" Asadian Research Group "
Welcome to the Asadian Research Group Website
" Medical Sciences in Tehran, Iran "
Asadian Research Group
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- +98-21-88666136 (627)
- Email us
- e.asadian@sbmu.ac.ir
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- Medical Sciences in Tehran, Iran
Research Interests
WWW.asadianresearchgroup.com
Tissue Engineering
Tissue engineering is a transformative field that aims to restore or replace damaged tissues through the use of biomaterials, cells, and bioactive molecules. Our research focuses on utilizing biotemplates, specifically plant-derived skeletons, which are modified with various nanomaterials and stem cells to create scaffolds for wound healing and bone engineering applications. These biotemplates provide a natural framework that mimics the extracellular matrix, promoting cell adhesion, proliferation, and differentiation. By integrating innovative nanomaterials into these structures, we enhance their mechanical properties and biocompatibility, facilitating effective tissue repair. The incorporation of stem cells further supports regenerative processes, enabling targeted healing and functional recovery in damaged tissues. Through our efforts, we aim to advance the development of effective tissue engineering solutions that contribute to improved clinical outcomes in regenerative medicine.
WWW.asadianresearchgroup.com
Drug Delivery Systems
Drug delivery systems (DDS) are innovative technologies designed to transport therapeutic agents to specific target sites within the body, enhancing the efficacy of treatments while minimizing side effects. Our research focuses on developing novel nanocarriers, such as metal-organic frameworks and polymeric nanoparticles, which are engineered with various coatings to facilitate both targeted and passive drug delivery. These advanced carriers improve the pharmacokinetics of drugs, allowing for controlled release and enhanced bioavailability. By utilizing these sophisticated systems, we aim to overcome traditional challenges in drug administration, such as poor solubility and systemic toxicity, ultimately leading to more effective therapies for chronic diseases and improved patient outcomes. Through our work, we strive to contribute to the evolution of personalized medicine by ensuring that therapeutic agents reach their intended sites of action in a timely and efficient manner.
www.asadianresearchgroup.com
Electrochemical (Bio)Sensors
Wearable electrochemical (bio)sensors represent a groundbreaking advancement in health monitoring technology, offering non-invasive and real-time analysis of biological signals. These sensors leverage electrochemical principles to detect a variety of analytes, including metabolites, drugs, and physiological markers, directly from body fluids such as sweat and interstitial fluid. Their design often incorporates innovative materials like hydrogels, which enhance biocompatibility and allow for the immobilization of bioreceptors without compromising their activity. Recent developments have focused on improving the sensitivity and selectivity of these devices through the integration of nanomaterials and advanced fabrication techniques. As a result, wearable electrochemical biosensors are becoming essential tools for continuous health monitoring, enabling early diagnosis and personalized healthcare solutions while minimizing the economic burden of chronic diseases.
Asadian Research Group
Welcome to the Asadian Research Group Website!
We are proud to be part of the Department of Tissue Engineering and Regenerative Medicine at the School of Advanced Technologies in Medicine, Shahid Beheshti University of Medical Sciences (SBMU). Our research focuses on three key areas: Wearable electrochemical sensors and biosensors, where we design and develop innovative sensing platforms integrated with artificial intelligence and portable devices for efficient analysis of pharmaceutical and biological species; Drug delivery systems, utilizing cutting-edge nanocarriers for both passive and targeted delivery of therapeutic agents; and Fabrication of scaffolds enhanced with nanomaterials, aimed at applications such as wound healing and bone tissue engineering. Through our interdisciplinary approach, we strive to advance the field of regenerative medicine and improve healthcare outcomes.
