Arthroscopic rotator cuff repair is the gold standard for treatment, but current techniques have shortcomings, especially for larger tears. Single-row repairs often fail to fully restore the footprint, leading to high retear rates. Although triple-row and double-row repairs show promise, concerns regarding retear persist. Biomechanical studies favor triple-row repair for better coverage and pressure distribution. Techniques such as linked double-row and double-pulley methods enhance strength. Secondary cuff failures near the musculotendinous junction are commonly caused by stress concentration. To address these challenges, novel methods have employed linked, knotless, and bridging constructs. Our approach, the double pulley-triple row, aims to minimize retears, especially at the musculotendinous junction, and provides uniform pressure distribution, which is particularly beneficial for large tears. The surgical steps involve standard arthroscopic procedures with specific instruments. Despite these challenges, our method combines proven techniques for optimized outcomes and promising improved results in rotator cuff repair.

Rotator cuff tears are common shoulder injuries that often necessitate surgical intervention, particularly when nonoperative treatments fail. Arthroscopic rotator cuff repair is the current gold standard; however, challenges, such as high retear rates, especially in large tears, persist. Traditional techniques, such as single-row and double-row repairs, have limitations in fully restoring the anatomical footprint and ensuring optimal healing. This review examines the novel double pulley-triple row technique, which aims to overcome these limitations by enhancing the footprint contact area, load distribution, and tendon healing. By evaluating the double pulley-triple row method in comparison to established techniques, this study explores the potential advantages, limitations, and future directions of rotator cuff repair.

Arthroscopic rotator cuff repair is the gold standard for treatment, but current techniques have shortcomings, especially for larger tears. Single-row repairs often fail to fully restore the footprint, leading to high retear rates. Although triple-row and double-row repairs show promise, concerns regarding retear persist. Biomechanical studies favor triple-row repair for better coverage and pressure distribution. Techniques such as linked double-row and double-pulley methods enhance strength. Secondary cuff failures near the musculotendinous junction are commonly caused by stress concentration. To address these challenges, novel methods have employed linked, knotless, and bridging constructs. Our approach, the double pulley-triple row, aims to minimize retears, especially at the musculotendinous junction, and provides uniform pressure distribution, which is particularly beneficial for large tears. The surgical steps involve standard arthroscopic procedures with specific instruments. Despite these challenges, our method combines proven techniques for optimized outcomes and promising improved results in rotator cuff repair.

Rotator cuff tears are common shoulder injuries that often necessitate surgical intervention, particularly when nonoperative treatments fail. Arthroscopic rotator cuff repair is the current gold standard; however, challenges, such as high retear rates, especially in large tears, persist. Traditional techniques, such as single-row and double-row repairs, have limitations in fully restoring the anatomical footprint and ensuring optimal healing. This review examines the novel double pulley-triple row technique, which aims to overcome these limitations by enhancing the footprint contact area, load distribution, and tendon healing. By evaluating the double pulley-triple row method in comparison to established techniques, this study explores the potential advantages, limitations, and future directions of rotator cuff repair.

Arthroscopic rotator cuff repair is the gold standard for treatment, but current techniques have shortcomings, especially for larger tears. Single-row repairs often fail to fully restore the footprint, leading to high retear rates. Although triple-row and double-row repairs show promise, concerns regarding retear persist. Biomechanical studies favor triple-row repair for better coverage and pressure distribution. Techniques such as linked double-row and double-pulley methods enhance strength. Secondary cuff failures near the musculotendinous junction are commonly caused by stress concentration. To address these challenges, novel methods have employed linked, knotless, and bridging constructs. Our approach, the double pulley-triple row, aims to minimize retears, especially at the musculotendinous junction, and provides uniform pressure distribution, which is particularly beneficial for large tears. The surgical steps involve standard arthroscopic procedures with specific instruments. Despite these challenges, our method combines proven techniques for optimized outcomes and promising improved results in rotator cuff repair.

Rotator cuff tears are common shoulder injuries that often necessitate surgical intervention, particularly when nonoperative treatments fail. Arthroscopic rotator cuff repair is the current gold standard; however, challenges, such as high retear rates, especially in large tears, persist. Traditional techniques, such as single-row and double-row repairs, have limitations in fully restoring the anatomical footprint and ensuring optimal healing. This review examines the novel double pulley-triple row technique, which aims to overcome these limitations by enhancing the footprint contact area, load distribution, and tendon healing. By evaluating the double pulley-triple row method in comparison to established techniques, this study explores the potential advantages, limitations, and future directions of rotator cuff repair.

Arthroscopic rotator cuff repair is the gold standard for treatment, but current techniques have shortcomings, especially for larger tears. Single-row repairs often fail to fully restore the footprint, leading to high retear rates. Although triple-row and double-row repairs show promise, concerns regarding retear persist. Biomechanical studies favor triple-row repair for better coverage and pressure distribution. Techniques such as linked double-row and double-pulley methods enhance strength. Secondary cuff failures near the musculotendinous junction are commonly caused by stress concentration. To address these challenges, novel methods have employed linked, knotless, and bridging constructs. Our approach, the double pulley-triple row, aims to minimize retears, especially at the musculotendinous junction, and provides uniform pressure distribution, which is particularly beneficial for large tears. The surgical steps involve standard arthroscopic procedures with specific instruments. Despite these challenges, our method combines proven techniques for optimized outcomes and promising improved results in rotator cuff repair.

Rotator cuff tears are common shoulder injuries that often necessitate surgical intervention, particularly when nonoperative treatments fail. Arthroscopic rotator cuff repair is the current gold standard; however, challenges, such as high retear rates, especially in large tears, persist. Traditional techniques, such as single-row and double-row repairs, have limitations in fully restoring the anatomical footprint and ensuring optimal healing. This review examines the novel double pulley-triple row technique, which aims to overcome these limitations by enhancing the footprint contact area, load distribution, and tendon healing. By evaluating the double pulley-triple row method in comparison to established techniques, this study explores the potential advantages, limitations, and future directions of rotator cuff repair.

Background: Degenerative tendinopathy, a condition causing movement restriction due to high pain, highly impacts productivity and quality of life. The healing process is a complex phenomenon and involves a series of intra-cellular and inter-cellular processes. Proliferation and differentiation of the tenocyte is a major and essential process to heal degenerative tendinopathy. The recent development in microRNA (miRNA)-mediated reprogramming of the cellular function through specific pathways opened door for the development of new regenerative therapeutics. Based on information about gene expression and regulation of tendon injury and healing, we attempted to evaluate the combinatorial effect of selected miRNAs for better healing of degenerative tendinopathy. Methods: The present study was designed to evaluate the combinatorial effect of two miRNAs (has-miR-140 and has-miR-135) in the healing process of the tendon. Publicly available information/data were retrieved from appropriate platforms such as PubMed.Only molecular data, directly associated with tendinopathies, including genes/proteins and miRNAs, were used in this study. The miRNAs involved in tendinopathy were analyzed by a Bioinformatics tools (e.g., TargetScan, miRDB, and the RNA22v2). Interactive involvement of the miRNAs with key proteins involved in tendinopathy was predicted by the Insilco approach. Results: Based on information available in the public domain, tendon healing-associated miRNAs were predicted to explore their therapeutic potentials. Based on computation analysis, focusing on the potential regulatory effect on tendon healing, the miR-135 and miR-140 were selected for this study. These miRNAs were found as key players in tendon healing through Rho-associated coiled-coil containing protein kinase 1 (ROCK1), IGF-1/PI3K/Akt, PIN, and Wnt signaling pathways. It was also predicted that these miRNAs may reprogram the cells to induce proliferation and differentiation activity. Many miRNAs are likely to regulate genes important for the tendinopathy healing process, and the result of this study allows an approach for miRNA-mediated regeneration of the tenocyte for tendon healing. Based on computational analysis, the role of these miRNAs in different pathways was established, and the results provided insights into the combinatorial approach of miRNA-mediated cell reprogramming. Conclusions In this study, the association between miRNAs and the disease was evaluated to correlate the tendinopathy genes and the relevant role of different miRNAs in their regulation. Through this study, it was established that the synergistic effect of more than one miRNA on directed reprogramming of the cell could be helpful in the regeneration of damaged tissue. It is anticipated that this study will be helpful for the design of miRNA cocktails for the orchestration of cellular reprogramming events.

Artificial intelligence (AI) has rapidly transformed various aspects of life, and the launch of the chatbot “ChatGPT” by OpenAI in November 2022 has garnered significant attention and user appreciation. ChatGPT utilizes natural language processing based on a ”generative pre-trained transfer” (GPT) model, specifically the transformer architecture, to generate human-like responses to a wide range of questions and topics. Equipped with approximately 57 billion words and 175 billion parameters from online data, ChatGPT has potential applications in medicine and orthopedics. One of its key strengths is its personalized, easy-to-understand, and adaptive response, which allows it to learn continuously through user interaction. This article discusses how AI, especially ChatGPT, presents numerous opportunities in orthopedics, ranging from preoperative planning and surgical techniques to patient education and medical support. Although ChatGPT’s user-friendly responses and adaptive capabilities are laudable, its limitations, including biased responses and ethical concerns, necessitate its cautious and responsible use. Surgeons and healthcare providers should leverage the strengths of the ChatGPT while recognizing its current limitations and verifying critical information through independent research and expert opinions. As AI technology continues to evolve, ChatGPT may become a valuable tool in orthopedic education and patient care, leading to improved outcomes and efficiency in healthcare delivery. The integration of AI into orthopedics offers substantial benefits but requires careful consideration and continuous improvement.