Autoradiograph Collection

DNA Double Helix with Autoradiograph
Conceptual computer illustration of the DNA double helix together with a graphic representation of an autoradiograph display

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

DNA sequence magnified by a magnifying gl

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

Computer artwork depicting babys paternity test
Paternity testing. Computer artwork of the procedure involved in a babys paternity test. A sample of DNA (deoxyribonucleic acid, far left) is taken from the baby and its parents

Radiogram of DNA on hands

Computer artwork depicting genetic screening

Chromosomes and DNA (deoxyribonucleic acid) molecules on a DNA autoradiogram, computer artwork. Chromosomes are composed of deoxyribonucleic acid (DNA) coiled around proteins

DNA helix and autoradiogram. Conceptual computer artwork of a DNA (deoxyribonucleic acid) helix (red) surrounding a genetic autoradiogram (yellow with red bands)

DNA autoradiogram and codons. Conceptual computer artwork of a DNA autoradiogram (yellow) with superimposed triplets of letters (white)

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

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

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

DNA autoradiograms and numbers. Conceptual computer artwork of DNA autoradiograms (orange) superimposed over random numbers (white)

Computer artwork depicting embryo paternity test
Embryo paternity testing. Computer artwork of a paternity test of an embryo (at upper right). A sample of DNA, deoxyribonucleic acid (orange & red strand), is taken from the embryo and its parents

Researcher holding an autoradiogram
MODEL RELEASED. Researcher holding an autoradiogram

DNA fingerprinting, sequence of bases
Conceptual computer artwork of DNA fingerprinting used to prove family relationships. The illustration is based on a sequence of bases in a fragment of DNA (deoxyribonucleic acid)

Man displaying DNA Nucleobases
Conceptual computer illustration of a man displaying initials of the primary nucleobases of DNA: cytosine, adenine, guanine, and thymine

DNA Fingerprinting, X-ray Autoradiograph
The photo shows part of an X-ray (or autoradiograph) of bands of DNA produced by the technique of electrophoresis in an agarose gel

Chromosomes and DNA, artwork
Chromosomes and DNA. Computer artwork of X (pink) and Y (green) chromosomes with an autoradiogram in the background. Chromosomes are a packaged form of DNA (deoxyribonucleic acid)

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An autoradiograph provides a fascinating glimpse into the intricate world of DNA. In this captivating image, we witness the iconic DNA double helix intertwined with an autoradiograph, showcasing its unique fingerprint-like patterns. This powerful technique, known as DNA fingerprinting or DNA analysis, allows scientists to unravel mysteries and solve complex puzzles in various fields. Zooming in on the magnifying glass reveals a scientist meticulously studying an autoradiogram, deciphering the hidden secrets within the DNA sequence. With every detail carefully examined and analyzed, this process plays a crucial role in understanding genetic information and unlocking its potential applications. The significance of this technology extends beyond scientific research; it has found practical use even in everyday life. A computer artwork showcases how paternity tests can be conducted using DNA sequencing techniques. By comparing specific regions of an individual's genetic code with those of potential parents, these tests provide valuable insights into familial relationships. DNA sequencing itself is a groundbreaking method that enables us to read and interpret the precise order of nucleotides within our genes. It revolutionizes medical diagnostics by aiding in disease identification and treatment customization based on individuals' unique genetic makeup. As we delve deeper into this mesmerizing world of genetics through autoradiographs and other advanced technologies like DNA fingerprinting, we unlock doors to countless possibilities for scientific breakthroughs and advancements across multiple disciplines.