Computer vision detects inflammatory arthritis in standardized smartphone photographs in an Indian patient cohort

doi:10.3389/fmed.2023.1280462

. 2023 Nov 9:10:1280462.

doi: 10.3389/fmed.2023.1280462. eCollection 2023.

Computer vision detects inflammatory arthritis in standardized smartphone photographs in an Indian patient cohort

Sanat Phatak¹, Somashree Chakraborty², Pranay Goel²

Affiliations

PMID: 38020147
PMCID: PMC10666644
DOI: 10.3389/fmed.2023.1280462

Computer vision detects inflammatory arthritis in standardized smartphone photographs in an Indian patient cohort

Sanat Phatak et al. Front Med (Lausanne). 2023.

. 2023 Nov 9:10:1280462.

doi: 10.3389/fmed.2023.1280462. eCollection 2023.

Authors

Sanat Phatak¹, Somashree Chakraborty², Pranay Goel²

Affiliations

¹ KEM Hospital Research Centre, Pune, India.
² Indian Institute of Science, Education and Research, Pune, India.

PMID: 38020147
PMCID: PMC10666644
DOI: 10.3389/fmed.2023.1280462

Abstract

Introduction: Computer vision extracts meaning from pixelated images and holds promise in automating various clinical tasks. Convolutional neural networks (CNNs), a deep learning network used therein, have shown promise in analyzing X-ray images and joint photographs. We studied the performance of a CNN on standardized smartphone photographs in detecting inflammation in three hand joints and compared it to a rheumatologist's diagnosis.

Methods: We enrolled 100 consecutive patients with inflammatory arthritis with an onset period of less than 2 years, excluding those with deformities. Each patient was examined by a rheumatologist, and the presence of synovitis in each joint was recorded. Hand photographs were taken in a standardized manner, anonymized, and cropped to include joints of interest. A ResNet-101 backbone modified for two class outputs (inflamed or not) was used for training. We also tested a hue-augmented dataset. We reported accuracy, sensitivity, and specificity for three joints: wrist, index finger proximal interphalangeal (IFPIP), and middle finger proximal interphalangeal (MFPIP), taking the rheumatologist's opinion as the gold standard.

Results: The cohort consisted of 100 individuals, of which 22 of them were men, with a mean age of 49.7 (SD 12.9) years. The majority of the cohort (n = 68, 68%) had rheumatoid arthritis. The wrist (125/200, 62.5%), MFPIP (94/200, 47%), and IFPIP (83/200, 41.5%) were the three most commonly inflamed joints. The CNN achieved the highest accuracy, sensitivity, and specificity in detecting synovitis in the MFPIP (83, 77, and 88%, respectively), followed by the IFPIP (74, 74, and 75%, respectively) and the wrist (62, 90, and 21%, respectively).

Discussion: We have demonstrated that computer vision was able to detect inflammation in three joints of the hand with reasonable accuracy on standardized photographs despite a small dataset. Feature engineering was not required, and the CNN worked despite a diversity in clinical diagnosis. Larger datasets are likely to improve accuracy and help explain the basis of classification. These data suggest a potential use of computer vision in screening and follow-up of inflammatory arthritis.

Keywords: artificial intelligence; computer vision; digital health; inflammatory arthritis; screening.

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Conflict of interest statement

SP and PG are coinventors on a provisional patent application at the Indian Patent Office (not granted) that includes some of the material used in this manuscript. The remaining author declares that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Figures

**Figure 1**
Schema of photograph processing and outputs from the convolutional neural network.

**Figure 2**
Hue augmentation for skin tone: representative hue-augmented pairs with random hue variation between 6 and 34 degrees. **(A)** Index finger proximal interphalangeal joints, **(B)** middle finger interphalangeal joints, and **(C)** wrist joints. Note the henna on some images did not change the results.

**Figure 3**
Representative image showing the performance of Convolutional Neural Network (CNN) for three joints in contingency tables. Accuracy denotes the overall probability that a patient is correctly classified. MFPIP, middle finger proximal interphalangeal joint; IFPIP, index finger proximal interphalangeal joint; PPV, positive predictive value; NPV, negative predictive value.

**Figure 4**
**(A)** Representative training graph for naive (no hue augmentation) middle finger PIP. On this run, accuracy = 83%, sensitivity = 77%, and specificity = 88%. **(B)** Representative training graph for naive (with hue augmentation) MFPIP. On this run, accuracy = 81%, sensitivity = 65%, and specificity = 92%.

See this image and copyright information in PMC

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Computer vision detects inflammatory arthritis in standardized smartphone photographs in an Indian patient cohort

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Computer vision detects inflammatory arthritis in standardized smartphone photographs in an Indian patient cohort

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