Assessing Diabetic Foot Ulcer Microcirculation With High-frequency Contrast Enhanced Ultrasound

Diabetes Mellitus

Diabetic Foot Ulcers, High-Frequency Contrast-Enhanced Ultrasound, Microcirculation blood supply assessment, Amputation, Limb salvage

The objective of this observational study is to investigate and validate the utility of high-frame-rate ultrasound imaging technology for dynamic observation of the blood perfusion process at the site of ulcer wounds in real-time, focusing on patients with Diabetic Foot Ulcers (DFU). The primary research questions it seeks to address are as follows: * What are the dynamic characteristics of vascular dynamics at the site of ulcer wounds in patients with DFU under high-frame-rate ultrasound imaging? * Is High-Frequency Contrast-Enhanced Ultrasound (H-CEUS) technology feasible for effectively visualizing the microcirculation of ulcer wounds in patients with DFU? Participants will Undergo high-frame-rate ultrasound imaging for real-time observation of blood perfusion dynamics at the site of ulcer wounds. Researchers will compare ulcerated sites with normal sites to see whether the use of High-Frequency Contrast-Enhanced Ultrasound (H-CEUS) has any discernible impact on the visualization of microcirculation in ulcer wounds.

1. Investigate H-CEUS abnormalities in microcirculation at DFU ulcer sites Conduct H-CEUS detection of blood vessels at ulcer sites for each participant. Qualitatively and quantitatively analyze differences in contrast enhancement time, intensity, uniformity, direction, and vessel morphology among different patient groups based on time-intensity curves. Compare H-CEUS indicators between DFU ulcer and normal sites, followed by single-factor and multi-factor logistic regression analysis to identify meaningful imaging indicators for diagnosing DFU and construct an H-CEUS score. 2. Correlate H-CEUS score with traditional measurement indicators Perform color Doppler ultrasound (CDU), laser Doppler perfusion monitoring (LDPM), and transcutaneous partial pressure of oxygen (TcPO2) measurements at ulcer sites for participants. Analyze the correlation between H-CEUS score and the aforementioned five traditional microcirculation assessment methods. This analysis aims to determine if H-CEUS effectively reflects the degree of ischemia in DFU patients' ulcerated limbs, providing a new, non-invasive assessment tool to assist physicians in accurately assessing ulcer severity and tissue damage, facilitating the formulation of individualized and effective treatment plans. 3. Construct and evaluate the limb salvage predictive model using H-CEUS Conduct a retrospective analysis of clinical data from hospitalized DFU patients, categorizing them into limb salvage and amputation groups. Compare baseline data, biochemical indicators, and data based on H-CEUS scores between the two groups. Utilize single-factor and multi-factor logistic regression analysis to identify amputation-related risk factors. Subsequently, employ a random forest algorithm to construct a model based on H-CEUS data to predict limb salvage in DFU patients. To further validate the accuracy and clinical utility of this predictive model, nomogram charts and decision curve analysis (DCA) will be created.

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