Patellar tendinopathy (PT) is a common knee disorder, particularly among elite athletes, with a reported prevalence of approximately 14.2%. Athletes affected by PT may experience persistent pain, functional impairment, reduced quality of life, decreased physical performance, and even premature career termination. Diagnosing PT remains challenging due to the absence of a gold standard diagnostic method. Although imaging techniques such as ultrasonography (US) and magnetic resonance imaging (MRI) can aid in confirming the diagnosis and assessing severity, MRI is costly and less accessible, and US shows poor correlation with clinical symptoms. Consequently, diagnosis largely relies on clinical examination and medical history. Infrared thermography (IT) has emerged as a potential alternative imaging technique, offering a low-cost, reliable, and non-invasive method to detect thermal asymmetries indicative of underlying pathologies. Technological advancements have enhanced the precision of IT, reducing the thermal asymmetry threshold from 2-3 ºC in the 1970s to 0.5 ºC in current knee assessments. First-order statistics, such as mean gray intensity, and second-order features based on the gray-level co-occurrence matrix (GLCM), have been extensively used in medical image analysis, including IT, to quantify structural and textural characteristics. The size of the region of interest (ROI) is also a critical factor in thermal and texture analyses, as it can influence sensitivity and diagnostic accuracy. Given these considerations, the objectives of this study were: (1) to evaluate differences in thermal and GLCM-based textural features between athletes with PT and healthy controls; (2) to compare the diagnostic performance of IT and GLCM features applied to thermographic images; and (3) to identify the most appropriate ROI size for optimal characterization of PT using both thermal and textural analysis.
Study Type
OBSERVATIONAL
Enrollment
54
The IT images were recorded with an OPTRIS PI 450 IRT camera coupled to Optris PI Connect Software (Germany). The IRT camera has a Noise Equivalent Temperature Difference \<40 mK with 38º x 29º FOV, a wide range of temperature from -20°C to +100°C, spectrum range of 7.5-13 μm, focal plane array sensor size of 382 × 288 pixels, emissivity set at 0.98 and a measurement uncertainty of ± 2% of the overall temperature reading. The size of the capture frame will be 55.4 × 40.63 cm (1.5 mm/px).
Ceu Cardenal Herrera University
Elche, Alicante, Spain
Textural analysis based on the Gray-Level Co-occurrence Matrix (GLCM)
GLCM relies on the angular relationship between neighboring pixels and the distance between them. relies on the angular relationship between neighboring pixels and the distance between them.
Time frame: baseline
Energy or angular second moment (ASM)
ASM Measures the uniformity or regularity in the distribution of image values. Higher values indicate greater uniformity in the image.
Time frame: baseline
Homogeneity or inverse difference moment (IDM)
IDM reflects the homogeneity of image composition, associated with pixel pairs. Homogeneous images with minimal variations produce high IDM values
Time frame: baseline
Contrast (CON)
CON represents the degree of local variations in gray levels within the image.If the variation increases, the contrast increases.
Time frame: baseline
Textural correlation (TCOR)
TCOR expresses linear dependencies between gray levels in the image. Regions with similar gray levels tend to exhibit higher values.
Time frame: baseline
Entropy (ENT)
Indicates the level of disorder within the image. Homogeneous images result in lower entropy values
Time frame: baseline
Age (years)
Time frame: baseline
Sex
Time frame: baseline
Body Mass index (BMI)
kg/m²
Time frame: baseline
time of evolution (months)
Time frame: baseline
This platform is for informational purposes only and does not constitute medical advice. Always consult a qualified healthcare professional.