**EDIT**: Your edit clarifies you are interested in *Best-First Search*, and not *BFS*.

**Best-First Search is actually an informed algorithm**, which expands the most promising node first. Very similar to the well known A* algorithm (actually A* is a specific best-first search algorithm).

**Dijkstra is uninformed algorithm** - it should be used when you have no knowledge on the graph, and cannot estimate the distance from each node to the target.

Note that A* (which is a s best-first search) decays into Dijkstra's algorithm when you use heuristic function `h(v) = 0`

for each `v`

.

In addition, **Best First Search is not optimal** [not guaranteed to find the shortest path], and also A*, if you do not use an admissible heuristic function, while Dijkstra's algorithm is always optimal, since it does not relay on any heuristic.

**Conclusion**: Best-First Search should be prefered over dijkstra when you have some knowledge on the graph, and can estimate a distance from target. If you don't - an uninformed Best-First Search that uses `h(v) = 0`

, and relays only on already explored vertices, decays into Dijkstra's algorithm.

Also, if optimality is important - Dijkstra's Algorithm always fit, while a best-first search algorithm (A* specifically) can be used only if an appropriate heuristic function is available.

**Original answer - answering why to chose Dijkstra over BFS:**

BFS fails when it comes to **weighted graphs**.

**Example:**

```
A
/ \
1 5
/ \
B----1----C
```

In here: `w(A,B) = w(B,C) = 1, w(A,C) = 5`

.

BFS from A will return `A->C`

as the shortest path, but for the weighted graph, it is a path of weight 5!!! while the shortest path is of weight 2: `A->B->C`

.

Dijkstra's algorithm will not make this mistake, and return the shortest weighted path.

**If your graph is unweighted - BFS is both optimal and complete** - and should usually be prefered over dijkstra - both because it is simpler and faster (at least asymptotically speaking).