Vitamin C-Induced Photo-Redox Threshold Enables High-Fidelity Volumetric Printing of Pristine Collagen

Tomographic volumetric printing (TVP) enables rapid fabrication of complex, centimeter-scale 3D architectures. TVP of pristine proteins like collagen is attractive because it better preserves native bioactive motifs that regulate cell–matrix signaling. However, direct TVP of collagen remains challenging because dityrosine crosslinking, driven by visible-light-activated Ru(II)bpy ₃ ²⁺ /sodium persulfate (SPS), lacks an effective inhibitory mechanism. This results in near-immediate crosslinking upon exposure to light, which leads to an insufficient nonlinear threshold response that fails to suppress background curing. Here, we introduce vitamin C (L-ascorbic acid) as a biocompatible redox regulator to overcome this limitation. UV–Vis kinetics demonstrate that vitamin C suppresses Ru(III) accumulation and scavenges persulfate radicals within Ru/SPS system. This dual action generates a critical photo-redox and crosslinking threshold that inhibits dityrosine formation until vitamin C is depleted. Thereby the threshold response needed for TVP is successfully established, which enables high-fidelity volumetric printing of native collagen. Post-printing construct densification (∼53% shrinkage) further improves feature resolution (80 µm positive; 120 µm negative) and yields mechanically stable and highly stretchable hydrogels (up to 180% strain). Collagen resin with vitamin C supports both cell seeding post-printing and cell-laden printing with high cell density and viability, enabling the rapid biofabrication of cell-instructive 3D microenvironments.