Upper limb infections: A comparison between diabetic and non-diabetic patients

Factors Affecting 30-Day Outcomes in Patients Undergoing Nontraumatic Upper Extremity Amputation: A Retrospective Descriptive Longitudinal Study

BACKGROUND

Current literature concerning upper extremity amputations (UEAs) is very sparse. In this study, we conducted the first multicenter retrospective analysis aiming to identify risk factors associated with unfavorable outcomes in patients undergoing nontraumatic UEAs.

METHODS

A retrospective cohort study was conducted using the National Surgical Quality Improvement Program database. Adult patients who underwent nontraumatic UEAs between 2005 and 2021 were divided into two cohorts based on whether they experienced 30-day major morbidity (MM). Thereafter, multivariable binary logistic regression analysis was used to identify risk factors of MM.

RESULTS

From a total of 2984 cases, MM was observed in 8.7% of patients. Factors associated with MM included American Society of Anesthesiologists classes 3 (odds ratio [OR], 2.974 [1.862 to 4.748]) and 4 (OR, 4.736 [2.857 to 7.848]), being underweight (OR, 2.370 [1.251 to 4.491]), and suffering from insulin-dependent diabetes (OR, 1.390 [1.018 to 1.898]). In addition, an infectious surgical indication was associated with an increased risk of MM compared with having a benign (OR, 0.648 [0.488 to 0.682]) or malignant (OR, 0.205 [0.091 to 0.462]) indication. Moreover, patients undergoing shoulder amputations were at an increased risk of MM compared with those undergoing amputations of the forearm/wrist (OR, 0.243 [0.072 to 0.819]) and hands/fingers (OR, 0.286 [0.095 to 0.861]).

CONCLUSION

The risk factors identified for MM after nontraumatic UEAs should guide surgeons toward appropriately identifying high-risk patients and adequately counseling them preoperatively.

Neuromuscular implants: Interfacing with skeletal muscle for improved clinical translation of prosthetic limbs

After an amputation, advanced prosthetic limbs can be used to interface with the nervous system and restore motor function. Despite numerous breakthroughs in the field, many of the recent research advancements have not been widely integrated into clinical practice. This review highlights recent innovations in neuromuscular implants-specifically those that interface with skeletal muscle-which could improve the clinical translation of prosthetic technologies. Skeletal muscle provides a physiologic gateway to harness and amplify signals from the nervous system. Recent surgical advancements in muscle reinnervation surgeries leverage the "bio-amplification" capabilities of muscle, enabling more intuitive control over a greater number of degrees of freedom in prosthetic limbs than previously achieved. We anticipate that state-of-the-art implantable neuromuscular interfaces that integrate well with skeletal muscle and novel surgical interventions will provide a long-term solution for controlling advanced prostheses. Flexible electrodes are expected to play a crucial role in reducing foreign body responses and improving the longevity of the interface. Additionally, innovations in device miniaturization and ongoing exploration of shape memory polymers could simplify surgical procedures for implanting such interfaces. Once implanted, wireless strategies for powering and transferring data from the interface can eliminate bulky external wires, reduce infection risk, and enhance day-to-day usability. By outlining the current limitations of neuromuscular interfaces along with potential future directions, this review aims to guide continued research efforts and future collaborations between engineers and specialists in the field of neuromuscular and musculoskeletal medicine.