Innovative spiral nerve conduits: Addressing nutrient transport and cellular activity for critical-sized nerve defects.

Large-gap nerve defects require nerve guide conduits (NGCs) for complete regeneration and muscle innervation. Many NGCs have been developed using various scaffold designs and tissue engineering strategies to promote axon regeneration. Still, most are tubular with inadequate pore sizes and lack surface cues for nutrient transport, cell attachment, and tissue infiltration.

Carboxymethyl cellulose-agarose hydrogel in poly(3-hydroxybutyrate-co-3-hydroxyvalerate) nanofibers: A novel tissue engineered skin graft.

Healing chronic and critical-sized full-thickness wounds is a major challenge in the healthcare sector. Scaffolds prepared using electrospinning and hydrogels serve as effective treatment options for wound healing by mimicking the native skin microenvironment. Combining synthetic nanofibers with tunable hydrogel properties can effectively overcome limitations in skin scaffolds made only with nanofibers or hydrogels.

Facile fabrication of Bi-layered perfusable hydrogel tubes as biomimetic 3D arterial construct.

Small-diameter arterial conduits with native physiological and biological equivalence continues to be a constant global demand posing critical challenges in fabrication. Advent of various strategies towards mimicking the structural hierarchy of a native blood vessel, often involve complex instrumentation and template-assistance with post-processing complications eventually compromising structural fidelity. In the present research, we report a template-free, facile strategy- '3D wet writing' by peripheral-core differential ionic gelation to fabricate perfusable customizable constructs of any dimension, thickness and length in <5 mins.

Reverse engineering of an anatomically equivalent nerve conduit.

Reconstruction of peripheral nervous tissue remains challenging in critical-sized defects due to the lack of Büngner bands from the proximal to the distal nerve ends. Conventional nerve guides fail to bridge the large-sized defect owing to the formation of a thin fibrin cable. Hence, in the present study, an attempt was made to reverse engineer the intricate epi-, peri- and endo-neurial tissues using Fused Deposition Modeling based 3D printing.

Tissue engineering approaches towards the regeneration of biomimetic scaffolds for age-related macular degeneration.

Age-related macular degeneration (AMD) is the third major cause of blindness in people aged above 60 years. It causes dysfunction of the retinal pigment epithelium (RPE) and leads to an irreversible loss of central vision. The present clinical treatment options are more palliative in controlling the progression of the disease and do not functionally restore the degenerated RPE monolayer and photoreceptors.

Marigold-like tyrosinase-embedded nanostructures-a nano-in-micro system.

Marigold-like tyrosinase-entrenched nanostructures were developed by a facile method using a metal cofactor to overcome the limitations of conventional enzyme immobilization techniques. The protein-copper complex promotes the hierarchical self-assembly of nanopetals into marigold-like microstructures through a sequential germination process. Nanopetals, which originated from bead-like tiny projections, showed budding over the surface and promoted the anisotropic growth of copper phosphate nanocrystals upon co-ordination with the active functional groups in protein.