Great Hospitals: The History of Neurosurgery at the University of Vermont Medical Center-A Macroscopic Examination of Microscope-Savvy Pioneers.

The University of Vermont's (UVM) Division of Neurosurgery is enshrined in a rich history of innovation and academic prowess, which have significantly contributed to making neurosurgery the field it is today. From humble beginnings, the department was started by one Raymond Madiford Peardon "Pete" Donaghy on a parenthetically watertight research budget amounting to $25 and shared space in a Quonset hut. Passion and commitment to progress, as well as an innate openness to collaboration, propelled Pete Donaghy, his colleagues, pupils, and successors to establish an exemplary center for treatment of neurosurgical disease, with multiple revolutionary accomplishments along the way. These accomplishments include the birth and promotion of microneurosurgery, the performance of the first extracranial to intracranial bypass, and the education of other neurosurgical giants. The New England Skull Base Course, held annually in UVM's "R.M. Peardon Donaghy Microvascular and Skull Base Laboratory," is a 3-day cadaver-based teaching course for neurosurgery and ear nose and throat residents throughout New England. The course bears testament to Donaghy's everlasting influence on the UVM Division of Neurosurgery and continues to positively affect the education of countless trainees. The purpose of this historical perspective is to outline the events and accomplishments that define the UVM Division of Neurosurgery's many contributions to the field at large and the ongoing efforts to honor Donaghy's example through maintaining a culture of humility, hard work, and commitment to neurosurgical innovation and education.

Microscopic and Endoscopic Skull Base Approaches Hands-On Cadaver Course at 30: Historical Vignette.

Laboratory-based cadaveric training is essential for the development and refinement of neurosurgical technical skills in the operating room and has become an integral training component around the world. Postresidency fellowship-the first pillar of skull base surgery training-includes both hands-on clinical care and surgery supervised by an experienced skull base surgeon. Time is spent in a skull base laboratory practicing approaches and developing anatomic mastery. The second pillar includes formal skull-base courses-institutional dissection laboratories provide continuous anatomic and surgical education while complementary annual or semiannual cadaver courses gather recognized experts to share their knowledge and experience in an essential 2- to 3-day setting. In this paper, we present the history of the longest running annual skull-base cadaver microsurgical course, which was started by Dr. Ossama Al-Mefty: Annual Surgical Approaches to the Skull Base Course. At the Microscopic and Endoscopic Hands-on Cadaver Workshop, held in St. Louis, Missouri, we celebrated its 30th anniversary in April 2019. We also present the impact this course has had on neurosurgery and skull base surgery and on the professional and scientific developments of its participants in particular.

From magnifying glass to operative microscopy - the historical and modern role of the microscope in microsurgery.

The modern computer-assisted microscope, being a hallmark of microsurgery, has become a standard piece of equipment in the operating theatre. Its introduction enabled visualisation of fine anatomical structures, obscure to the unaided eye, and revolutionised many surgical specialties, such as neurological, ophthalmological, or vascular. These astounding achievements have been the culmination of a century of constant progress in optical engineering and microsurgery, since 1921, when a microscope was first used during surgery. Long before surgery, pathology adopted microscopes, and they have become its most prominent diagnostic tools. We traced the evolution of this important invention and discussed its present status and future prospects.

Timing of Microsurgical Reconstruction in Lower Extremity Trauma: An Update of the Godina Paradigm.

BACKGROUND: Marko Godina, in his landmark paper in 1986, established the principle of early flap coverage for reconstruction of traumatic lower extremity injuries. The aim of this study was to determine how timing influences outcomes in lower extremity traumatic free flap reconstruction based on Godina's original findings. METHODS: A retrospective review identified 358 soft-tissue free flaps from 1979 to 2016 for below knee trauma performed within 1 year of injury. Patients were stratified based on timing of coverage: 3 days or less (early), 4 to 90 days (delayed), and more than 90 days (late). The delayed group was further divided into two groups: 4 to 9 days and 10 to 90 days. Flap outcomes were examined based on timing of reconstruction. RESULTS: Flaps performed within 3 days after injury compared with between 4 to 90 days had decreased risk of major complications (OR, 0.40, p = 0.04). A receiver operating curve demonstrated day 10 to be the optimal day for predicting flap success. Flaps performed less than or equal to 3 days versus 4 to 9 days had no differences in any flap outcomes. In contrast, flaps performed within 4 to 9 days of injury compared to within 10 to 90 days were associated with significantly lower total flap failure rates (relative risk, 0.29, p = 0.025) and major complications (relative risk, 0.37, p = 0.002). CONCLUSIONS: Early free flap reconstruction performed within 3 days of injury had superior outcomes compared with the delayed (4 to 90 day) group, consistent with Godina's original findings. However, as an update to his paradigm, this ideal early period of reconstruction can be safely extended to within 10 days of injury without an adverse effect on outcomes. CLINICAL QUESTION/LEVEL OF EVIDENCE: Therapeutic, III.

The history of microsurgery.

Microsurgery is a term used to describe the surgical techniques that require an operating microscope and the necessary specialized instrumentation, the three "Ms" of Microsurgery (microscope, microinstruments and microsutures). Over the years, the crucial factor that transformed the notion of microsurgery itself was the anastomosis of successively smaller blood vessels and nerves that have allowed transfer of tissue from one part of the body to another and re-attachment of severed parts. Currently, with obtained experience, microsurgical techniques are used by several surgical specialties such as general surgery, ophthalmology, orthopaedics, gynecology, otolaryngology, neurosurgery, oral and maxillofacial surgery, plastic surgery and more. This article highlights the most important innovations and milestones in the history of microsurgery through the ages that allowed the inauguration and establishment of microsurgical techniques in the field of surgery.

The history of neurosurgery at the House Clinic in Los Angeles.

Although most widely known as the birthplace of neuro-otology, the House Clinic in Los Angeles has been the site of several major contributions to the field of neurosurgery. From the beginning of the formation of the Otologic Medical Group in 1958 (later renamed the House Ear Clinic), these contributions have been largely due to the innovative and collaborative work of neurosurgeon William E. Hitselberger, MD, and neuro-otologist William F. House, MD, DDS. Together they were responsible for the development and widespread adoption of the team approach to skull-base surgery. Specific neurosurgical advances accomplished at the House Clinic have included the first application of the operative microscope to neurosurgery, the application of middle fossa and translabyrinthine approaches for vestibular schwannoma, and the development of combined petrosal, retrolabyrinthine, and other alternative petrosal approaches and of hearing preservation surgery for vestibular schwannoma. The auditory brainstem implant, invented at the House Clinic in 1979, was the first ever successful application of central nervous system neuromodulation for restoration of function. Technological innovations at the House Clinic have also advanced neurosurgery. These include the first video transmission of microsurgery, the first suction irrigator, the first debulking instrument for tumors, and the House-Urban retractor for middle fossa surgery.

[Vascular microsurgery course: 40 years at the Centro Médico Nacional 20 de Noviembre (ISSSTE) and 33 years at the Faculty of Medicine of the UNAM]. / Curso de microcirugía vascular: 40 años en el Centro Médico Nacional 20 de Noviembre del Instituto de Seguridad y Servicios Sociales de los Trabajadores del Estado y 33 años en la Facultad de Medicina de la Universidad Nacional Autónoma de México.

On June 1977, "Centro Médico Nacional 20 de Noviembre," in Mexico City, implemented the first vascular microsurgery course. The aim was to develop clinical applications of microsurgery focus on surgical specialties, due to the necessity to develop microsurgical skills. On August 1964 we started the program course at the surgical department of the School of Medicine at Universidad Nacional Autónoma de México (UNAM). Actually, our course is given five times a year at 20 de Noviembre hospital, and four times at the UNAM. One June 2017, the Experimental Surgical Department at "Centro Médico Nacional 20 de Noviembre" reached 40 continuous or uninterrupted years of successfully teaching the microsurgical vascular skills. The aim of this study is to evaluate the satisfaction degree among the students. For that propose, a written survey was applied one year later, after successfully completed the course. These results reveal a satisfaction rate of 80% among these students.

El Curso de Microcirugía Vascular (CMV) inició en el Centro Médico Nacional (CMN) 20 de Noviembre en la Ciudad de México, en junio de 1977, con la idea de poder desarrollar aplicaciones clínicas de microcirugía en todas las especialidades quirúrgicas. En vista de la gran demanda hacia la microcirugía como destreza, en agosto de 1984 iniciamos el programa de Microcirugía Vascular en el Departamento de Cirugía de la Facultad de Medicina de la Universidad Nacional Autónoma de México (UNAM). El CMV se imparte cinco veces al año en el CMN 20 de Noviembre del Instituto de Seguridad y Servicios Sociales de los Trabajadores del Estado y cuatro en la Facultad de Medicina de la UNAM. En junio de 2017, el Servicio de Cirugía Experimental del CMN 20 de Noviembre cumple 40 años ininterrumpidos de impartir con éxito el CMV. Con el fin de evaluar el CMV de acuerdo con el nivel de satisfacción, a partir de 2016 se implementó el uso de un cuestionario. La finalidad es dar seguimiento repitiendo el cuestionario un año después para valorar las habilidades adquiridas. Los porcentajes demuestran que más del 80% de los alumnos están satisfechos con las destrezas adquiridas en el CMV.

The microneurosurgical anatomy legacy of Albert L. Rhoton Jr., MD: an analysis of transition and evolution over 50 years.

The authors chronologically categorized the 160 original articles written by Dr. Rhoton and his fellows to show why they selected their themes and how they carried out their projects. The authors note that as neurosurgery progresses and new techniques and approaches are developed, accurate and safe treatment will depend upon continued clarification of microsurgical anatomy.

Godina's Principles in the Twenty-First Century and the Evolution of Lower Extremity Trauma Reconstruction.

BACKGROUND: February of 2016 marked 30 years since the passing of Marko Godina, a pioneer and prodigy in the field of reconstructive microsurgery. Most noteworthy among his many contributions was his method of radical debridement of contaminated compound fractures followed by early free tissue transfer for wound closure. In the last three decades, the landscape of reconstructive surgery has undergone significant transformation owing to advances in reconstructive techniques and wound care technology, as well as new data. METHODS: Dr. Godina's work and legacy are reviewed, compared and contrasted with new and evolving data regarding lower extremity trauma reconstruction. RESULTS: Advancements in technique and technology have greatly molded lower extremtiy reconstruction over the past thirty years. Nonetheless, Dr. Godina's principles of timely care and early vascularized soft tissue coverage have withstood the test of time. CONCLUSION: Marko Godina's contribution to reconstructive microsurgery cannot be overstated and his groundbreaking work continues to serve as the foundation of lower extremity trauma reconstruction. Three decades after his seminal work, we honor Dr. Godina's legacy and explore how his principles have endured, evolved, or been replaced.

History, Evolution, and Continuing Innovations of Intracranial Aneurysm Surgery.

Evolution in the surgical treatment of intracranial aneurysms is driven by the need to refine and innovate. From an early application of the Hunterian carotid ligation to modern-day sophisticated aneurysm clip designs, progress has been made through dedication and technical maturation of cerebrovascular neurosurgeons to overcome challenges in their practices. The global expansion of endovascular services has challenged the existence of aneurysm surgery, changing the complexity of the aneurysm case mix and volume that are referred for surgical repair. Concepts of how to best treat intracranial aneurysms have evolved over generations and will continue to do so with further technological innovations. As with the evolution of any type of surgery, innovations frequently arise from the criticism of current techniques.

[The Development of First Operating Microscopes from Zeiss Jena and Oberkochen to Series Production]. / Die Entwicklung der ersten OP-Mikroskope von Zeiss Jena und Oberkochen bis zur Serienfertigung.

Introduction: The history of the first operating microscopes from Zeiss is often confusing, not painstaking and partly contradictory because of the parallel development of Zeiss Jena (East Germany) and Zeiss Oberkochen (West Germany). Methods: To investigate the early beginnings of the construction of the operating microscopes documents of the Carl Zeiss Archive and the Optical Museum in Jena, the memoirs of Prof. Dr. Rosemarie Albrecht and some relevant publications were used. Results: The development of the first Jena operating microscope was initiated in 1949 by the ENT-physician Prof. Dr. Rosemarie Albrecht in the Soviet occupation zone. The first prototype was tested in the University ENT Clinic, Jena since summer of 1950. On the Leipzig Trade Fair in autumn 1952 the VEB Optik Carl Zeiss Jena presented the first operating microscope nationally and internationally. Series production began in 1953. The first operating microscope of Zeiss Oberkochen was primarily developed by technical designers (H. Littmann) as a colposcope. But in the Carl Zeiss Archive no documents could be found related to the cooperation with gynecologists. 1953 the operating microscope (OPMI 1) came into public and its series production started. From this date on, it was adopted by the otologist Prof. Dr. Horst Ludwig Wullstein to the needs of Otorhinolaryngology. Conclusion: The first Zeiss operating microscope came from Jena. The operating microscope from Zeiss Oberkochen had some advantages for the surgeons and won the competition in the future.

Advances and Innovations in Microsurgery.

LEARNING OBJECTIVES: After reading this article, the participant should be able to: 1. summarize the evolution of perforator, chimeric, and free style flaps; 2. define and give examples of supermicrosurgery as well as understand its application in treatment of lymphedema; and 3. appreciate the development and advancements of composite tissue allotransplantation. SUMMARY: Although microsurgery may seem like a highly specialized niche within plastic surgery, it is more than just a discipline that focuses on small anastomoses. It is a tool and a way of thinking that allows us to embody the true tenets of plastic surgery, as quoted by Tagliocozzi. What began as a challenge of returning amputated tissue to the body and achieving wound closure has evolved into a refinement of technique and change in philosophy that empowers the plastic surgeon to work creatively to "restore, rebuild, and make whole."