There　is　rapid　progress　in　the　field　of　3D　printing　technology　for　the　production　of　electrodes,　electrolytes,　and　packages　of　batteries　due　to　the　technique＇s　low　cost,　a　wide　range　of　geometries　printable,　and　rapid　prototyping　speed　by　combining　computer-aided　design　with　advanced　manufacturing　procedures.　The　most　important　part　of　3D　printing　applied　in　batteries　is　the　printing　of　electrodes,　electrolytes,　and　packages.　These　will　affect　the　battery　energy/power　density.　However,　there　are　still　several　challenges　that　need　to　be　overcome　to　print　active　and　stable　electrodes/electrolytes　for　energy　storage　systems　that　can　rival　that　of　the　state-of-the-art.　In　this　review,　the　printing　materials,　and　methods　for　batteries　from　liquid　to　solid-state　batteries　are　discussed　and　recent　examples　of　this　technique　applied　in　high　power/energy　batteries　are　highlighted.　This　review　for　batteries　will　cover　3D　printing　technologies,　printed　cathode,　and　anode　in　conventional　batteries,　and　printed　solid-state　electrolytes　in　solid-state　batteries.　The　working　principles,　advantages,　and　limitations　for　solid-state　batteries　via　the　3D　printing　method　will　be　discussed　before　highlighting　the　printing　materials　for　electrodes　and　electrolytes.　We　will　then　discuss　how　to　modify　the　electrode　and　solid-state　electrolyte　to　raise　the　electrochemical　performance　of　solid-state　batteries　using　3D　printing.　Finally,　we　will　give　our　insights　into　the　future　perspectives　of　this　printing　technique　for　fabricating　batteries.　©　2022　Elsevier　Ltd