Selective  laser  melting  (SLM)  is  an  additive  manufacturing  process  that  builds  metal  components according to computer-aided design (CAD), selectively fusing and consolidating metal powders one layer at a time. This incremental building approach can yield components with complex geometries, without the economic  constraints  of  traditional  large-scale  manufacturing.  This  study  systematically  investigates the influence  of  various  laser  conditions  (i.e.,  scanning  speed  and  scanning  strategy)  on  the  microstructure and  mechanical  properties  of  Co–Cr–Mo  alloys  fabricated  by  SLM.  Hot  isostatic  pressing  (HIP)  was applied after SLM to further densify the fabricated components, and their microstructures and mechanical properties  were  compared  with  those  of  untreated  components.  Parts  with  relative  density  of  ~97.26% were  obtained  with  a  high-energy  laser  and  double  laser  scanning,  and  subsequent  HIP  effectively eliminated  the  majority  of  pores.  X-ray  diffraction  revealed  that γ  and ε  phases  co-existed  owing  to  the high  solidification  rate  during  SLM.  Directional  columnar  grains  and  fine  cellular  dendrites  that  were parallel   and   normal,   respectively,   to   the   build   direction   were   observed.   Although   variations   in microstructure resulting from different SLM conditions were small, the deformation behavior remarkably changed. The improved mechanical properties was attributed mainly to increased densification and grain-boundary strengthening. However, the HIP treatment increased the tensile ductility and reduced the yield strength,  despite  the  increased  densification.  The tension-fractured  surface  suggests  that  mostly  quasi-cleavage brittle fracture took place in the SLM-processed parts.