Engaging Images - Public Art and Poetry Competition

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Location: The Forum

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COMPETITION TIME!The Saw Trust logo

Take inspiration from the photos in the 'Engaging Images' Exhibition and try your hand at either a poem and/or piece of artwork. We exhibited these images at The Forum, Norwich till Saturday 26th October 2019 as part of the Norwich Science Festival but now you can see them included below!

Please note everyone can submit up to one art piece and one written piece (poetry). The categories are:

Under 12 years old,
12 -18 years old,
Adult
Adult professional

Entries will be judged by a panel of experts and winning entries will be used as part of an exhibition at the Sainsbury Centre for Visual Arts and The Forum Trust later this year. For more information and to download your entry form please click here

All entries must be received by 11th November 2019.

Please send this entry form and supporting documents/images by email to: alexia.mlynarska@norwichresearchpark.com

Or by post to; Alexia Mlynarska,

                        Centrum
                        Norwich Research Park
                        Norwich
                        NR4 7UG
Good Luck!

Now for the Images:

A cosy lawn Juan Pablo Gomez-Escribano, John Innes Centre Most of the compounds we use as antibiotics are obtained from soil-dwelling microbes called actinomycetes. These bacteria grow as filaments on a solid substrate. When the environmental conditions are adequate, part of the filaments grow into the air and develop into spores, tiny but strong reproductive structures that can persist even under very tough conditions. In this macro-photograph of a colony of actinomycete Streptomyces coelicolor, you can see the lawn of thin white filaments over which drops of water have condensed and accumulated the blue antibiotic made by this microbe.

A Cosy Lawn

Juan Pablo Gomez-Escribano, John Innes Centre

Most of the compounds we use as antibiotics are obtained from soil-dwelling microbes called actinomycetes. These bacteria grow as filaments on a solid substrate. When the environmental conditions are adequate, part of the filaments grow into the air and develop into spores, tiny but strong reproductive structures that can persist even under very tough conditions. In this macro-photograph of a colony of actinomycete Streptomyces coelicolor, you can see the lawn of thin white filaments over which drops of water have condensed and accumulated the blue antibiotic made by this microbe.

AfriPlantSci19 - DNA extraction from local Kenyan plant tissue Danny Ward, John Innes Centre Students of the AfriPlantSci19 summer school selecting from a variety of local plant samples for DNA extraction, purification and analyses. This image was taken at the AfriPlantSci19 summer school at Pwani University, Kilifi, Kenya. The summer school is an initiative started by the John Innes Centre (JIC) and sessions like this were run by JIC staff and PhD students on internship placements in Africa.

AfriPlantSci19 - DNA extraction from local Kenyan plant tissue

Danny Ward, John Innes Centre

Students of the AfriPlantSci19 summer school selecting from a variety of local plant samples for DNA extraction, purification and analyses. This image was taken at the AfriPlantSci19 summer school at Pwani University, Kilifi, Kenya. The summer school is an initiative started by the John Innes Centre (JIC) and sessions like this were run by JIC staff and PhD students on internship placements in Africa.

An Uncertain Future Matt Heaton, John Innes Centre An Ethiopian farmer weeds his young wheat crop and checks for signs of rust while his son watches. Ethiopia is the largest wheat producer in sub-Saharan Africa and many rely on the harvest it yields. With changing climates however, fungal rusts that damage the crop are becoming more prevalent. Unless tighter detection and control strategies are developed, the future of cereal farmers is growing in uncertainty. The Saunders group at the John Innes Centre are developing new methods to track rust outbreaks more quickly so control methods can be improved.

An Uncertain Future

Matt Heaton, John Innes Centre

An Ethiopian farmer weeds his young wheat crop and checks for signs of rust while his son watches. Ethiopia is the largest wheat producer in sub-Saharan Africa and many rely on the harvest it yields. With changing climates however, fungal rusts that damage the crop are becoming more prevalent. Unless tighter detection and control strategies are developed, the future of cereal farmers is growing in uncertainty. The Saunders group at the John Innes Centre are developing new methods to track rust outbreaks more quickly so control methods can be improved.

Delayed Fluorescence in Arabidopsis Hannah Rees, Earlham Institute  Circadian clocks are inbuilt time-keepers which allow plants to anticipate daily changes in light and temperature. At the Earlham Institute we are studying circadian rhythms in thale cress plants (Arabidopsis thaliana) using delayed fluorescence (DF) imaging. The dots in the image show 96-well plates containing around 20 seedlings which are pseudo-coloured for their delayed fluorescence intensity. Plates are imaged within a purposely built dark room using CCD-cameras capable of long exposure times. Photos are taken every hour over the course of a week and help scientists to measure the natural circadian rhythms of the plants.

Delayed Fluorescence in Arabidopsis

Hannah Rees, Earlham Institute 

Circadian clocks are inbuilt time-keepers which allow plants to anticipate daily changes in light and temperature. At the Earlham Institute we are studying circadian rhythms in thale cress plants (Arabidopsis thaliana) using delayed fluorescence (DF) imaging. The dots in the image show 96-well plates containing around 20 seedlings which are pseudo-coloured for their delayed fluorescence intensity. Plates are imaged within a purposely built dark room using CCD-cameras capable of long exposure times. Photos are taken every hour over the course of a week and help scientists to measure the natural circadian rhythms of the plants.

Digesting mycoprotein Raffaele Colosimo, Quadram Institute Bioscience   Mycoprotein (such as Quorn™) is a food ingredient composed of fungal hyphae. Scientists at the Quadram Institute are investigating mechanisms underpinning the health benefits of consuming these foods by determining how the complex mycoprotein structure controls the digestion and the bioavailability of nutrients. This image is an optical micrograph showing a fusion of the gastric (left) and intestinal (right) phases of an in vitro digestion of mycoprotein. The internal proteins (pink) are partially released during the digestion, whereas the cell wall fibres remain intact with a shiny blue colour.

Digesting mycoprotein

Raffaele Colosimo, Quadram Institute Bioscience

 

Mycoprotein (such as Quorn™) is a food ingredient composed of fungal hyphae. Scientists at the Quadram Institute are investigating mechanisms underpinning the health benefits of consuming these foods by determining how the complex mycoprotein structure controls the digestion and the bioavailability of nutrients. This image is an optical micrograph showing a fusion of the gastric (left) and intestinal (right) phases of an in vitro digestion of mycoprotein. The internal proteins (pink) are partially released during the digestion, whereas the cell wall fibres remain intact with a shiny blue colour.

Leafhopper nymph Adi Kliot (sample preparation) and Eva Wegel (imaging), John Innes Centre Optical section through an infected Aster Leafhopper nymph Macrosteles quadrilineatus. The leafhopper is a vector for phytoplasma bacterium, which causes Aster Yellows Witches' Broom disease in plants. The Magenta colour in the image shows the bacterium membrane and the green colour shows the presence of a protein secreted by the bacterium.  Scientists at the John Innes Centre are investigating the role of phytoplasma proteins in manipulating both plants and insects into working for the phytoplasma, in the hopes of disrupting it and stopping the spread of disease-causing phytoplasma.

Leafhopper nymph

Adi Kliot (sample preparation) and Eva Wegel (imaging), John Innes Centre

Optical section through an infected Aster Leafhopper nymph Macrosteles quadrilineatus. The leafhopper is a vector for phytoplasma bacterium, which causes Aster Yellows Witches' Broom disease in plants. The Magenta colour in the image shows the bacterium membrane and the green colour shows the presence of a protein secreted by the bacterium.

Scientists at the John Innes Centre are investigating the role of phytoplasma proteins in manipulating both plants and insects into working for the phytoplasma, in the hopes of disrupting it and stopping the spread of disease-causing phytoplasma.

Pioneering Diagnostic Device NNUH NHS FT The Norfolk and Norwich University Hospital (NNUH) and the University of East Anglia (UEA) are developing a wearable piece of technology that hopes to speed up the diagnosis of the most common causes of dizziness, one of the most common reasons for a doctor to visit patients over the age of 75 years old. The CAVA (Continuous Ambulatory Vestibular Assessment) device uses five electrodes attached to a person’s head, is lightweight, durable, can be worn day and night to monitor head and eye movements and allows doctors to evaluate real life attacks of dizziness.

Pioneering Diagnostic Device

NNUH NHS FT

The Norfolk and Norwich University Hospital (NNUH) and the University of East Anglia (UEA) are developing a wearable piece of technology that hopes to speed up the diagnosis of the most common causes of dizziness, one of the most common reasons for a doctor to visit patients over the age of 75 years old.

The CAVA (Continuous Ambulatory Vestibular Assessment) device uses five electrodes attached to a person’s head, is lightweight, durable, can be worn day and night to monitor head and eye movements and allows doctors to evaluate real life attacks of dizziness. 

Robotic assisted surgery  NNUH NHS FT   In January the Norfolk and Norwich University Hospital (NNUH) celebrated three years of saving and transforming cancer patients’ lives through robotic surgery. The state-of-the-art robotic surgery equipment, operated by a surgeon, carried out the first radical prostatectomy in Norwich in February 2016 to remove the prostate of a cancer patient, and has since been used on average four times a week to help save more lives.  Surgeons use the four-armed robot and console, which provides a magnified 3D view, for robotic assisted prostatectomies, bladder removal, partial kidney and kidney removal and colorectal surgery.

Robotic assisted surgery

NNUH NHS FT

 In January the Norfolk and Norwich University Hospital (NNUH) celebrated three years of saving and transforming cancer patients’ lives through robotic surgery. The state-of-the-art robotic surgery equipment, operated by a surgeon, carried out the first radical prostatectomy in Norwich in February 2016 to remove the prostate of a cancer patient, and has since been used on average four times a week to help save more lives.

Surgeons use the four-armed robot and console, which provides a magnified 3D view, for robotic assisted prostatectomies, bladder removal, partial kidney and kidney removal and colorectal surgery.

Sky at night Thomas C McLean, University of East Anglia A bacterial colony of Streptomyces coelicolor growing on milk powder agar. This bacterium makes a blue pigmented antibiotic called actinorhodin which can be seen, secreted into the colony's surroundings, and in combination with the colour of the agar appears darker than the typical sky blue. Much research at the University of East Anglia, in collaboration with the John Innes Centre, has been centred around this fascinating and remarkable micro-organism and related actinomycetes to better understand their basic biology and to uncover new antibiotics.

Sky at night

Thomas C McLean, University of East Anglia

A bacterial colony of Streptomyces coelicolor growing on milk powder agar. This bacterium makes a blue pigmented antibiotic called actinorhodin which can be seen, secreted into the colony's surroundings, and in combination with the colour of the agar appears darker than the typical sky blue. Much research at the University of East Anglia, in collaboration with the John Innes Centre, has been centred around this fascinating and remarkable micro-organism and related actinomycetes to better understand their basic biology and to uncover new antibiotics.

Streptomyces bacteria  Siobhan Dorai-Raj, David Widdick (sample cultivation) and Andrew Davies (photography) John Innes Centre The bacteria in the photograph are actinomycete isolated from a soil sample collected by students at Monkfield Park Primary School, Cambourne. The students were taking part in an antibiotics-themed Science Art and Writing (SAW) project led by Prof. Barrie Wilkinson from the John Innes Centre with writer Mike O’Driscoll and artist, Chris Hann. The outreach day involved a morning of science experiments followed by poetry writing and art, all inspired by the science. The SAW Trust aims to break down the traditional barriers between science and the arts.

Awesome Actinomycetes

Siobhan Dorai-Raj, David Widdick (sample cultivation) and Andrew Davies (photography) John Innes Centre

The bacteria in the photograph are actinomycete isolated from a soil sample collected by students at Monkfield Park Primary School, Cambourne. The students were taking part in an antibiotics-themed Science Art and Writing (SAW) project led by Prof. Barrie Wilkinson from the John Innes Centre with writer Mike O’Driscoll and artist, Chris Hann. The outreach day involved a morning of science experiments followed by poetry writing and art, all inspired by the science. The SAW Trust aims to break down the traditional barriers between science and the arts.

Wheat infected with the blast fungus in Meherpur, Bangladesh Nick Talbot, The Sainsbury Laboratory Wheat infected with the blast fungus in Meherpur, Bangladesh. This destructive disease is a new plant health emergency for South Asia. It first appeared in the region in 2016 following imports of contaminated wheat from South America. Scientists at The Sainsbury Laboratory and their Bangladeshi colleagues have developed open science platforms to tackle the outbreak.

Wheat infected with the blast fungus in Meherpur, Bangladesh

Nick Talbot, The Sainsbury Laboratory

Wheat infected with the blast fungus in Meherpur, Bangladesh. This destructive disease is a new plant health emergency for South Asia. It first appeared in the region in 2016 following imports of contaminated wheat from South America. Scientists at The Sainsbury Laboratory and their Bangladeshi colleagues have developed open science platforms to tackle the outbreak.

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