The $3$-path isolation number of a connected $n$-vertex graph $G$, denoted by $ι(G,P_3)$, is the size of a smallest subset $D$ of the vertex set of $G$ such that the closed neighbourhood $N[D]$ of $D$ in $G$ intersects each $3$-vertex path of $G$, meaning that no two edges of $G-N[D]$ intersect. Zhang and Wu proved that $ι(G,P_3) \leq 2n/7$ unless $G$ is a $3$-path or a $3$-cycle or a $6$-cycle. The bound is attained by infinitely many graphs having induced $6$-cycles. Huang, Zhang and Jin proved that if $G$ has no $6$-cycles, or $G$ has no induced $5$-cycles and no induced $6$-cycles, then $ι(G, P_3) \leq n/4$ unless $G$ is a $3$-path or a $3$-cycle or a $7$-cycle or an $11$-cycle. They asked if the bound still holds asymptotically for connected graphs having no induced $6$-cycles. More precisely, taking $f(n)$ to be the maximum value of $ι(G,P_3)$ over all connected $n$-vertex graphs $G$ having no induced $6$-cycles, their question is whether $\limsup_{n \to\infty}\frac{f(n)}{n} = \frac{1}{4}$. We verify this by proving that $f(n) = \left \lfloor (n+1)/4 \right \rfloor$. The proof hinges on further proving that if $G$ is such a graph and $ι(G, P_3) = (n+1)/4$, then $ι(G-v, P_3) < ι(G, P_3)$ for each vertex $v$ of $G$. This new idea promises to be of further use. We also prove that if the maximum degree of such a graph $G$ is at least $5$, then $ι(G,P_3) \leq n/4$.