Growing　demands　on　energy　storage　devices　have　inspired　a　tremendous　amount　of　research　on　rechargeable　batteries.　Future　generations　of　rechargeable　batteries　are　required　to　have　high　energy　density,　long　lifespan,　low　cost,　high　safety,　low　environmental　impact,　and　wide　commercial　affordability.　To　achieve　these　goals,　significant　efforts　are　underway　to　focus　on　electrolyte　chemistry,　electrode　engineering,　and　new　designs　for　energy　storage　systems.　Herein,　a　comprehensive　overview　of　an　innovative　sodium-based　hybrid　metal-ion　battery　(HMIBs)　for　advanced　next-generation　energy　storage　is　presented.　Recent　advances　on　sodium-based　HMIBs　from　the　development　of　reformulated　or　novel　materials　associated　with　Na+　ions　and　other　metal　ions　(such　as　Li+,　K+,　Mg2+,　Zn2+,　etc.),　are　summarized　in　this　work.　Daniell　cell　and　＂rocking-chair＂　type　batteries　are　covered.　Finally,　the　current　challenges　and　future　remedies　in　terms　of　the　design　and　fabrication　of　new　electrolytes,　cathodes,　and　anodes　for　advanced　HMIBs　are　discussed　in　this　report.