Successful regeneration of weight‐bearing bone defects and critical‐sized cartilage defects
remains a major challenge in clinical orthopedics. In the past decades, biodegradable …

During the last few decades, non-thermal plasma surface functionalization of polymeric
materials has increasingly earned a high-flying position in a wide range of application fields …

Bone tissue engineering is a highly interdisciplinary field that seeks to tackle the most
challenging bone-related clinical issues. The major components of bone tissue engineering …

Millions of people lose or damage their organs or tissues due to disease, birth defects, or
accidents each year. Stem cells, such as embryonic stem cells (ESCs), induced pluripotent …

Polymer/metal nanocomposites consisting of polymer as matrix and metal nanoparticles as
nanofiller commonly show several attractive advantages such as electrical, mechanical and …

The paucity of cellular and molecular signals essential for normal wound healing makes
severe dermatological ulcers stubborn to heal. The novel strategies of skin regenerative …

The ultimate goal of tissue engineering is to replace damaged tissues by applying
engineering technology and the principles of life sciences. To successfully engineer a …

This paper provides a comprehensive overview of nanofibrous structures for tissue
engineering purposes and the role of non-thermal plasma technology (NTP) within this field …

The suffering from organ dysfunction due to damaged or diseased tissue/bone has been
globally on the rise. Current treatment strategies for non-union bone defects include: the use …

With advances in bone tissue engineering, various materials and methods have been
explored to find a better scaffold that can help in improving bone growth and regeneration …