The Masamune-Bergman reaction[cite]10.1039/C29710001516[/cite],[cite]10.1021/ja00757a071[/cite] is an example of a highly unusual class of chemical mechanism[cite]10.1021/cr4000682[/cite] involving the presumed formation of the biradical species shown as Int1 below by cyclisation of a cycloenediyne reactant. Such a species is so reactive that it will be quickly trapped, as for example by dihydrobenzene to form the final product. This cycloenediyne is not just an obscure chemical curiosity, the motif is incorporated into the natural product Calicheamicin, which is a potent antitumor antibiotic discovered in the 1980s. This drug owes its activity to the cyclisation TS1 shown below, which for n=2 occurs at the low temperature of 310K. The resulting biradical Int1 is a potent hydrogen abstractor, the species acting this way for hydrogen atoms associated with deoxyribose of DNA, ultimately leading to strand scission. Although I have explored many a mechanism on this blog using computational methods, I have never included any biradical examples. Here I explore the computational aspects of this reaction, and also include a pathway proceeding vis TS2- Int2 – TS3 in which hydrogen abstraction precedes cyclisation, in order to see how competitive such an alternative might be as a function of the ring size (n in scheme below).