The CONGEST model for distributed network computing is well suited for analyzing the impact of limiting the throughput of a network on its capacity to solve tasks efficiently. For many "global" problems there exists a lower bound of Ω(D+n/B), where B is the amount of bits that can be exchanged between two nodes in one round of communication, n is the number of nodes and D is the diameter of the graph. Typically, upper bounds are given only for the case B=O(logn), or for the case B=+∞. For B=O(logn), the Minimum Spanning Tree (MST) construction problem can be solved in O(D+nlog∗n) rounds, and the Single Source Shortest Path (SSSP) problem can be (1+ϵ)-approximated in O(ϵ−O(1)(D+n)) rounds. We extend these results by providing algorithms with a complexity parametric on B. We show that, for any B=Ω(logn), there exists an algorithm that constructs a MST in O(D+n/B) rounds, and an algorithm that (1+ϵ)-approximate the SSSP problem in O(ϵ−O(1)(D+n/B)) rounds. We also show that there exist problems that are bandwidth insensitive.