We study the dynamics of disentanglement of two qubits initially prepared in a Bell state and coupled at different sites to an Ising spin chain in a transverse field (ITF) playing the role of a dynamic spin environment. The initial state of the whole system is prepared in a tensor product state rho(Bell) circle times rho(chain), where the state of the chain is taken to be given by the ground state vertical bar G(lambda(i))> of the ITF Hamiltonian H-E(lambda(i)) with an initial field lambda(i). At time t = 0(+), the strength of the transverse field is suddenly quenched to a new value, lambda(f), and the whole system (chain + qubits) undergoes a unitary dynamics generated by the total Hamiltonian H-Tot = H-E(lambda(f)) + H-I, where H-I describes a local interaction between the qubits and the spin chain. The resulting dynamics leads to a disentanglement of the qubits, which is described through Wootters' concurrence, due to their interaction with the nonequilibrium environment. The concurrence is related to the Loschmidt echo, which in turn is expressed in terms of the time-dependent covariance matrix associated with the ITF. This permits a precise numerical and analytical analysis of the disentanglement dynamics of the qubits as a function of their distance, bath properties, and quench amplitude. In particular, we emphasize the special role played by a critical initial environment.