Using a simple low-cost 3D bio-printer, the bio-ink was successfully extruded in concentric circles to form the shape of a human cornea. It took less than 10 minutes to print.

Published Date

31 – May – 2018

| Last Updated

31 – May – 2018

First 3D-printed human corneas could aid transplants in the futur...

In a first, British scientists have 3D printed human corneas that could cut down shortage of eye donors available for transplant.


In the research, researchers from Britain’s Newcastle University, mixed stem cells (human corneal stromal cells) from a healthy donor cornea with alginate and collagen to create a solution that could be printed or a “bio-ink”.


Using a simple low-cost 3D bio-printer, the bio-ink was successfully extruded in concentric circles to form the shape of a human cornea. It took less than 10 minutes to print.


“Our unique gel — a combination of alginate and collagen — keeps the stem cells alive whilst producing a material which is stiff enough to hold its shape but soft enough to be squeezed out the nozzle of a 3D printer,” said lead author Che Connon, a professor at the varisty.


The results published in the journal, Experimental Eye Research, also stated that the stem cells could culture — or grow.


“…we have a ready to use bio-ink containing stem cells allowing users to start printing tissues without having to worry about growing the cells separately,” Connon added.


According to the researchers, there is a significant shortage of corneas available to transplant, with 10 million people worldwide requiring surgery to prevent corneal blindness as a result of diseases such as trachoma, an infectious eye disorder


Further, the study also demonstrated that the cornea could also be built to match a patient’s unique specifications.


The dimensions of the printed tissue were originally taken from an actual cornea. By scanning a patient’s eye, they could use the data to rapidly print a cornea which matched the size and shape, the team explained.


“…what we have shown is that it is feasible to print corneas using coordinates taken from a patient eye and that this approach has potential to combat the world-wide shortage,” Connon said.


However, the researchers admitted that further investigations on 3D printed corneas are needed before they could be used in transplants.



‘).insertAfter(‘.inside-container p:eq(1)’); */
// $( ” ).insertAfter(‘.inside-container p:eq(0)’);
//});#}
//method to trunkate the text
function shorten(text, maxLength) {
var ret = text;
if (ret.length > maxLength) {
ret = ret.substr(0,maxLength-3) + “…”;
}
return ret;
}

$(function(){
//function to put utm on DontMiss links
/*if(isDesktop()){
$(‘div.dontMiss > a’).each(function(){
$(this).prop(‘href’, $(this).prop(‘href’)+’?utm_source=within_article&utm_medium=desktop&utm_campaign=related’);
//trunkate dont miss content
var sub = shorten($(this).html(),47);
$(this).html(sub);
});
}else{
$(‘div.dontMiss > a’).each(function(){
$(this).prop(‘href’, $(this).prop(‘href’)+’?utm_source=within_article&utm_medium=mobile&utm_campaign=related’);
});
}*/

//disabled method to append dontmiss links to page content by Mayank
/*$(‘div.dontMiss > a’).each(function(index){
//loop over each list item

// if(index%2 > 0){
// index = index – 1;
// }
if($(‘.inside-container > p:eq(‘+index+’)’).length){
if(isDesktop()){
$(‘.inside-container > p:eq(‘+((index * 2) + 1)+’)’).append(‘

Related: ‘ + $(this).html() + ‘‘ );
}else{
$(‘.inside-container > p:eq(‘+((index * 2) + 1)+’)’).append(‘

Related: ‘ + $(this).html() + ‘‘ );
}
}
});*/
$(‘div.dontMissArea’).hide();

/* if(isDesktop()) {
$(‘div.dontMissArea’).hide();
}else{
$(‘div.dontMissArea’).show();
} */

/*
* ga event tracking on page scroll start and end by Mayank
*/

// Debug flag
var debugMode = false;

// Default time delay before checking location
var callBackTime = 100;

// # px before tracking a reader
var readerLocation = 150;

// Set some flags for tracking & execution
var timer = 0;
var scroller = false;
var endContent = false;
var didComplete = false;

// Set some time variables to calculate reading time
var startTime = new Date();
var beginning = startTime.getTime();
var totalTime = 0;

// Get some information about the current page
var pageTitle = document.title;

// Track the aticle load — disabled
if (!debugMode) {
// ga(‘send’, ‘event’, ‘Reading’, ‘ArticleLoaded’, pageTitle, {‘nonInteraction’: 1});
// console.log(“ga(‘send’, ‘event’, ‘Reading’, ‘ArticleLoaded’, pageTitle, {‘nonInteraction’: 1}”);
} else {
alert(‘The page has loaded. Woohoo.’);
}

// Check the location and track user
function trackLocation() {
bottom = $(window).height() + $(window).scrollTop();
height = $(document).height();

// If user starts to scroll send an event
if (bottom > readerLocation && !scroller) {
currentTime = new Date();
scrollStart = currentTime.getTime();
timeToScroll = Math.round((scrollStart – beginning) / 1000);
if (!debugMode) {
ga(‘send’, ‘event’, ‘Reading’, ‘StartReading’, pageTitle, timeToScroll, {‘metric1’ : timeToScroll});
} else {
alert(‘started reading ‘ + timeToScroll);
}
scroller = true;
}

// If user has hit the bottom of the content send an event
if (bottom >= $(‘.inside-container’).scrollTop() + $(‘.inside-container’).innerHeight() && !endContent) {
currentTime = new Date();
contentScrollEnd = currentTime.getTime();
timeToContentEnd = Math.round((contentScrollEnd – scrollStart) / 1000);
if (!debugMode) {
if (timeToContentEnd = height && !didComplete) {
currentTime = new Date();
end = currentTime.getTime();
totalTime = Math.round((end – scrollStart) / 1000);
if (!debugMode) {
ga(‘send’, ‘event’, ‘Reading’, ‘PageBottom’, pageTitle, totalTime, {‘metric3’ : totalTime});
} else {
alert(‘bottom of page ‘+totalTime);
}
didComplete = true;
}
}

// Track the scrolling and track location
$(window).scroll(function() {
if (timer) {
clearTimeout(timer);
}

// Use a buffer so we don’t call trackLocation too often.
timer = setTimeout(trackLocation, callBackTime);
});
});

‘).insertAfter(“.inside-container p:eq(2)”);
}

});



Source link