Dna Sequencing Collection

Gel electrophoresis chamber

Creation of oil using designer microbes. Conceptual computer artwork depicting an oil well pump in a petri dish, representing the use of artificially created micro-organisms to produce oil

Creation of artificial life, artwork
Creation of artificial life. Conceptual computer artwork depicting the creation of a new life-form in a petri dish. Geneticists are working on methods for combining artificially replicated genes into

DNA electrophoresis gels, artwork
DNA electrophoresis. Computer artwork of agarose electrophoresis gels. Each gel reveals different fragments of DNA. The fragments are separated by applying an electric current across the gel

View of microtubes, pipette & DNA sequence
DNA research. View of a pipettor tip (lower left) and microtubes in a rack on top of a DNA sequence. The DNA sequence which is also known as an autoradiogram

DNA fingerprints. The photo shows an X-ray (or autoradiograph) of bands of DNA produced by the technique of electrophoresis in an agarose gel

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

Automated DNA sequencing laboratory equipment and paraphernalia

DNA sequencing C016 / 9690
MODEL RELEASED. DNA sequencing. Researcher examining a flow cell from a benchtop high-throughput sequencing system (in background)

DNA sequencing C016 / 9691
MODEL RELEASED. DNA sequencing. Researcher examining a flow cell from a benchtop high-throughput sequencing system (in background)

Making money from designer microbes. Conceptual computer artwork depicting US dollar signs in petri dishes, representing the economic benefits of creating artificial micro-organisms

DNA nucleosomes, molecular model
DNA nucleosomes. Molecular model of four DNA (deoxyribonucleic acid) nucleosomes, known as a tetranucleosome. Nucleosomes are the fundamental repeating units used to package DNA inside cell nuclei

cientist studies DNA autoradiogram with magnifier
MODEL RELEASED. Gene mapping. Male scientist studies a series of DNA sequencing autoradiograms or " genetic fingerprints" through a magnifying glass

Rows of PCR systems copying human DNA
Human genome research. Rows of GeneAmp polymerase chain reaction (PCR) systems copying human DNA at the Joint Genome Institute (JGI)

Technician using a pipettor during DNA sequencing
MODEL RELEASED. DNA sequencing. Male technician using a pipettor above an electrophoresis gel during DNA (Deoxyribonucleic Acid) sequencing

Researchers sequencing human DNA in a laboratory
Human genome research. Researchers carrying out DNA sequencing at the Joint Genome Institute (JGI). Computers sit between the large automated sequencers

Computer print-out of a DNA sequence
DNA sequencing. Computer print-out of the sequence of bases in a sample of DNA (deoxyribonucleic acid). The sequence, which makes up the genetic code

Computer screen display of DNA sequencing pattern
DNA sequencing. Computer display of a DNA (deoxyribonucleic acid) sequencing pattern showing in colour the four chemical bases in DNA

Scientist examining DNA sequencing autoradiogram on a light box. Each group of four strips represents the nucleotide sequence of AGCT (Adenine-Guanine-Cytosine-Thymine)

Automated DNA sequencers for human genome project
Human genome research. Automated DNA sequencers used for the Human Genome Project. The human genome project aims to find the base sequence of all the genes in human DNA (deoxyribonucleic acid)

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

Male technician examines DNA sequences

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

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

DNA sequencing

Male technician examines DNA fingerprints
MODEL RELEASED. DNA fingerprinting. Male technician examines a DNA sequencing autoradiogram or " genetic fingerprint"

DNA sequence magnified by a magnifying glass
DNA sequences. A magnifying glass over two DNA sequences. The sequence also known as an autoradiogram is four rows of irregularly spaced black bands

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

DNA fingerprint autoradiograms
Gene mapping. Deoxyribonucleic Acid (DNA) autorad- iograms prepared as part of gene mapping studies. Banding patterns on the autoradiogram form a genetic fingerprint

Conceptual artwork of human genetic analysis
Human genetic analysis. Conceptual computer artwork of a human passing through a scanning device, representing human genetic analysis for health and medical purposes

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"Unlocking the Blueprint of Life: Exploring the Fascinating World of DNA Sequencing" In the realm of scientific marvels, gel electrophoresis takes center stage as a powerful technique in DNA sequencing. With its ability to separate and analyze fragments based on size, it unravels the intricate genetic code that defines life itself. Delving deeper into this captivating field, scientists have harnessed designer microbes to create oil – an extraordinary feat that could revolutionize energy production. These genetically modified organisms hold immense potential for sustainable fuel solutions, paving the way towards a greener future. Beyond practical applications, artists have found inspiration in DNA sequencing's creative possibilities. They craft breathtaking artworks depicting vibrant DNA electrophoresis gels, showcasing nature's hidden beauty through mesmerizing patterns and colors. Peering into a laboratory scene reveals a captivating view of microtubes filled with precious samples alongside pipettes delicately handling strands of genetic material. The meticulous process unfolds before our eyes as scientists decipher each unique DNA sequence like detectives solving mysteries encoded within our very cells. DNA fingerprints emerge as invaluable tools for identification and forensic investigations. This revolutionary technique allows us to distinguish individuals based on their unique genetic markers, unraveling secrets locked deep within our genes. Stepping into an automated DNA sequencing laboratory unveils state-of-the-art equipment and paraphernalia meticulously designed to streamline this complex process. Cutting-edge technologies enable researchers to decode vast amounts of genetic information at unprecedented speeds, propelling scientific breakthroughs forward. The codes C016/9690 and C016/9691 represent milestones in the ongoing quest for understanding life's building blocks. These significant sequences serve as guideposts along humanity's journey towards unlocking nature's deepest secrets while opening doors to endless possibilities yet unexplored. As we continue exploring new frontiers in science and technology, we witness not only groundbreaking advancements but also artistic expressions inspired by these discoveries.