Bioinspired　superhydrophobic　surfaces　have　attracted　great　interest　due　to　their　special　functions　and　wide　applications.　However,　it　is　still　a　big　challenge　to　construct　a　durable　superhydrophobic　coating　for　large-scale　applications　due　to　its　easy　destruction　by　the　mechanochemical　attack.　In　this　mini-review,　we　present　the　state-of-the-art　developments　in　the　rational　design　of　mechanochemical　durable　and　self-healing　superhydrophobic　surfaces.　First,　the　mechanically　durable　superhydrophobic　surfaces　are　constructed　to　endure　mechanical　damage　by　adjusting　the　surface　morphology　and　increasing　the　binding　force　between　the　substrates　and　the　modified　materials.　Second,　chemical　damages　also　have　been　taken　into　consideration　to　develop　chemically　robust　superhydrophobic　surfaces,　such　as　chemical　etching,　ultraviolet　(UV)-light　irradiation,　and　bioerosion,　etc.　Third,　endowing　superhydrophobic　coatings　with　self-healing　function　can　effectively　improve　the　durability　and　prolong　the　lifespan　of　the　coatings　by　releasing　low-surface-energy　agents　or　regenerating　topographic　structures.　Finally,　the　challenges　and　future　perspectives　in　developing　super　durable　bioinspired　superhydrophobic　surfaces　by　structure　design　and　chemistry　control　are　discussed.　The　innovative　points　provided　in　this　mini-review　will　provide　deep　fundamental　insight　for　prolonging　the　lifetime　of　the　superhydrophobic　surfaces　and　enable　their　practical　applications　in　the　near　future.