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Blood Circulation Disorder clinical trials

View clinical trials related to Blood Circulation Disorder.

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NCT ID: NCT05469282 Completed - Clinical trials for Deep Vein Thrombosis

CEFID-I (CEra Flow Improves DVT-1)

Start date: August 22, 2022
Phase: N/A
Study type: Interventional

The study is a single center clinical trial to evaluate the efficacy and safety of blood circulation improvement using an investigational medical device, which is a product on the market and it's name is Ceragem Master V6, for the risk group of Deep Vein Thrombosis (DVT) and the ordinary person. The study compares before and after the application by one time application.

NCT ID: NCT04879875 Completed - Ischemia Clinical Trials

New Method for Real-time Detection of Tissue Ischemia (ISCALERT)

ISCALERT
Start date: September 1, 2021
Phase: N/A
Study type: Interventional

This is a prospective, single arm, open, single centre clinical investigation designed to examine the feasibility and safety of the IscAlertâ„¢ device in patients scheduled for limb (arm/leg) surgery with tourniquet. IscAlert is measuring CO2 in muscular and subcutaneous tissue. IscAlert is inserted into normal muscle and subcutaneous tissue in ischemic (operated limb with a tourniquet) and non-ischemic limb (non-operated limb).After the tourniquet is inflated, ischemia develops in the muscles and subcutaneous tissue. This will result in an increase in CO2, which will be detected by the sensors on the operated extremity, while the sensors on the non-operated will show normal values. After releasing the tourniquet cuff, the muscle will be reperfused and the CO2 level is expected to decrease into normal levels. 50 number of patients will be enrolled to undergo the procedures. The IscAlert will be removed from the patient before the patient is discharged from the operating room, but in 25 of the patients, IscAlertâ„¢ will be inserted for 72 hours in the operated extremity after the end of surgery. After this, the sensors are removed. 250 Devices is planned to be used in this clinical study.

NCT ID: NCT04396288 Completed - Clinical trials for Bone Diseases, Metabolic

Ultrasound Imaging-based Measurement of Intra-osseous Vascular Response

Start date: September 14, 2021
Phase: N/A
Study type: Interventional

Blood circulation within bone is thought to have a key role in bone growth, in fracture healing and in the development of bone diseases like osteoporosis. Current medical imaging techniques such as conventional ultrasonography fail to detect blood circulation within bone. The investigators propose to develop a new type of ultrasonography called intraosseous functional ultrasonography that will enable the detection and the characterization of blood circulation in solid bone tissue, marrow and soft tissues surrounding bone (muscle for instance). Because most soft tissues are essentially made of water, the speed of sound in soft tissues is close to that in water and it varies only a little between different types of soft tissues. For this reason, clinical ultrasound scanners used for ultrasonography assume that the speed of sound in the human body is the same for all types of soft tissues. This assumption is reasonable in soft tissues, but it does not hold in bone because solid bone tissue is much stiffer than soft tissues. Seismologists have extensive experience in producing images of the structure of the Earth based on the analysis of elastic waves which follow the same laws of Physics as ultrasound waves. The subsurface of the Earth contains layers of solid materials and liquids, consequently it is very similar to a region of the human body containing bone and soft tissues. Therefore the investigators will first work on the adaption of time-tested seismic imaging methods to make ultrasonography of bone possible. Once a correct image of bone is obtained, the investigators will use an ultrasound scanner dedicated to research to repeat this image hundreds of times per second, very much like a slow motion video. Because blood is moving while bone is still, the intensity in the image is being slightly changed where blood is moving. Thus the analysis of these changes makes it possible to detect and characterize blood flow within bone. In this way the investigators expect to be able to detect blood flowing with a speed as low as a few millimeters per second. Finally the sensitivity of the technique to detect and characterize blood circulation in bone will be evaluated in patients at the hospital and in healthy volunteers. The success of this work will help gaining knowledge on the role of blood circulation within bone. In the long term, it may help in the diagnosis of bone diseases.