The usage of nanoparticles in tissue engineering applications has increased significantly in the last
several years. Functional tissues are developed by regulating cell proliferation, differentiation, and migration on
nanostructured scaffolds containing cells. These scaffolds provide an environment that is more structurally supportive
than the microarchitecture of natural bone. Given its exceptional properties, such as its osteogenic potential,
biocompatibility, and biodegradability, chitosan is a good and promising biomaterial. Unfortunately,
chitosan's low mechanical strength makes it unsuitable for load-bearing applications. By mixing chitosan with
other biomaterials, this drawback might be mitigated. Bone tissue engineering uses both bioresorbable materials
like tricalcium phosphate and bioactive materials like hydroxyapatite and bioglass. Alumina and titanium are
examples of bioinert materials that are part of these bioceramics. When produced at nanoscale scales, these
materials have a larger surface area and better cell adhesion. This review paper will go into great detail on the
bioinert, bioresorbable, and bioactive nanoceramics-reinforced chitosan scaffolds for bone tissue engineering.