Security of 3D-printed polylactide acid piece sterilization in the operating room: a sterility test

Three-dimensional (3D) imaging technology has become a popular clinical technology for surgical planning and simulation in rhinoplasty. This technology offers the opportunity to translate a simulated 3D image into a surgical plan in the operating room in a quantitative manner. Herein, we describe a technique for creating patient-specific 3D-printed rhinoplasty marking templates from preoperative 3D imaging. Five adult patients presenting for primary rhinoplasty were recruited as subjects. 3D photographs were captured of each patient, and goals of surgery were digitally simulated based on patient preference. Simulated and baseline digital renderings were exported to a third-party 3D printing company. 3D-printed plastic molds were created to precisely fit the patient’s preoperative nose when overlaid on the dorsum. Molds included windows through the lateral walls corresponding to the preoperative simulation whereby the patient’s desired dorsal height and contour was marked on the skin immediately prior to surgery. 3D image capture, digital rendering, and goals of surgery simulations were created using standard office-based 3D imaging equipment and added an additional 10 minutes the standard preoperative rhinoplasty consultation. Turnaround time was 5 days and cost was $100 per patient. The senior author found the patient-specific marking templates to effectively transfer the patient’s desired dorsal height and contour onto the patient in the form of skin markings. The technique described herein aids quantitative translation of patient goals in dorsal reduction rhinoplasty into the operating room and onto the patient in the form of preoperative marking. The workflow is fast, cost-effective, uses standard office-based technology, and requires little technological expertise.

Download Full-text

3D-printed cranial models simulating operative field depth for microvascular training in neurosurgery

Surgical Neurology International ◽

10.25259/sni_849_2020 ◽

2021 ◽

Vol 12 ◽

pp. 213

Author(s):

Vadim Byvaltsev ◽

Roman Polkin ◽

Dmitry Bereznyak ◽

Morgan B. Giers ◽

Phillip A. Hernandez ◽

...

Keyword(s):

Operating Room ◽

3D Models ◽

Surgical Approaches ◽

Hand Position ◽

Rigid Fixation ◽

Training Models ◽

Operating Field ◽

Skull Model ◽

3D Printed ◽

Aortic Anastomosis

Background: The skills required for neurosurgical operations using microsurgical techniques in a deep operating field are difficult to master in the operating room without risk to patients. Although there are many microsurgical training models, most do not use a skull model to simulate a deep field. To solve this problem, 3D models were created to provide increased training in the laboratory before the operating room, improving patient safety. Methods: A patient’s head was scanned using computed tomography. The data were reconstructed and converted into a standard 3D printing file. The skull was printed with several openings to simulate common surgical approaches. These models were then used to create a deep operating field while practicing on a chicken thigh (femoral artery anastomosis) and on a rat (abdominal aortic anastomosis). Results: The advantages of practicing with the 3D printed models were clearly demonstrated by our trainees, including appropriate hand position on the skull, becoming comfortable with the depth of the anastomosis, and simulating proper skull angle and rigid fixation. One limitation is the absence of intracranial structures, which is being explored in future work. Conclusion: This neurosurgical model can improve microsurgery training by recapitulating the depth of a real operating field. Improved training can lead to increased accuracy and efficiency of surgical procedures, thereby minimizing the risk to patients.

Download Full-text

STERILIZATION OF BEDSIDE 3D-PRINTED DEVICES FOR USE IN THE OPERATING ROOM

Annals of 3D Printed Medicine ◽

10.1016/j.stlm.2022.100045 ◽

2022 ◽

pp. 100045

Author(s):

Dr. Jeremy Wiseman ◽

Dr. Thampi Rawther ◽

Dr. Marc Langbart ◽

Dr. Michael Kernohan ◽

Dr. Quan Ngo

Keyword(s):

Operating Room ◽

3D Printed

Download Full-text

Heart and Lung Sound Measurement Using an Esophageal Stethoscope with Adaptive Noise Cancellation

Sensors ◽

10.3390/s21206757 ◽

2021 ◽

Vol 21 (20) ◽

pp. 6757

Author(s):

Nourelhuda Mohamed ◽

Hyun-Seok Kim ◽

Kyu-Min Kang ◽

Manal Mohamed ◽

Sung-Hoon Kim ◽

...

Keyword(s):

Operating Room ◽

Coming Out ◽

Background Noise ◽

Lung Sounds ◽

Adaptive Noise Cancellation ◽

Lung Sound ◽

Cardiorespiratory System ◽

Software Application ◽

3D Printed ◽

Adaptive Noise

In surgeries where general anesthesia is required, the auscultation of heart and lung sounds is essential to provide information on the patient’s cardiorespiratory system. Heart and lung sounds can be recorded using an esophageal stethoscope; however, there is huge background noise when this device is used in an operating room. In this study, a digital esophageal stethoscope system was designed. A 3D-printed case filled with Polydimethylsiloxane material was designed to hold two electret-type microphones. One of the microphones was placed inside the printed case to collect the heart and lung sound signals coming out from the patient through the esophageal catheter, the other was mounted on the surface of the case to collect the operating room sounds. A developed adaptive noise canceling algorithm was implemented to remove the operating room noise corrupted with the main heart and lung sound signals and the output signal was displayed on software application developed especially for this study. Using the designed case, the noise level of the signal was reduced to some extent, and by adding the adaptive filter, further noise reduction was achieved. The designed system is lightweight and can provide noise-free heart and lung sound signals.

Download Full-text

Biomedical applications: Pitfalls in the practice

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100169626 ◽

1994 ◽

Vol 52 ◽

pp. 378-379

Author(s):

J. D. Shelburne ◽

Peter Ingram ◽

Victor L. Roggli ◽

Ann LeFurgey

Keyword(s):

Operating Room ◽

Liquid Nitrogen ◽

Lung Tissue ◽

Biomedical Applications ◽

Microprobe Analysis ◽

Tissue Sample ◽

Cellular Level ◽

Tissue Samples ◽

Asbestos Fibers

At present most medical microprobe analysis is conducted on insoluble particulates such as asbestos fibers in lung tissue. Cryotechniques are not necessary for this type of specimen. Insoluble particulates can be processed conventionally. Nevertheless, it is important to emphasize that conventional processing is unacceptable for specimens in which electrolyte distributions in tissues are sought. It is necessary to flash-freeze in order to preserve the integrity of electrolyte distributions at the subcellular and cellular level. Ideally, biopsies should be flash-frozen in the operating room rather than being frozen several minutes later in a histology laboratory. Electrolytes will move during such a long delay. While flammable cryogens such as propane obviously cannot be used in an operating room, liquid nitrogen-cooled slam-freezing devices or guns may be permitted, and are the best way to achieve an artifact-free, accurate tissue sample which truly reflects the in vivo state. Unfortunately, the importance of cryofixation is often not understood. Investigators bring tissue samples fixed in glutaraldehyde to a microprobe laboratory with a request for microprobe analysis for electrolytes.

Download Full-text