at right

Male technician examines DNA sequences

Newly formed protocell, artwork
Newly formed protocell. Image 2 of 5. Artwork showing cellular components inside a basic cell membrane. This protocell (artificial cell)

DNA, conceptual artwork
DNA, conceptual computer artwork

Computer artwork of a segment of beta DNA

DNA sequence on a computer monitor screen
DNA sequence. DNA sequence or " genetic fingerprint" on a computer monitor screen. Each coloured band represents one of the bases that make up the genetic code of this sample of DNA

Technician examines results of DNA electrophoresis
MODEL RELEASED. DNA electrophoresis. Researcher looks at samples of DNA (DeoxyriboNucleic Acid) fragments which have been separated by electro- phoresis

DNA molecule and autoradiogram, artwork
DNA molecule and DNA autoradiogram, computer artwork. DNA (deoxyribonucleic acid) is composed of two strands twisted into a double helix

Storing genetic material. Researcher removing a tray of vials containing human tissue samples taken from a freezer. The DNA (deoxyribonucleic acid)

DNA fingerprinting used to prove paternity. The photo shows part of an X-ray (or autoradiograph) of bands of DNA produced by the technique of electrophoresis in an agarose gel

Viral RNA replication cycle, artwork
Viral RNA replication cycle. Computer artwork showing the three stages of the replication cycle that forms double-stranded DNA (deoxyribonucleic acid)

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Biochemistry is the captivating realm where science and life intertwine, revealing the intricate secrets of our existence. As I gaze at the computer screen displaying a mesmerizing human genetic sequence, I am reminded of the boundless potential encoded within each double-stranded RNA molecule. The elegant dance of DNA transcription unfolds before my eyes, its molecular model illuminating the blueprint of life itself. In another corner, caffeine crystals come to life under a light micrograph, reminding us that even in our daily rituals lies an underlying biochemical symphony. The iconic DNA molecule stands tall as a symbol of discovery and progress, thanks to the pioneering work of Watson and Crick who unraveled its mysteries. Isaac Asimov's brilliance shines through as we acknowledge his contributions not only as a renowned US author but also as a biochemist who bridged literature with scientific exploration. Artistic renditions capture the beauty and complexity of metabolic enzymes and secondary structures of proteins, showcasing nature's ingenuity at every turn. The quest for knowledge extends into brain protein research; unlocking these enigmatic molecules could hold answers to understanding neurological disorders that plague humanity. A stunning computer artwork reveals beta DNA segments intertwined with spheres like celestial bodies orbiting their own gravitational pull - an awe-inspiring representation of interconnectedness on both macroscopic and microscopic scales. Amidst it all lies the nucleotide base matrix - an intricate web connecting all living beings across time and space. Biochemistry beckons us to explore this matrix further; deciphering its language holds profound implications for medicine, agriculture, biotechnology, and beyond. In this captivating world where science meets life's building blocks, biochemistry invites us to unravel nature's deepest secrets while inspiring wonderment at every step along this remarkable journey.