In this paper, we provide near-optimal accelerated first-order methods for minimizing a broad class of smooth nonconvex functions that are strictly unimodal on all lines through a minimizer. This function class, which we call the class of smooth quasar-convex functions, is parameterized by a constant $γ\in (0,1]$, where $γ= 1$ encompasses the classes of smooth convex and star-convex functions, and smaller values of $γ$ indicate that the function can be "more nonconvex." We develop a variant of accelerated gradient descent that computes an $ε$-approximate minimizer of a smooth $γ$-quasar-convex function with at most $O(γ^{-1} ε^{-1/2} \log(γ^{-1} ε^{-1}))$ total function and gradient evaluations. We also derive a lower bound of $Ω(γ^{-1} ε^{-1/2})$ on the worst-case number of gradient evaluations required by any deterministic first-order method, showing that, up to a logarithmic factor, no deterministic first-order method can improve upon ours.