The original question was answered by @rcollyer. I am answering the question you posted in your first comment to rcollyer's answer:

But what if instead our s is "s := NDSolve[{x'[t]^2 == -x[t]^3 - x[t] + 1, x[0] == 0.5}, x, {t, 0, 5}]" Then the FindRoot function just gives back an error while the plot shows that there is a zero around 0.6 or so.

So:

```
s = NDSolve[{x'[t]^2 == -x[t]^3 - x[t] + 1, x[0] == 0.5},
x, {t, 0, 1}, Method -> "StiffnessSwitching"];
Plot[Evaluate[{x[t]} /. s], {t, 0, 1}]
FindRoot[x[t] /. s[[1]], {t, 0, 1}]
```

```
{t -> 0.60527}
```

**Edit**

Answering rcollyer's comment, the "second line" comes from the squared derivative, as in:

```
s = NDSolve[{x'[t]^2 == Sin[t], x[0] == 0.5}, x[t], {t, 0, Pi}];
Plot[Evaluate[{x[t]} /. s], {t, 0, Pi}]
```

Coming from:

```
DSolve[{x'[t]^2 == Sin[t]}, x[t], t]
(*
{{x[t] -> C[1] - 2 EllipticE[1/2 (Pi/2 - t), 2]},
{x[t] -> C[1] + 2 EllipticE[1/2 (Pi/2 - t), 2]}}
*)
```