In this paper, we introduce a variation of the group testing problem where each test is specified by an ordered subset of items, and returns the first defective item in the specified order. We refer to this as \textit{cascaded group testing} and the goal is to identify a small set of $K$ defective items amongst a collection of size $N$, using as few tests as possible. For the adaptive testing regime, we show that a simple scheme is able to find all defective items in at most $K$ tests, which is optimal. For the non-adaptive setting, we first come up with a necessary and sufficient condition for any collection of tests to be feasible for recovering all the defectives. Using this, we are able to show that any feasible non-adaptive strategy requires at least $\Omega(K^2)$ tests. In terms of achievability, it is easy to show that a collection of $O(K^2 \log (N/K))$ randomly constructed tests is feasible. We show via carefully constructed explicit designs that one can do significantly better. We provide two simple schemes for $K = 1, 2$ which only require one and two tests respectively irrespective of the number of items $N$. Note that this is in contrast to standard binary group testing, where at least $\Omega(\log N)$ tests are required. The case of $K \ge 3$ is more challenging and here we come up with an iterative design which requires only $\text{poly}(\log \log N)$ tests.
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