Public release date: 10-Jun-2012 [ | E-mail | Share ] <\/p>\n
Contact: Andreas Zumbuehl andreas.zumbuehl@unige.ch<\/a> 41-223-796-719 Universit de Genve<\/p>\n In Switzerland, more than 20,000 people (37% of all deaths) die of cardiovascular disease caused by atherosclerosis each year. Treatment options are currently available to people who suffer from the disease but no drug can target solely the diseased areas, often leading to generalized side effects. Intravenous injection of a vasodilator (a substance that dilates blood vessels), such as nitroglycerin, dilates both the diseased vessels and the rest of our arteries. Blood pressure can thus drop, which would limit the desired increased blood flow generated by vasodilatation of diseased vessels and needed for example during a heart attack. <\/p>\n In order to increase the effectiveness of treatments against atherosclerosis and to reduce side effects, a team of researchers from UNIGE, HUG and the University of Basel have developed nanocontainers having the ability to release their vasodilator content exclusively to diseased areas. <\/p>\n Nanotechnology in medicine <\/p>\n Though no biomarker specific to atherosclerosis has been identified, there is a physical phenomenon inherent to stenosis (the narrowing of blood vessels) known as shear stress. This force results from fluctuations in blood flow induced by the narrowing of the artery and runs parallel to the flow of blood. It is by making use of this phenomenon that the team of researchers has developed a veritable time bomb, a nanocontainer which, under pressure from the shear stress in stenosed arteries, will release its vasodilator contents. <\/p>\n By rearranging the structure of certain molecules (phospholipids) in classic nanocontainers such as liposome, scientists were able to give them a lenticular shape as opposed to the normal spherical shape. In the form of a lens, the nanocontainer then moves through the healthy arteries without breaking. This new nanocontainer is perfectly stable, except when subjected to the shear stress of stenosed arteries. And that's exactly the intention of this technological advance. The vasodilator content is distributed only to the stenotic arteries, significantly increasing the efficacy of the treatment and reducing side effects. In brief, we exploited a previously unexplored aspect of an existing technology. This research offers new perspectives in the treatment of patients with cardiovascular disease, explains Andreas Zumbuehl from the Department of Organic Chemistry at UNIGE. <\/p>\n Nanomedicine is a discipline stemming from general nanoscience but which orients itself towards medical research. The interdisciplinary collaboration between chemistry, physics, basic science and clinical medicine in a highly technical environment could lead to a new era of research, states Till Saxer of the Cardiology and General Internal Medicine Departments at HUG. <\/p>\n The nano component is present in all disciplines, but the most interesting aspect of nanomedicine is its overview allowing the development of clinical products that integrate this global medical point of view from the earliest onset of research projects, states Bert Mller, Director of the Biomaterials Science Centre (BMC) at Basel. <\/p>\n When chemistry gets involved <\/p>\n<\/p>\n Original post: Public release date: 10-Jun-2012 [ | E-mail | Share ] Contact: Andreas Zumbuehl andreas.zumbuehl@unige.ch<\/a> 41-223-796-719 Universit de Genve In Switzerland, more than 20,000 people (37% of all deaths) die of cardiovascular disease caused by atherosclerosis each year. Treatment options are currently available to people who suffer from the disease but no drug can target solely the diseased areas, often leading to generalized side effects Continue reading
\nResearchers develop a 'time bomb' to fight cardiovascular disease<\/a><\/p>\n","protected":false},"excerpt":{"rendered":"