The easiest way of doing it is by using the transition matrix T and then using a plain Markovian random walk (in brief, the graph can be considered as a finite-state Markov chain).
Let A and D be the adjacency and degree matrices of a graph G, respectively. The transition matrix T is defined as T = D^(-1) A.
Let p^(0) be the state vector (in brief, the i-th component indicates the probability of being at node i) at the beginning of the walk, the first step (walk) can be evaluated as p^(1) = T p^(0).
Iteratively, the k-th random walk step can be evaluated as p^(k) = T p^(k-1).
In plain Networkx terms...
# let's generate a graph G
G = networkx.gnp_random_graph(5, 0.5)
# let networkx return the adjacency matrix A
A = networkx.adj_matrix(G)
A = A.todense()
A = numpy.array(A, dtype = numpy.float64)
# let's evaluate the degree matrix D
D = numpy.diag(numpy.sum(A, axis=0))
# ...and the transition matrix T
T = numpy.dot(numpy.linalg.inv(D),A)
# let's define the random walk length, say 10
walkLength = 10
# define the starting node, say the 0-th
p = numpy.array([1, 0, 0, 0, 0]).reshape(-1,1)
visited = list()
for k in range(walkLength):
# evaluate the next state vector
p = numpy.dot(T,p)
# choose the node with higher probability as the visited node