Bio Technology Collection (page 7)

Immunofluorescent LM of recombinant monkey cells

Genetic engineering. Computer artwork showing a DNA (deoxyribonucleic acid) double helix being cut by a pair of scissors, next to a model of DNAs molecular structure

Biotechnology research, conceptual image. Silhouette of a scientist looking through a microscope. The scientist is superimposed upon images of machinery and to his right are images of cells

Engineered bacteria, conceptual artwork
Engineered bacteria, conceptual computer artwork. Cutaway of a bacterium showing its underlying mechanics. This could represent the ability scientists have to alter

Genetic individuality. Conceptual computer artwork showing a womans head branded with a bar code, underneath which is the word DNA. DNA (deoxyribonucleic acid) carries genetic information

Computer graphic of deformity in a DNA molecule
Deformed DNA molecule. Computer-generated model of a segment of the molecule Deoxyribonucleic Acid (DNA), showing a deformity in its shape. DNA forms a natural double-helix shape

DNA autoradiogram on hand
DNA autoradiogram projected onto a hand. The bands (dark on light) of the autoradiogram show genetic sequences. The bands correspond to the nucleotide bases in a DNA (deoxyribonucleic acid) sample

Researcher holds DNA SeroChip for medical tests
DNA SeroChip. Researcher holding a DNA SeroChip, a type of DNA BioChip, used for cheap and rapid simultaneous analyses for infectious organisms in samples of blood

Artwork of an autoradiogram showing DNA sequences
DNA sequences. Computer artwork of an autoradiogram of DNA (deoxyribonucleic acid) sequences. A close up view of a sequence (also known as the DNA fingerprint) is superimposed in the foreground

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

DNA microarray and double helix

TEM of influenza vaccine of haemagglutinin
Transmission electron micrograph (TEM) of an experimental influenza vaccine comprising haema- gluttinin particles. The particles seen here are derived from the protein coats of many influenza

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

Immunofluorescent LM of recombinant culture cells
Recombinant cells. Immunofluorescent light micrograph of recombinant COS-9 culture cells expressing the viral gene Large T antigen. Vaults are green, mitochondria are red and cell nuclei are blue

Engineered bacteria, conceptual image. Bacteria (green) made out of Lego, representing the ability scientists have to alter and rearrange a bacteriums genetic material

Robot loading DNA in automated genome mapping
Human genome project. A robot arm loads DNA (deoxyribonucleic acid) into plastic plates in an automated laboratory dedicated to mapping the human genome

DNA helix on circuit board. Computer artwork representing the fusion of computers and humans to form cybernetic beings, or the use of computers in genetic engineering to design improved humans

Biological computing

Computers in genetic research. Conceptual computer artwork showing a computer monitor containing DNA double helices against a backdrop of cells (pink)

Artwork of DNA sequences and chromosomes
DNA sequences & chromosomes. Computer artwork of an autoradiogram of DNA (deoxyribonucleic acid) sequences. A close up view of a sequence is superimposed in the foreground

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

Lunar DNA library, conceptual computer artwork. The surface of the Moon is across bottom, with the Earth in the background

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

Genetic identity. Conceptual computer artwork of a hand, a fingerprint and a DNA microarray. These represent genetic fingerprinting and genetic identity

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 BioChip inventors examine test results

Eye and DNA autoradiogram
DNA autoradiogram reflected in an eye, computer artwork. The bands (pink and white) that make up the autoradiogram show the genetic sequence formed by the nucleotide bases in a DNA

Coloured TEM of a plasmid of DNA
Coloured transmission electron micrograph (TEM) of a closed circle or " plasmid" of DNA. A plasmid is a length of DNA that can exist apart from the chromosome

Double helix entering blackhole. Conceptual computer artwork of a double helix being sucked into a black hole. This could represent the uncharted territories

Computer artwork of DNA being manipulated
DNA manipulation. Computer artwork of a needle being inserted into a dividing cell against a background showing deoxyribonucleic acid (DNA)

Unlocking DNA, conceptual computer artwork. Key turning inside a DNA double helix. This could represent unlocking the secrets of DNA through recent discoveries and advances in genetic science

Scientist with ethidium bromide stained DNA gel
MODEL RELEASED: DNA electrophoresis. A scientist looking at DNA fragments in an electrophoresis gel. The fragments have been stained with ethidium bromide

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

Liposomes, TEM

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 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 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

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"Unleashing the Power of Bio Technology: Revolutionizing Science and Shaping Our Future" In today's rapidly advancing world, bio technology stands at the forefront of innovation, unlocking endless possibilities for humanity. As we gaze upon a computer screen displaying a mesmerizing human genetic sequence, we witness the intricate blueprint that defines our existence. But it doesn't stop there; bio technology continues to surprise us with its boundless creativity. Behold the square tomato, an extraordinary feat achieved through genetic engineering, showcasing how science can reshape nature itself. Delving deeper into this captivating realm, we encounter a DNA autoradiogram artwork—a fusion of science and art—where beauty meets scientific discovery in stunning visual representation. Zooming into the microscopic world, we observe a false-color scanning electron microscope image of hybridoma cells—an invaluable tool in producing monoclonal antibodies for medical breakthroughs against diseases like cancer. Speaking of cancer treatment advancements, an anti-cancer drug binding to DNA comes alive under atomic force microscopy (AFM), illustrating how precision medicine is revolutionizing patient care on a molecular level. The complexity behind these innovations becomes apparent as we explore genetic circuit diagrams—a roadmap guiding scientists towards manipulating biological systems for various applications such as sustainable agriculture or disease eradication. With every step forward in bio technology comes meticulous analysis. Scientists diligently examine DNA sequences using cutting-edge techniques to unravel mysteries hidden within our genes and unlock potential cures for countless ailments. Venturing beyond human genomes, grapevine genome sequencing takes center stage—unveiling secrets that enhance wine production while preserving ancient varieties cherished by connoisseurs worldwide. Yet amidst all this progress lies responsibility. The international biohazard symbol reminds us of the crucial need for safety protocols when working with potentially dangerous organisms or substances—a reminder that ethical considerations must always accompany scientific exploration. Within glass laboratory flasks bubbling with curiosity and ambition lie answers waiting to be discovered—the very essence of scientific inquiry that propels bio technology forward.