A Novel Instrument Holder to Improve Operative Efficiency in Endoscopic Laryngeal and Airway Surgery.

OBJECTIVE: Receiving instruments from surgical technicians during endoscopic laryngeal and airway microsurgery (ELAM) has challenges including repeated, expeditious handling of delicate instruments and passing them to the surgeon's hand opposite of where the surgical assistant is standing. Optimizing this interaction may reduce surgical errors and improve operative efficiency. METHODS: A proprietary ELAM instrument holder was attached to both sides of the operating room bed. The device consisted of an articulating arm with custom silicone inserts mounted on a tray (storing up to three endoscopic instruments). ELAM cases were randomized to be performed either with (device) or without the holder (control). Using custom software, instrument pass time (IPT), instrument drop rate (IDR), and communication errors (eg handing incorrect instruments) were manually recorded. Qualitative use metrics relating to overall device satisfaction were also obtained. RESULTS: Data were collected from 25 device and 23 control cases among three different laryngologists. Average IPT was nearly three times quicker for the device (0.80 s, n = 1175 passes) compared with controls (2.09 s, n = 1208 passes) [p < 0.001]. IPT interquartile range was five times higher for control (1.65 s) versus device cases (0.42 s). IDR was not significantly different [p = 0.48]; however, device cases had significantly lower communication errors compared to control cases [p = 0.01]. Surgeons and surgical assistants were similarly satisfied with the device on a 5-point Likert scale (mean: 4.2/5, standard deviation: 0.92). CONCLUSION: The proposed endoscopic instrument holder can improve ELAM operative workflow by reducing instrument passing time and variability without increasing IDR. LEVEL OF EVIDENCE: 2 Laryngoscope, 133:3492-3498, 2023.

Microstructural Measures of the Inferior Longitudinal Fasciculus Predict Later Cognitive and Language Development in Infants Born With Extremely Low Birth Weight.

OBJECTIVE: Extremely preterm children are at high risk for adverse neurodevelopmental outcomes. Identifying predictors of discrete developmental outcomes early in life would allow for targeted neuroprotective therapies when neuroplasticity is at its peak. Our goal was to examine whether diffusion magnetic resonance imaging (MRI) metrics of the inferior longitudinal and uncinate fasciculi early in life could predict later cognitive and language outcomes. STUDY DESIGN: In this pilot study, 43 extremely low-birth-weight preterm infants were scanned using diffusion MRI at term-equivalent age. White matter tracts were assessed via diffusion tensor imaging metrics of fractional anisotropy and mean diffusivity. The Language and Cognitive subscale scores of the Bayley Scales of Infant & Toddler Development-III at 18-22 months corrected age were our outcomes of interest. Multiple linear regression models were created to assess diffusion metrics of the inferior longitudinal and uncinate fasciculi as predictors of Bayley scores. We controlled for brain injury score on structural MRI, maternal education, birth weight, and age at MRI scan. RESULTS: Of the 43 infants, 36 infants had high-quality diffusion tensor imaging and returned for developmental testing. The fractional anisotropy of the inferior longitudinal fasciculus was associated with Bayley-III scores in univariate analyses and was an independent predictor of Bayley-III cognitive and language development over and above known predictors in multivariable analyses. CONCLUSIONS: Incorporating new biomarkers such as the fractional anisotropy of the inferior longitudinal fasciculus with structural MRI findings could enhance accuracy of neurodevelopment predictive models. Additional research is needed to validate our findings in a larger cohort.