Utilizing　photocatalytic　technology　to　reduce　water　or　carbon　dioxide　to　solar　fuels　and　to　selectively　or　non-selectively　oxidize　organics　to　their　respective　target　products,　is　a　promising　and　sustainable　way　to　increase　the　supply　of　energy　and　chemical　feedstocks,　reduce　greenhouse　gas　emissions,　and　solve　environmental　pollution.　However,　photoredox　reaction　proceeding　efficiently　and　stably　is　often　a　challenge　in　the　absence　of　scavengers.　A　recent　development　surge　is　integrating　solar　fuels　production　and　organic　oxidation　into　a　light-driven　photoredox　system,　so　as　to　realize　the　simultaneous　utilization　of　electrons　and　holes,　which　is　desirable　from　the　consideration　of　economic　benefits　of　photocatalytic　technology　application.　In　this　review,　we　briefly　recap　the　recent　advances　concerning　dual-function　cooperative　photoredox　catalytic　systems　integrating　solar　fuels　production　with　organic　oxidation.　Firstly,　the　dual-functional　reaction　systems　combining　hydrogen　production　and　organic　oxidation　are　discussed,　which　includes　hydrogen　evolution　coupled　with　non-selective　organic　oxidation　to　degrade　pollutants,　and　hydrogen　evolution　integrated　with　selective　organic　conversion　to　produce　value-added　chemicals.　After　that,　we　discuss　the　emerging　system　combining　carbon　dioxide　reduction　and　organic　conversion.　Finally,　we　cast　a　personal　prospect　on　the　opportunities　and　challenges　for　the　future　development　of　this　booming　and　cooperative　dual-function　photoredox　catalysis　field.　©　2022　Elsevier　B.V.