The Zika virus became a global threat in 2015 due to its association with microcephaly. Preventing its spread depends on developing vaccines, with virus-like particles (VLP) being a promising approach, especially because of their safety profile and high immunogenicity. This study focused on the production of Zika VLP using Sf9 cells and the baculovirus expression system, evaluating cell growth kinetics, nutrient consumption, and metabolite production in Sf-900™ III medium. As a methodology, this study includes bioreactor experiments, cell density and viability quantification, nutrient and metabolite analysis, Dot Blot, Western Blot, and transmission electron microscopy. Among the critical conditions tested are culture medium supplementation with 0.028mM cholesterol/ 6nM bovine serum albumin, multiplicity of infection (MOI= 0.2 or 2), and dissolved oxygen tension (DOT= 5 or 30% air saturation). As a result, it was observed that Sf9 cells achieved rapid exponential growth, with doubling times ranging from 22.8 to 35.4hours and stable glucose and glutamine consumption. The infection phase recorded cell death rates between 8200 and 12600 cells mL⁻¹ h⁻¹, with higher VLP production under low MOI (0.2) and low DOT (5%). These conditions also reduced protein degradation and nutrient consumption. The produced VLP ranged from 32 to 73nm in size, with smaller sizes observed under low MOI conditions. Finally, controlling the DOT at 5% air saturation without cholesterol/albumin supplementation increased VLP production without the need to raise the viral load, highlighting the importance of choosing the appropriate combination of critical parameters (MOI, DOT, and medium supplementation) as key factors in optimizing the upstream process. This finding impacts substantially upstream stage efficiency and economy, which could be useful for future scaling up to the commercial manufacturing scale.