Precise "chemical surgery" has been performed on human embryos to remove disease in a world first، Chinese researchers have told the BBC. The team at Sun Yat-sen University used a technique called base editing to correct a single error out of the three billion "letters" of our genetic code. They altered lab-made embryos to remove the disease beta-thalassemia، which were not implanted. The team says the approach may one day treat a range of inherited diseases. Base editing alters the fundamental building blocks of DNA: the four bases adenine، cytosine، guanine and thymine. They are commonly known by their respective letters، A، C، G and T. All the instructions for building and running the human body are encoded in combinations of those four bases.The potentially life-threatening blood disorder beta-thalassemia is caused by a change to a single base in the genetic code - known as a point mutation. The team in China edited it back. They scanned DNA for the error then converted a G to an A، correcting the fault. Junjiu Huang، one of the researchers، told the BBC News website: "We are the first to demonstrate the feasibility of curing genetic disease in human embryos by base editor system." He said their study opens new avenues for treating patients and preventing babies being born with beta-thalassemia، "and even other inherited diseases". The experiments were performed in tissues taken from a patient with the blood disorder and in human embryos made through cloning. Genetics revolution Base editing is an advance on a form of gene-editing known as Crispr، that is already revolutionising science. Crispr breaks DNA. When the body tries to repair the break، it deactivates a set of instructions called a gene. It is also an opportunity to insert new genetic information.Base editing works on the DNA bases themselves to convert one into another. Prof David Liu، who pioneered base editing at Harvard University، describes the approach as "chemical surgery". He says the technique is more efficient and has fewer unwanted side-effects than Crispr. He told the BBC: "About two-thirds of known human genetic variants associated with disease are point mutations. "So base editing has the potential to directly correct، or reproduce for research purposes، many pathogenic [mutations]."