diff --git a/1_tps_sampling_tutorial.ipynb b/1_tps_sampling_tutorial.ipynb
index bf34b4e..195bfe1 100644
--- a/1_tps_sampling_tutorial.ipynb
+++ b/1_tps_sampling_tutorial.ipynb
@@ -59,7 +59,7 @@
    "source": [
     "The next cell shows you how to set up several things specific to OpenMM. We'll be running in the $NVT$ ensemble, with $T=300 K$. We're using the [Velocity Verlet with Velocity Randomization (VVVR) integrator](http://arxiv.org/abs/1301.3800), which simulates Langevin dynamics. Note that the integrator itself comes from [`openmmtools`](https://github.com/choderalab/openmmtools), a library that extends OpenMM. You should always use a reversible integrator when performing path sampling simulations. The default integrators in OpenMM are leapfrog-based, and therefore not reversible.\n",
     "\n",
-    "You can learn a lot more about setting up OpenMM simulations from the [OpenMM documentation](http://docs.openmm.org/). However, it is often even easier to use the [OpenMM Script Builder](http://builder.openmm.org/) to learn how to set up the simulation the way you'd like."
+    "You can learn a lot more about setting up OpenMM simulations from the [OpenMM documentation](http://docs.openmm.org/). However, it is often even easier to use [OpenMM-Setup](https://github.com/openmm/openmm-setup/) to learn how to set up the simulation the way you'd like."
    ]
   },
   {