Please see the part under the EDIT!

I think the other options are more general, and probably nicer from a programmatic view. I just had a quick idea how you could get the list in a very easy way using numpy.

First create the adjacency matrix and your list of nodes is an array:

```
import numpy as np
node_list= np.random.randint(10 , size=(10, 2))
A = np.zeros((np.max(node_list) + 1, np.max(node_list) + 1)) # + 1 to account for zero indexing
A[node_list[:, 0], node_list[:, 1]] = 1 # set connected nodes to 1
x, y = np.where(A == 0) # Find disconnected nodes
disconnected_list = np.vstack([x, y]).T # The final list of disconnected nodes
```

I have no idea though, how this will work with really large scale networks.

EDIT: The above solution was me thinking a bit too fast. As of now the solution above provides the missing edges between nodes, not the disconnected nodes (in the case of a directed graph). Furthermore, the disconnected_list includes the each node twice. Here is a hacky second idea of solution:

```
import numpy as np
node_list= np.random.randint(10 , size=(10, 2))
A = np.zeros((np.max(node_list) + 1, np.max(node_list) + 1)) # + 1 to account for zero indexing
A[node_list[:, 0], node_list[:, 1]] = 1 # set connected nodes to 1
A[node_list[:, 1], node_list[:, 0]] = 1 # Make the graph symmetric
A = A + np.triu(np.ones(A.shape)) # Add ones to the upper triangular
# matrix, so they are not considered in np.where (set k if you want to consider the diagonal)
x, y = np.where(A == 0) # Find disconnected nodes
disconnected_list = np.vstack([x, y]).T # The final list of disconnected nodes
```