OK, so you have a graph, and you need to find a path from one node (source) to another (sink) such that max edge weight on the path minus min edge weight on the path is minimized. You don't say whether your graph is directed, can have negative edge weights, or has cycles, so lets assume a "yes" answer to all these questions.

When computing your path "score" (maximum difference between edge weights), we observe these are similar to path distances: you could have a path from A to B that scores higher (undesirable) or lower (desirable). If we treat path scores like path weights we observe that as we build a path by adding new edges, the path score (=weight) can only increase: given a path A->B->C where weight(A->B)=1 and weight(B->C)=5, yielding a path score of 4, if I add edge C->D to the path A->B->C, the path score can only increase or stay the same: the difference between minimum edge weight and maximum edge weight will not be lower than 4.

The conclusion from all of this is that we can explore the graph looking for best paths as if we are looking for optimal path in a graph with no negative edges. However, there could be (and likely to be, given the connectivity described) cycles. This means that Dijkstra's algorithm, properly implemented, will have optimal performance relative to this graph's topology given what we know today.

### No solution without full graph exploration

One may be misled into thinking that we can make locally good decisions about which edge should belong to the optimal path without exploring the whole graph. The following subgraph illustrates the problem with this:

Say you've need a path from A to F, and you are at node B. Given everything you know, you'd choose a path to C, as it minimizes the path score. What you don't know (yet) is that the next edge in that path will cause the score of this path to increase substantially. If you knew that you would have chosen the edge B->D as a next element in an optimal path.