The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
Researchers from the College of Mechanical, Aerospace and Manufacturing Engineering in UConn’s School of Engineering, pursue groundbreaking analysis to grasp the influence of aging-related physicochemical modifications on the construction and performance of elastin, a significant protein that imparts elasticity and recoil operate to many connective tissues within the human physique, together with inside elastic arteries. These modifications play a big function in age-related ailments corresponding to diabetes, motivating the significance of finding out elastin’s conduct in ageing arteries.
Led by Dr. Anna Tarakanova, the challenge has been awarded a $3 million R01 grant from the Nationwide Institutes of Well being (NIH) by way of 2028 to additional examine elastin and its function in arterial biomechanics in well being and ageing. Using a pioneering multi-scale method, the analysis integrates superior computational modeling and experimental research to unravel the complicated processes of elastin deterioration from sub-molecular to tissue scales. By doing so, the group goals to realize crucial insights into the mechanisms underlying arterial stiffening and different adjustments to vascular biomechanics throughout ageing and illness.
Dr. Katherine Yanhang Zhang, Professor of Mechanical Engineering at Boston College, is a co-Investigator on the challenge.
“This collaborative challenge has the potential to remodel our elementary understanding of the molecular-scale processes that underlie arterial mechanical adjustments as we age, and drive essentially the most prevalent aging-associated ailments,” stated Tarakanova.
This modern framework not solely deepens our understanding of arterial biomechanics from the smallest scale up, but additionally holds the promise of creating preventative and reparative interventions to many age-related vascular ailments. The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
Researchers from the College of Mechanical, Aerospace and Manufacturing Engineering in UConn’s School of Engineering, pursue groundbreaking analysis to grasp the influence of aging-related physicochemical modifications on the construction and performance of elastin, a significant protein that imparts elasticity and recoil operate to many connective tissues within the human physique, together with inside elastic arteries. These modifications play a big function in age-related ailments corresponding to diabetes, motivating the significance of finding out elastin’s conduct in ageing arteries.
Led by Dr. Anna Tarakanova, the challenge has been awarded a $3 million R01 grant from the Nationwide Institutes of Well being (NIH) by way of 2028 to additional examine elastin and its function in arterial biomechanics in well being and ageing. Using a pioneering multi-scale method, the analysis integrates superior computational modeling and experimental research to unravel the complicated processes of elastin deterioration from sub-molecular to tissue scales. By doing so, the group goals to realize crucial insights into the mechanisms underlying arterial stiffening and different adjustments to vascular biomechanics throughout ageing and illness.
Dr. Katherine Yanhang Zhang, Professor of Mechanical Engineering at Boston College, is a co-Investigator on the challenge.
“This collaborative challenge has the potential to remodel our elementary understanding of the molecular-scale processes that underlie arterial mechanical adjustments as we age, and drive essentially the most prevalent aging-associated ailments,” stated Tarakanova.
This modern framework not solely deepens our understanding of arterial biomechanics from the smallest scale up, but additionally holds the promise of creating preventative and reparative interventions to many age-related vascular ailments. The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
Researchers from the College of Mechanical, Aerospace and Manufacturing Engineering in UConn’s School of Engineering, pursue groundbreaking analysis to grasp the influence of aging-related physicochemical modifications on the construction and performance of elastin, a significant protein that imparts elasticity and recoil operate to many connective tissues within the human physique, together with inside elastic arteries. These modifications play a big function in age-related ailments corresponding to diabetes, motivating the significance of finding out elastin’s conduct in ageing arteries.
Led by Dr. Anna Tarakanova, the challenge has been awarded a $3 million R01 grant from the Nationwide Institutes of Well being (NIH) by way of 2028 to additional examine elastin and its function in arterial biomechanics in well being and ageing. Using a pioneering multi-scale method, the analysis integrates superior computational modeling and experimental research to unravel the complicated processes of elastin deterioration from sub-molecular to tissue scales. By doing so, the group goals to realize crucial insights into the mechanisms underlying arterial stiffening and different adjustments to vascular biomechanics throughout ageing and illness.
Dr. Katherine Yanhang Zhang, Professor of Mechanical Engineering at Boston College, is a co-Investigator on the challenge.
“This collaborative challenge has the potential to remodel our elementary understanding of the molecular-scale processes that underlie arterial mechanical adjustments as we age, and drive essentially the most prevalent aging-associated ailments,” stated Tarakanova.
This modern framework not solely deepens our understanding of arterial biomechanics from the smallest scale up, but additionally holds the promise of creating preventative and reparative interventions to many age-related vascular ailments. The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
Researchers from the College of Mechanical, Aerospace and Manufacturing Engineering in UConn’s School of Engineering, pursue groundbreaking analysis to grasp the influence of aging-related physicochemical modifications on the construction and performance of elastin, a significant protein that imparts elasticity and recoil operate to many connective tissues within the human physique, together with inside elastic arteries. These modifications play a big function in age-related ailments corresponding to diabetes, motivating the significance of finding out elastin’s conduct in ageing arteries.
Led by Dr. Anna Tarakanova, the challenge has been awarded a $3 million R01 grant from the Nationwide Institutes of Well being (NIH) by way of 2028 to additional examine elastin and its function in arterial biomechanics in well being and ageing. Using a pioneering multi-scale method, the analysis integrates superior computational modeling and experimental research to unravel the complicated processes of elastin deterioration from sub-molecular to tissue scales. By doing so, the group goals to realize crucial insights into the mechanisms underlying arterial stiffening and different adjustments to vascular biomechanics throughout ageing and illness.
Dr. Katherine Yanhang Zhang, Professor of Mechanical Engineering at Boston College, is a co-Investigator on the challenge.
“This collaborative challenge has the potential to remodel our elementary understanding of the molecular-scale processes that underlie arterial mechanical adjustments as we age, and drive essentially the most prevalent aging-associated ailments,” stated Tarakanova.
This modern framework not solely deepens our understanding of arterial biomechanics from the smallest scale up, but additionally holds the promise of creating preventative and reparative interventions to many age-related vascular ailments. The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
Researchers from the College of Mechanical, Aerospace and Manufacturing Engineering in UConn’s School of Engineering, pursue groundbreaking analysis to grasp the influence of aging-related physicochemical modifications on the construction and performance of elastin, a significant protein that imparts elasticity and recoil operate to many connective tissues within the human physique, together with inside elastic arteries. These modifications play a big function in age-related ailments corresponding to diabetes, motivating the significance of finding out elastin’s conduct in ageing arteries.
Led by Dr. Anna Tarakanova, the challenge has been awarded a $3 million R01 grant from the Nationwide Institutes of Well being (NIH) by way of 2028 to additional examine elastin and its function in arterial biomechanics in well being and ageing. Using a pioneering multi-scale method, the analysis integrates superior computational modeling and experimental research to unravel the complicated processes of elastin deterioration from sub-molecular to tissue scales. By doing so, the group goals to realize crucial insights into the mechanisms underlying arterial stiffening and different adjustments to vascular biomechanics throughout ageing and illness.
Dr. Katherine Yanhang Zhang, Professor of Mechanical Engineering at Boston College, is a co-Investigator on the challenge.
“This collaborative challenge has the potential to remodel our elementary understanding of the molecular-scale processes that underlie arterial mechanical adjustments as we age, and drive essentially the most prevalent aging-associated ailments,” stated Tarakanova.
This modern framework not solely deepens our understanding of arterial biomechanics from the smallest scale up, but additionally holds the promise of creating preventative and reparative interventions to many age-related vascular ailments. The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
Researchers from the College of Mechanical, Aerospace and Manufacturing Engineering in UConn’s School of Engineering, pursue groundbreaking analysis to grasp the influence of aging-related physicochemical modifications on the construction and performance of elastin, a significant protein that imparts elasticity and recoil operate to many connective tissues within the human physique, together with inside elastic arteries. These modifications play a big function in age-related ailments corresponding to diabetes, motivating the significance of finding out elastin’s conduct in ageing arteries.
Led by Dr. Anna Tarakanova, the challenge has been awarded a $3 million R01 grant from the Nationwide Institutes of Well being (NIH) by way of 2028 to additional examine elastin and its function in arterial biomechanics in well being and ageing. Using a pioneering multi-scale method, the analysis integrates superior computational modeling and experimental research to unravel the complicated processes of elastin deterioration from sub-molecular to tissue scales. By doing so, the group goals to realize crucial insights into the mechanisms underlying arterial stiffening and different adjustments to vascular biomechanics throughout ageing and illness.
Dr. Katherine Yanhang Zhang, Professor of Mechanical Engineering at Boston College, is a co-Investigator on the challenge.
“This collaborative challenge has the potential to remodel our elementary understanding of the molecular-scale processes that underlie arterial mechanical adjustments as we age, and drive essentially the most prevalent aging-associated ailments,” stated Tarakanova.
This modern framework not solely deepens our understanding of arterial biomechanics from the smallest scale up, but additionally holds the promise of creating preventative and reparative interventions to many age-related vascular ailments. The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
Researchers from the College of Mechanical, Aerospace and Manufacturing Engineering in UConn’s School of Engineering, pursue groundbreaking analysis to grasp the influence of aging-related physicochemical modifications on the construction and performance of elastin, a significant protein that imparts elasticity and recoil operate to many connective tissues within the human physique, together with inside elastic arteries. These modifications play a big function in age-related ailments corresponding to diabetes, motivating the significance of finding out elastin’s conduct in ageing arteries.
Led by Dr. Anna Tarakanova, the challenge has been awarded a $3 million R01 grant from the Nationwide Institutes of Well being (NIH) by way of 2028 to additional examine elastin and its function in arterial biomechanics in well being and ageing. Using a pioneering multi-scale method, the analysis integrates superior computational modeling and experimental research to unravel the complicated processes of elastin deterioration from sub-molecular to tissue scales. By doing so, the group goals to realize crucial insights into the mechanisms underlying arterial stiffening and different adjustments to vascular biomechanics throughout ageing and illness.
Dr. Katherine Yanhang Zhang, Professor of Mechanical Engineering at Boston College, is a co-Investigator on the challenge.
“This collaborative challenge has the potential to remodel our elementary understanding of the molecular-scale processes that underlie arterial mechanical adjustments as we age, and drive essentially the most prevalent aging-associated ailments,” stated Tarakanova.
This modern framework not solely deepens our understanding of arterial biomechanics from the smallest scale up, but additionally holds the promise of creating preventative and reparative interventions to many age-related vascular ailments. The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.
Researchers from the College of Mechanical, Aerospace and Manufacturing Engineering in UConn’s School of Engineering, pursue groundbreaking analysis to grasp the influence of aging-related physicochemical modifications on the construction and performance of elastin, a significant protein that imparts elasticity and recoil operate to many connective tissues within the human physique, together with inside elastic arteries. These modifications play a big function in age-related ailments corresponding to diabetes, motivating the significance of finding out elastin’s conduct in ageing arteries.
Led by Dr. Anna Tarakanova, the challenge has been awarded a $3 million R01 grant from the Nationwide Institutes of Well being (NIH) by way of 2028 to additional examine elastin and its function in arterial biomechanics in well being and ageing. Using a pioneering multi-scale method, the analysis integrates superior computational modeling and experimental research to unravel the complicated processes of elastin deterioration from sub-molecular to tissue scales. By doing so, the group goals to realize crucial insights into the mechanisms underlying arterial stiffening and different adjustments to vascular biomechanics throughout ageing and illness.
Dr. Katherine Yanhang Zhang, Professor of Mechanical Engineering at Boston College, is a co-Investigator on the challenge.
“This collaborative challenge has the potential to remodel our elementary understanding of the molecular-scale processes that underlie arterial mechanical adjustments as we age, and drive essentially the most prevalent aging-associated ailments,” stated Tarakanova.
This modern framework not solely deepens our understanding of arterial biomechanics from the smallest scale up, but additionally holds the promise of creating preventative and reparative interventions to many age-related vascular ailments. The analysis carried out on the UConn School of Engineering is poised to make vital contributions to the sector of biomechanics and enhance human well being outcomes within the course of.