<p class="title">Researchers have developed a new self-calibrating, lensless endoscope that produces three-dimensional (3D) images of objects smaller than a single cell.</p>.<p class="bodytext">Without a lens or any optical, electrical or mechanical components, the tip of the endoscope measures just 200 microns across, about the width of a few human hairs twisted together, researchers said.</p>.<p class="bodytext">As a minimally invasive tool for imaging features inside living tissues, the extremely thin endoscope could enable a variety of research and medical applications, they said.</p>.<p class="bodytext">"The lensless fibre endoscope is approximately the size of a needle, allowing it to have minimally invasive access and high-contrast imaging as well as stimulation with a robust calibration against bending or twisting of the fibre," said Juergen W Czarske from the Dresden University of Technology in Germany.</p>.<p class="bodytext">The endoscope is likely to be especially useful for optogenetics -- research approaches that use light to stimulate cellular activity.</p>.<p class="bodytext">It also could prove useful for monitoring cells and tissues during medical procedures as well as for technical inspections.</p>.<p class="bodytext">Conventional endoscopes use cameras and lights to capture images inside the body.</p>.<p class="bodytext">In recent years researchers have developed alternative ways to capture images through optical fibres, eliminating the need for bulky cameras and other bulky components, allowing for significantly thinner endoscopes.</p>.<p class="bodytext">Despite their promise, however, these technologies suffer from limitations such as an inability to tolerate temperature fluctuations or bending and twisting of the fibre.</p>.<p class="bodytext">A major hurdle to making these technologies practical is that they require complicated calibration processes, in many cases while the fibre is collecting images.</p>.<p class="bodytext">To address this, the researchers added a thin glass plate, just 150 microns thick, to the tip of a coherent fibre bundle, a type of optical fibre that is commonly used in endoscopy applications.</p>.<p class="bodytext">The coherent fibre bundle used in the experiment was about 350 microns wide and consisted of 10,000 cores.</p>.<p class="bodytext">When the central fibre core is illuminated, it emits a beam that is reflected back into the fibre bundle and serves as a virtual guide star for measuring how the light is being transmitted, known as the optical transfer function.</p>.<p class="bodytext">The optical transfer function provides crucial data the system uses to calibrate itself on the fly.</p>.<p class="bodytext">A key component of the new setup is a spatial light modulator, which is used to manipulate the direction of the light and enable remote focusing.</p>.<p class="bodytext">The spatial light modulator compensates the optical transfer function and images onto the fibre bundle.</p>.<p class="bodytext">The back-reflected light from the fibre bundle is captured on the camera and superposed with a reference wave to measure the light's phase.</p>.<p class="bodytext">The position of the virtual guide star determines the instrument's focus, with a minimal focus diameter of approximately one micron.</p>.<p class="bodytext">The researchers used an adaptive lens and a 2D galvanometer mirror to shift the focus and enable scanning at different depths.</p>.<p class="bodytext">The team tested their device by using it to image a 3D specimen under a 140-micron thick coverslip.</p>.<p class="bodytext">Scanning the image plane in 13 steps over 400 microns with an image rate of 4 cycles per second, the device successfully imaged particles at the top and bottom of the 3D specimen.</p>.<p class="bodytext">However, its focus deteriorated as the galvanometer mirror's angle increased.</p>.<p class="bodytext">The researchers suggest future work could address this limitation. </p>
<p class="title">Researchers have developed a new self-calibrating, lensless endoscope that produces three-dimensional (3D) images of objects smaller than a single cell.</p>.<p class="bodytext">Without a lens or any optical, electrical or mechanical components, the tip of the endoscope measures just 200 microns across, about the width of a few human hairs twisted together, researchers said.</p>.<p class="bodytext">As a minimally invasive tool for imaging features inside living tissues, the extremely thin endoscope could enable a variety of research and medical applications, they said.</p>.<p class="bodytext">"The lensless fibre endoscope is approximately the size of a needle, allowing it to have minimally invasive access and high-contrast imaging as well as stimulation with a robust calibration against bending or twisting of the fibre," said Juergen W Czarske from the Dresden University of Technology in Germany.</p>.<p class="bodytext">The endoscope is likely to be especially useful for optogenetics -- research approaches that use light to stimulate cellular activity.</p>.<p class="bodytext">It also could prove useful for monitoring cells and tissues during medical procedures as well as for technical inspections.</p>.<p class="bodytext">Conventional endoscopes use cameras and lights to capture images inside the body.</p>.<p class="bodytext">In recent years researchers have developed alternative ways to capture images through optical fibres, eliminating the need for bulky cameras and other bulky components, allowing for significantly thinner endoscopes.</p>.<p class="bodytext">Despite their promise, however, these technologies suffer from limitations such as an inability to tolerate temperature fluctuations or bending and twisting of the fibre.</p>.<p class="bodytext">A major hurdle to making these technologies practical is that they require complicated calibration processes, in many cases while the fibre is collecting images.</p>.<p class="bodytext">To address this, the researchers added a thin glass plate, just 150 microns thick, to the tip of a coherent fibre bundle, a type of optical fibre that is commonly used in endoscopy applications.</p>.<p class="bodytext">The coherent fibre bundle used in the experiment was about 350 microns wide and consisted of 10,000 cores.</p>.<p class="bodytext">When the central fibre core is illuminated, it emits a beam that is reflected back into the fibre bundle and serves as a virtual guide star for measuring how the light is being transmitted, known as the optical transfer function.</p>.<p class="bodytext">The optical transfer function provides crucial data the system uses to calibrate itself on the fly.</p>.<p class="bodytext">A key component of the new setup is a spatial light modulator, which is used to manipulate the direction of the light and enable remote focusing.</p>.<p class="bodytext">The spatial light modulator compensates the optical transfer function and images onto the fibre bundle.</p>.<p class="bodytext">The back-reflected light from the fibre bundle is captured on the camera and superposed with a reference wave to measure the light's phase.</p>.<p class="bodytext">The position of the virtual guide star determines the instrument's focus, with a minimal focus diameter of approximately one micron.</p>.<p class="bodytext">The researchers used an adaptive lens and a 2D galvanometer mirror to shift the focus and enable scanning at different depths.</p>.<p class="bodytext">The team tested their device by using it to image a 3D specimen under a 140-micron thick coverslip.</p>.<p class="bodytext">Scanning the image plane in 13 steps over 400 microns with an image rate of 4 cycles per second, the device successfully imaged particles at the top and bottom of the 3D specimen.</p>.<p class="bodytext">However, its focus deteriorated as the galvanometer mirror's angle increased.</p>.<p class="bodytext">The researchers suggest future work could address this limitation. </p>