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Streamlining brain tumor surgery care during the COVID-19 pandemic: A case-control study

  • Regin Jay Mallari,

    Roles Data curation, Formal analysis, Investigation, Methodology, Validation, Writing – original draft, Writing – review & editing

    Affiliation Pacific Neuroscience Institute, Providence Saint John’s Health Center, Santa Monica, California, United States of America

  • Michael B. Avery,

    Roles Data curation, Formal analysis, Investigation, Methodology, Validation, Writing – original draft, Writing – review & editing

    Affiliation Pacific Neuroscience Institute, Providence Saint John’s Health Center, Santa Monica, California, United States of America

  • Alex Corlin,

    Roles Data curation, Formal analysis, Writing – original draft

    Affiliation Pacific Neuroscience Institute, Providence Saint John’s Health Center, Santa Monica, California, United States of America

  • Amalia Eisenberg,

    Roles Data curation, Investigation, Methodology, Writing – original draft, Writing – review & editing

    Affiliation Pacific Neuroscience Institute, Providence Saint John’s Health Center, Santa Monica, California, United States of America

  • Terese C. Hammond,

    Roles Conceptualization, Data curation, Writing – review & editing

    Affiliation Saint John’s Cancer Institute (formerly John Wayne Cancer Institute), Providence Saint John’s Health Center, Santa Monica, California, United States of America

  • Neil A. Martin,

    Roles Conceptualization, Formal analysis, Writing – review & editing

    Affiliations Pacific Neuroscience Institute, Providence Saint John’s Health Center, Santa Monica, California, United States of America, Saint John’s Cancer Institute (formerly John Wayne Cancer Institute), Providence Saint John’s Health Center, Santa Monica, California, United States of America

  • Garni Barkhoudarian,

    Roles Conceptualization, Formal analysis, Investigation, Methodology, Project administration, Supervision, Writing – review & editing

    Affiliations Pacific Neuroscience Institute, Providence Saint John’s Health Center, Santa Monica, California, United States of America, Saint John’s Cancer Institute (formerly John Wayne Cancer Institute), Providence Saint John’s Health Center, Santa Monica, California, United States of America

  • Daniel F. Kelly

    Roles Conceptualization, Data curation, Formal analysis, Methodology, Project administration, Supervision, Writing – original draft, Writing – review & editing

    dkelly@pacificneuro.org

    Affiliations Pacific Neuroscience Institute, Providence Saint John’s Health Center, Santa Monica, California, United States of America, Saint John’s Cancer Institute (formerly John Wayne Cancer Institute), Providence Saint John’s Health Center, Santa Monica, California, United States of America

Abstract

Background

The COVID-19 pandemic forced a reconsideration of surgical patient management in the setting of scarce resources and risk of viral transmission. Herein we assess the impact of implementing a protocol of more rigorous patient education, recovery room assessment for non-ICU admission, earlier mobilization and post-discharge communication for patients undergoing brain tumor surgery.

Methods

A case-control retrospective review was undertaken at a community hospital with a dedicated neurosurgery and otolaryngology team using minimally invasive surgical techniques, total intravenous anesthesia (TIVA) and early post-operative imaging protocols. All patients undergoing craniotomy or endoscopic endonasal removal of a brain, skull base or pituitary tumor were included during two non-overlapping periods: March 2019–January 2020 (pre-pandemic epoch) versus March 2020–January 2021 (pandemic epoch with streamlined care protocol implemented). Data collection included demographics, preoperative American Society of Anesthesiologists (ASA) status, tumor pathology, and tumor resection and remission rates. Primary outcomes were ICU utilization and hospital length of stay (LOS). Secondary outcomes were complications, readmissions and reoperations.

Findings

Of 295 patients, 163 patients were treated pre-pandemic (58% women, mean age 53.2±16 years) and 132 were treated during the pandemic (52% women, mean age 52.3±17 years). From pre-pandemic to pandemic, ICU utilization decreased from 92(54%) to 43(29%) of operations (p<0.001) and hospital LOS≤1 day increased from 21(12.2%) to 60(41.4%), p<0.001, respectively. For craniotomy cohort, median LOS was 2 days for both epochs; median ICU LOS decreased from 1 to 0 days (p<0.001), ICU use decreased from 73(80%) to 29(33%),(p<0.001). For endonasal cohort, median LOS decreased from 2 to 1 days; median ICU LOS was 0 days for both epochs; (p<0.001). There were no differences pre-pandemic versus pandemic in ASA scores, resection/remission rates, readmissions or reoperations.

Conclusion

This experience suggests the COVID-19 pandemic provided an opportunity for implementing a brain tumor care protocol to facilitate safely decreasing ICU utilization and accelerating discharge home without an increase in complications, readmission or reoperations. More rigorous patient education, recovery room assessment for non-ICU admission, earlier mobilization and post-discharge communication, layered upon a foundation of minimally invasive surgery, TIVA anesthesia and early post-operative imaging are possible contributors to these favorable trends.

Introduction

As the COVID-19 pandemic spread into the U.S. and global healthcare system in February and March of 2020, hospitals rapidly adjusted to care for the influx of infected patients [13]. This redirection created a reduced capacity to perform operations and an overall dramatic but transient decrease in surgical volumes at most hospitals, including neurosurgical procedures [46]. With limited ICU beds and the concern of viral transmission between patients and caregivers, many hospitals stopped non-emergent neurosurgical procedures for several weeks or months early in the pandemic then gradually resumed as COVID-dedicated wards were established [7, 8]. While this unforeseen crisis delayed care for many patients, it provided an opportunity and call to action for further streamlining safe and efficient brain tumor care.

Surgery for primary and secondary brain tumors by craniotomy or endonasal transsphenoidal removal is resource intensive and has historically required multi-day hospital admissions, often including initial recovery in the ICU [913]. For over a decade, our center has been using minimally invasive approaches, complication avoidance protocols, total intravenous anesthesia (TIVA) and early postoperative imaging to optimize outcomes and shorten LOS in patients with brain, skull base and pituitary tumors [1420]. The pandemic-induced scarcity of ICU and monitored beds at our hospital, further forced our clinicians and administrators to develop accelerated timelines and safety protocols from admission to discharge, so that brain tumor patients with evolving neurological deficits or endocrinopathies could be treated expeditiously.

Herein, we analyze two brain tumor cohorts from two non-overlapping epochs immediately before the pandemic and during the pandemic during which a streamlined care protocol was implemented. We assess ICU and hospital LOS, surgical complications, readmissions and reoperations. Prior studies have demonstrated that LOS, ICU LOS, and readmissions are suitable measures of resource utilization and the downstream impact of surgical complications [2124]. Although we do not present financial data, we believe this case-control series provides valuable information on how reductions in brain tumor care resource utilization can be achieved without compromising quality or patient safety.

Methods

Patient population, setting and study design

After institutional review board (Providence Saint John’s Cancer Institute) approval (IRB# JWCI-19-1101), a retrospective review was performed of all patients who underwent surgery for a primary or secondary brain tumor, skull base tumor, or pituitary tumor by one of the senior authors (DFK, GB) [25]. Patient consent was waived due to the retrospective nature of the study.

All patients were cared for at Providence Saint John’s Health Center in Santa Monica, CA, a non-trauma center community hospital with neurosurgical and surgical oncology fellowship training programs, and a brain tumor and pituitary tumor referral center. The hospital has 204 adult licensed beds including a shared ICU of 23 beds, 25 telemetry/step-down unit beds and 156 adult medical-surgical beds; an additional 62 beds are licensed for women and children.

The study period was divided into two epochs: March 2019–January 2020 (pre-pandemic) and March 2020–January 2021 (pandemic). Data collected and analyzed through EPIC electronic medical record included patient demographics, histopathology, preoperative American Society of Anesthesiologists (ASA) status, pre- and postoperative clinical status, magnetic resonance imaging (MRI), operative notes, ICU and hospital LOS, and complications: death, stroke, hematoma, cranial neuropathy, cerebrospinal fluid (CSF) leak, meningitis, hypopituitarism, epistaxis requiring treatment, pulmonary embolus (PE), deep vein thrombosis (DVT), myocardial infarction (MI). All patients had at least a 1-month clinical follow-up, and pre- and post-operative hormonal testing for patients with pituitary and parasellar tumors.

Preoperative patient evaluation and management

As previously described, all patients were evaluated in an outpatient clinic with physical examination, MRI, other relevant neuro-imaging studies, blood work, hormonal testing and medical clearance [14, 15, 17]. All patients had a symptomatic or growing tumor and most were admitted the day of surgery; a minority (6%) were emergent or transferred urgently from an outside hospital.

Surgical approach & complication avoidance protocols

All operations were performed in non-overlapping fashion [26, 27]. Total intravenous anesthesia (TIVA) was used in all cases to promote rapid emergence from surgery [2830]. Surgical approach was tailored according to tumor pathology, location, and prior treatments. Minimally invasive “keyhole” approaches such as the supraorbital, mini-pterional or retromastoid route were applied to most tumors often augmented with endoscopic visualization [15, 17, 20, 31] and always with surgical navigation and Doppler probe for vessel localization [14, 15, 17, 32]. An endoscopic endonasal route was used for almost all pituitary adenomas, and many midline skull base tumors such as craniopharyngiomas and meningiomas [16, 18, 20, 31, 33].

A graded skull base repair protocol was used to minimize risk of post-operative CSF leak and meningitis, and pituitary gland sparing procedures were used to maximize chances of gland recovery and minimize risk of new hypopituitarism [16, 34, 35].

Post-operative surveillance, imaging and mobilization

Patients were extubated in the operating room immediately post-surgery, and upon arrival to the recovery room, were carefully observed with standard vital sign monitoring and neurological assessments. Patients had a postoperative head computed tomography (CT) after surgery from the recovery room. Provided there were no concerning findings, and the patient was awakening well from surgery, they were admitted to a step-down unit monitored bed [16, 17]. ICU admission was generally reserved for patients with significant comorbidities, severe preoperative neurological deficits, severe preoperative brain edema, high seizure risk, new postoperative deficits, requiring continued mechanical ventilation or at significant risk of airway compromise [3638]. A brain or pituitary MRI is typically performed on post-operative day (POD) #1.

Pandemic epoch streamlined care protocol

Initially, from March-October 2020, all patients were required to have 2 negative SARS-CoV-2 tests (RT-PCR) within 7 days of surgery. In the last 3 months of the pandemic epoch, one negative SARS-CoV-2 test (RT-PCR) within 4 days of surgery was required. If the patient required urgent surgery due to imminent neurological deterioration and had a positive SARS-CoV-2 test, the operation would proceed in a dedicated COVID operating suite.

Our streamlined care protocol initiated at the onset of the pandemic included several changes to facilitate less ICU utilization and shorter hospitalization (Table 1). First, in the preoperative clinic visit, we initiated more direct patient and family counseling, explaining they would likely be ready for hospital discharge by POD#1 or #2, provided they were ambulating well, and post-operative imaging showed expected changes. They were also told that timely discharge was in their best interest so they could be home with family members, and in turn would free-up beds for patients with COVID-19 or other critical illnesses. Specifically, most supratentorial brain tumor patients were told they would likely go to a stepdown unit bed and be ready for discharge home on POD#1 provided they awoke well from surgery and their CT scan from the recovery room demonstrated expected findings. Similarly, endonasal surgery patients with pituitary adenomas and Rathke’s cleft cysts were told that they would be admitted to a step-down unit bed and would likely be able to go home on POD#1. Patients with more complex tumors such as craniopharyngiomas, skull base meningiomas and posterior fossa tumors were told a decision of ICU versus step-down unit and discharge day would be based on clinical status in recovery room and post-operative CT, but that a POD#1 discharge was quite possible.

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Table 1. Clinical practice protocols promoting less ICU utilization and early discharge.

https://doi.org/10.1371/journal.pone.0254958.t001

Second, all care team members, including recovery room staff, ICU and step-down unit staff, were made aware of the goal for non-ICU use if appropriate and earlier discharge, using multidisciplinary discussions including nurses, case managers, physical and occupational therapists aimed at assessing and prepping patients for early discharge. Postoperative orders were written that called for all relevant team members to initiate evaluations promptly, including early POD#1 MRI to facilitate rapid discharge.

Third, in the recovery room, if a patient was doing well (as assessed by the neurosurgical team and nursing staff) with a non-focal neurological exam or stable or improving exam compared to preoperative deficits, and head CT showed expected postoperative changes, such patients generally did not go to the ICU. Additionally, patients with a more delayed emergence from anesthesia or labile vital signs, were typically observed in recovery room for a longer period (up to 2–3 hours), which in most cases confirmed suitability for transfer to the step-down unit.

Fourth, all patients were mobilized as soon as possible post-surgery, with assistance from nurses and therapists typically beginning the day of surgery. Finally, all patients received a follow-up phone call the day after discharge by the neurosurgical nurse practitioner and had their first follow-up clinic appointment typically within 7 days of surgery.

Data collection and outcome measures

Primary outcomes were ICU usage and hospital LOS with subgroup analysis for craniotomy and endonasal cohorts. Secondary outcomes were surgical complications, 30-day readmissions and reoperations. Tumor resection rates were defined as follows: gross-total resection (GTR) if no residual tumor is seen on the immediate postoperative MRI, near total resection (NTR) if ≥90% tumor removal, and subtotal removal (STR) if <90% tumor removal [15, 17, 20]. For patients with endocrine-active pituitary adenomas (acromegaly, Cushing’s disease, prolactinoma, thyrotropinoma), early surgical remission rates were reported as previously described [14].

Statistical analysis

Between-groups and within-group analyses were performed to determine any statistical differences. The χ2 test or the Fisher’s exact test was used to compare categorical variables. One-way ANOVA and/or the student t-test was used to determine statistical differences between the means of independent samples, while Kruskal-Wallis testing was used to compare continuous, nonparametric distributions. Statistical analysis was performed using IBM’s SPSS Software Version 26 (IBM Corp., Armonk, NY) with p<0.05 considered as statistically significant.

Results

Patient characteristics

Patient demographics and other characteristics are outlined in Table 2. The study period included 295 patients (56% women, mean age 52.8±17 years) who underwent a total of 317 operations (57% craniotomy, 43% endonasal). Of these, 163 patients (58% women, mean age 53.2±16 years) underwent 172 operations (53% craniotomy, 47% endonasal) pre-pandemic, and 132 patients (52% women, mean age 52.3±18 years) underwent 145 (61% craniotomy, 39% endonasal) operations during the pandemic. No significant differences were seen in age, prior surgery or pre-operative ASA class for craniotomy nor endonasal patients in the pre-pandemic and pandemic epochs. Tumor pathology subtypes were similar between the pre-pandemic and pandemic cohorts.

ICU and hospital LOS

Hospital LOS and ICU LOS pre-pandemic versus pandemic epochs are detailed in Table 3 and Fig 1. Mean LOS decreased for the entire cohort, but median LOS remained at 2 days. ICU utilization decreased from 53.5% to 29.7%, (p<0.001), and median ICU LOS decreased from 1 day to 0, (p<0.001). The percentage of patients discharged by POD#1 increased from 12.2% pre-pandemic to 41.4%, during the pandemic epoch, (p<0.001).

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Fig 1. Pre-pandemic versus pandemic hospital LOS from POD 0–10 for craniotomy and endonasal cohorts.

Overall LOS of 1day or less increased from 21 (12.2%) to 60 (41.4%), p<0.001. There were 6 and 4 patients (all craniotomies) in the pre-pandemic and pandemic cohorts who had LOS>10 days, respectively (not shown for graph readability). LOS range for craniotomy and endonasal approach was 1–20 days and 0–8 days, respectively.

https://doi.org/10.1371/journal.pone.0254958.g001

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Table 3. Primary and secondary outcomes pre-pandemic versus pandemic epochs.

https://doi.org/10.1371/journal.pone.0254958.t003

Considering the craniotomy cohort from pre-pandemic to pandemic epoch, ICU use decreased from 73(80%) to 29(33%), (p<0.001), mean ICU LOS decreased from 1.4±1.9 to 0.4±0.6 days (p<0.001) and median ICU LOS decreased from 1 to 0 days (p<0.001). For the endonasal cohort, median ICU LOS remained at 0 days while median hospital LOS decreased from 2 to 1 day (p<0.001).

The proportion of patients discharged by POD#1 significantly increased in the pandemic epoch for both craniotomy and endonasal surgeries (10% to 31% for craniotomy, p<0.001; 15% to 58% for endonasal, p<0.001). The only factors associated with LOS>3 days were pathology of glioma or metastasis (69% vs 31%, p = 0.04); prior surgery and patient age were not significant.

Complications, reoperations and unplanned 30-day readmissions

Comparing pre-pandemic and pandemic cohorts, no significant differences were seen in overall complication rates, reoperations, unplanned 30-day readmissions or mortality (Table 3). Major post-operative complications occurred in 17/163 (10%) patients undergoing craniotomies and 12/132 (9%) patients undergoing endonasal surgeries.

Post-operative neurological worsening after craniotomy (pre-pandemic and pandemic) occurred in 4 (2.4%) patients: two of whom suffered from ischemic infarcts, and both eventually improved. Complications requiring surgical intervention occurred in 3 (1.8%) patients: one for CSF leak repair, one for acute hematoma, and one for wound dehiscence. Reoperations for additional tumor removal occurred in 6 (3.6%) patients. Post-operative neurological worsening after endonasal surgery (oculomotor palsy) occurred in 1(0.8%) patient; 3 (2.2%) had CSF leaks, 2 of whom had reoperation. There were no cases of meningitis in the two cohorts and no operative deaths but 3 (1.8%) patients undergoing craniotomies for malignant tumors died within 30 days of surgery from tumor progression in the pandemic epoch.

Median ICU LOS (1 day vs 0, p = 0.02) and overall LOS (3 days vs 2, p<0.001) were both significantly longer for patients who suffered from major surgical complications. The most common reason for readmission for craniotomy patients was neurological worsening due to malignant tumor progression (5 patients—2 pre-pandemic, 3 pandemic epoch), while for endonasal patients it was for CSF rhinorrhea (3 patients pre-pandemic).

Regarding ICU use, as shown in Table 4, in addition to the factors of pre-pandemic epoch and having a craniotomy, patients with longer surgery times, higher EBL and a meningioma were more likely to be admitted to ICU. No patients in either the pre-pandemic or pandemic cohorts required admission to the ICU after initial admission to the step-down unit.

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Table 4. Factors associated with ICU versus non-ICU admission.

https://doi.org/10.1371/journal.pone.0254958.t004

Extent of tumor resection/remission

Tumor resection and endocrine remission rates were similar for pre-pandemic and pandemic cohorts: GTR/NTR was achieved in 62/91 (68%) versus 70/88 (80%) of craniotomies (p = 0.09), and in 57/64 (89%) versus 35/41 (85%) of endonasal operations (p = 0.76), respectively. Early endocrine remission of functional adenomas was 12/17 (71%) pre-pandemic versus 10/16 (63%) pandemic, respectively, p = 0.72.

COVID-19 infections

No patients or members of the surgical team contracted COVID-19 during the pandemic epoch in the postoperative period. One patient did become infected with COVID-19 one month after surgery, but likely due to outside circumstances beyond the surgery itself.

Discussion

Summary of experience & overview

In two brain tumor patient cohorts, well-matched in terms of age, preoperative ASA status, surgical approach and tumor pathology mix, after implementing a streamlined care protocol during the 11-month pandemic epoch, ICU utilization decreased from 54% to 29% of operations and hospital LOS of 1 day or less increased from 12% to 41%. For the craniotomy cohort, ICU utilization decreased from 80% to 33% and for the endonasal cohort, hospital LOS of 1 day or less increased from 15% to 58%. No patient who was initially monitored in the step-down unit required transfer into the ICU. The two cohorts had similar rates of tumor resection/ remission, surgical complications, readmissions and reoperations.

Winston Churchill is credited with saying “Never let a good crisis go to waste.” As U.S. healthcare gradually emerges from the pandemic, many aspects of surgical care, including how we prepare patients for surgery and where and how they recover will be forever altered. In our experience, the pandemic forced us to reconsider some basic assumptions about brain tumor care and acted as an accelerant to rapidly implement protocol changes that we had already been using on a more limited basis. In managing patients with benign and malignant brain tumors, skull base tumors and pituitary tumors, several factors can facilitate safe and early discharge and reduce ICU usage. Five of these factors were already integrated into our perioperative protocols (Table 1). The pandemic encouraged us to go further in terms of having i) more rigorous patient preparation and education, ii) more rigorous assessment in the recovery room for need of ICU monitoring and gaining a team comfort level of admission to a step-down unit bed, iii) focused care team engagement to encourage and facilitate early discharge, iv) earlier postoperative patient mobilization, and v) early patient follow-up post-discharge.

Minimally invasive tumor removal & complication avoidance protocols

The use of minimally invasive approaches for brain tumors is based in a philosophy and practice of limited brain exposure and manipulation, working through smaller corridors without static brain retractors and augmenting visualization with endoscopy and gravity-assisted positioning as needed, with the goal of maximal safe tumor resection [15, 31, 33]. The endoscopic endonasal route is now a well-accepted approach for many midline skull base and parasellar non-pituitary tumors. In our experience and that of others, using smaller incisions with more focused craniotomies, or the natural endonasal corridor facilitate less brain exposure, rapid healing, reduced pain need for narcotics, and a greater willingness for patients to mobilize and leave the hospital soon after surgery [15, 17, 31, 33, 3941]. Similarly, strict complication avoidance protocols help facilitate short LOS, reduced ICU use, and lower overall complication rates [42, 43]. For example, the measures we routinely employ of surgical navigation, Doppler ultrasound for vessel localization, endoscopy for maximizing visualization and strict skull base closure protocols to avoid CSF leaks in aggregate are associated with a low rate of new neurological deficits (1%, 3/317 operations) and a low CSF leak rate of 1.2% (4/317 operations) with no cases of meningitis [16, 17].

In recent large case series or national database reviews of craniotomy for brain tumor, mean LOS ranged from 6–6.4 days and median LOS ranged from 2–4 days, compared to our pandemic epoch mean LOS of 3.2 days and median LOS of 2 days [911, 44]. Similarly, for endonasal tumor removal, recent large case series had mean LOS ranging from 2.7–2.9 days compared to our pandemic epoch mean LOS of 1.7 days [12, 13].

Early postoperative imaging

Having a head CT immediately post-surgery is an important aspect of complication avoidance, serving as an early warning system for an evolving hematoma, suboptimal skull base reconstruction or other postoperative complications [16]. A postoperative CT showing expected changes also provides a greater sense of confidence that recovery in a non-ICU bed is safe.

Total intravenous anesthesia and limited postoperative narcotics

Compared to inhaled anesthetics, TIVA has been associated with lower rates of postoperative nausea, vomiting, and cognitive dysfunction and delirium, factors which contribute to extended hospital stay [2830]. Similarly, reduced narcotic use in the early perioperative period aim to help patients be more cognitively alert and physically active. In this cohort, there was only one case of DVT and no PEs, MIs or 30-day surgical mortalities. The low rate of thromboembolic events is likely due in part to the high functionality of patients with early ambulation and limited perioperative narcotic use and compares favorably to the 2.7–4.1% incidence recently published [45, 46].

Pandemic-induced enhancements of patient preparation, education & team engagement

During the initial COVID-19 surge in April-May 2020 and at the height of the second surge in December 2020-January 2021 (peak of 88 patients), our neurosurgical caseload was curtailed due to lack of ICU and step-down unit beds. However, the protocol we implemented early in the pandemic allowed us to still bring patients to surgery and rapidly and safely discharge them. We postulate, as others have shown, that more extensive patient education and expectation management of their ability to safely leave the hospital helped in this effort [47, 48]. Patient motivation in minimizing their hospital stay has helped facilitate these changes, which would have previously been met with a level of reluctance. Having the entire care team of surgeons, anesthesiologists, recovery room staff, intensivists, ICU and step-down unit nursing staff and hospital administration engaged in this goal was likely critical in favorably reducing ICU utilization and LOS.

Future enhancements and generalizability of this paradigm

At the peak of the December 2020—January 2021 surge, we developed a same-day surgery discharge plan to a local outpatient recovery unit or to home. This protocol was used in only 2 patients but provided proof of concept for same-day brain tumor surgery in select patients, as others have also promoted in carefully selected patients [49, 50]. Another opportunity for further reductions in LOS and cost is with enhanced recovery after surgery (ERAS) protocols [51, 52], which are being implemented at many centers including our own.

Although our brain tumor center treats mostly non-emergent patients (94%) with a high proportion of patients with prior surgery (25%), our pathology mix is similar to that of other centers and trends with national brain tumor demographics [25]. Additionally, while our findings are specific to patients with primary and secondary brain tumors, many of these measures are relevant and applicable to other specialties and are already being implemented in some centers [44, 47, 48, 53, 54].

Study limitations

The major limitation of this study is its retrospective nature. Additionally, the factors we propose that helped achieve less ICU use and shorter hospital LOS are only associations and not necessarily causally linked.

Conclusion

The severe resource limitations imposed by the COVID-19 pandemic provided a unique call to action to further streamline care for brain tumor patients. Layered upon a foundation of minimally invasive surgery, complication avoidance protocols, TIVA and early postoperative imaging, a protocol of more rigorous patient preparation and education, enhanced patient motivation, and care team engagement may have helped further reduce hospital and ICU LOS while maintaining quality outcomes and patient safety. These favorable shifts in brain tumor care are potentially applicable to other surgical specialties.

Supporting information

S1 Data. Data pertaining to the study described in the manuscript.

https://doi.org/10.1371/journal.pone.0254958.s001

(XLSX)

References

  1. 1. Ghafil C, Matsushima K, Ding L, Henry R, Inaba K. Trends in trauma admissions during the COVID-19 pandemic in Los Angeles County, California. JAMA network open. 2021;4(2):e211320–e211320. pmid:33616667
  2. 2. Phua J, Weng L, Ling L, et al. Intensive care management of coronavirus disease 2019 (COVID-19): challenges and recommendations. The Lancet Respiratory Medicine. 2020;8(5):506–517. pmid:32272080
  3. 3. Aziz S, Arabi YM, Alhazzani W, et al. Managing ICU surge during the COVID-19 crisis: rapid guidelines. Intensive care medicine. 2020;46:1303–1325. pmid:32514598
  4. 4. Jean WC, Ironside NT, Sack KD, Felbaum DR, Syed HR. The impact of COVID-19 on neurosurgeons and the strategy for triaging non-emergent operations: a global neurosurgery study. Acta neurochirurgica. 2020;162(6):1229–1240. pmid:32314059
  5. 5. Fontanella MM, De Maria L, Zanin L, et al. Neurosurgical practice during the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic: a worldwide survey. World neurosurgery. 2020;139:e818–e826. pmid:32380337
  6. 6. Khalafallah AM, Jimenez AE, Lee RP, et al. Impact of COVID-19 on an academic neurosurgery department: the Johns Hopkins experience. World neurosurgery. 2020;139:e877–e884. pmid:32461176
  7. 7. Núñez-Velasco S, Mercado-Pimentel R, Ochoa-Plascencia M, et al. Response to SARS-CoV-2 pandemic in a non-COVID-19 designated Latin-American neurosurgery department. World Neurosurgery. 2020;142:506–512. pmid:32438005
  8. 8. Hill CS, Muirhead WR, Vakharia VN, Marcus HJ, Choi D. An exit strategy for resuming nonemergency neurosurgery after Severe Acute Respiratory Syndrome Coronavirus 2: a United Kingdom perspective. World Neurosurgery. 2020;140:e395–e400. pmid:32505658
  9. 9. Dasenbrock HH, Liu KX, Devine CA, et al. Length of hospital stay after craniotomy for tumor: a National Surgical Quality Improvement Program analysis. Neurosurgical focus. 2015;39(6):E12. pmid:26621410
  10. 10. Senders JT, Muskens IS, Cote DJ, et al. Thirty-day outcomes after craniotomy for primary malignant brain tumors: a national surgical quality improvement program analysis. Neurosurgery. 2018;83(6):1249–1259. pmid:29481613
  11. 11. Sheppard JP, Lagman C, Romiyo P, et al. Racial differences in hospital stays among patients undergoing craniotomy for tumour resection at a single academic hospital. Brain tumor research and treatment. 2019;7(2):122. pmid:31686443
  12. 12. Caggiano C, Penn DL, Laws ER Jr. The role of the lumbar drain in endoscopic endonasal skull base surgery: a retrospective analysis of 811 cases. World neurosurgery. 2018;117:e575–e579. pmid:29935316
  13. 13. Vimawala S, Chitguppi C, Reilly E, et al. Predicting prolonged length of stay after endoscopic transsphenoidal surgery for pituitary adenoma. Paper presented at: International forum of allergy & rhinology2020. pmid:32362064
  14. 14. Thakur JD, Corlin A, Mallari RJ, et al. Pituitary adenomas in older adults (≥ 65 years): 90-day outcomes and readmissions: a 10-year endoscopic endonasal surgical experience. Pituitary. 2020:1–13.
  15. 15. Thakur JD, Mallari RJ, Corlin A, et al. Minimally invasive surgical treatment of intracranial meningiomas in elderly patients (≥ 65 years): outcomes, readmissions, and tumor control. Neurosurgical Focus. 2020;49(4):E17. pmid:33002879
  16. 16. Conger A, Zhao F, Wang X, et al. Evolution of the graded repair of CSF leaks and skull base defects in endonasal endoscopic tumor surgery: trends in repair failure and meningitis rates in 509 patients. Journal of neurosurgery. 2018;130(3):861–875. pmid:29749920
  17. 17. Ansari SF, Eisenberg A, Rodriguez A, Barkhoudarian G, Kelly DF. The supraorbital eyebrow craniotomy for intra-and extra-axial brain tumors: a single-center series and technique modification. Operative Neurosurgery. 2020;19(6):667–677. pmid:32745195
  18. 18. Barkhoudarian G, Palejwala SK, Ansari S, et al. Rathke’s cleft cysts: a 6-year experience of surgery vs. observation with comparative volumetric analysis. Pituitary. 2019;22(4):362–371. pmid:31016554
  19. 19. Fatemi N, Dusick JR, de Paiva Neto MA, Malkasian D, Kelly DF. Endonasal versus supraorbital keyhole removal of craniopharyngiomas and tuberculum sellae meningiomas. Operative Neurosurgery. 2009;64(suppl_5):ons269–ons287. pmid:19287324
  20. 20. Mallari RJ, Thakur JD, Rhee J, et al. Endoscopic Endonasal and Supraorbital Removal of Tuberculum Sellae Meningiomas: Anatomical Guides and Operative Nuances for Keyhole Approach Selection. Operative neurosurgery. 2021.
  21. 21. Mooney MA, Yoon S, Cole T, et al. Cost transparency in neurosurgery: a single-institution analysis of patient out-of-pocket spending in 13 673 consecutive neurosurgery cases. Neurosurgery. 2019;84(6):1280–1289. pmid:29767766
  22. 22. Neville IS, Ureña FM, Quadros DG, et al. Safety and costs analysis of early hospital discharge after brain tumour surgery: a pilot study. BMC surgery. 2020;20:1–10. pmid:31898499
  23. 23. Regenbogen SE, Cain-Nielsen AH, Norton EC, Chen LM, Birkmeyer JD, Skinner JS. Costs and consequences of early hospital discharge after major inpatient surgery in older adults. JAMA surgery. 2017;152(5):e170123–e170123. pmid:28329352
  24. 24. McLaughlin N, Martin NA, Upadhyaya P, et al. Assessing the cost of contemporary pituitary care. Neurosurgical focus. 2014;37(5):E7. pmid:26223274
  25. 25. Ostrom QT, Patil N, Cioffi G, Waite K, Kruchko C, Barnholtz-Sloan JS. CBTRUS statistical report: Primary brain and other central nervous system tumors diagnosed in the United States in 2013–2017. Neuro-oncology. 2020;22(Supplement_1):iv1–iv96.
  26. 26. Karsy M, Bowers CA, Scoville J, et al. Evaluation of complications and costs during overlapping transsphenoidal surgery in the treatment of pituitary adenoma. Neurosurgery. 2019;84(5):1104–1111. pmid:29897572
  27. 27. Guan J, Karsy M, Brock AA, Couldwell WT, Schmidt RH. Overlapping surgery: a review of the controversy, the evidence, and future directions. Neurosurgery. 2017;64(CN_suppl_1):110–113. pmid:28899036
  28. 28. Miura Y, Kamiya K, Kanazawa K, et al. Superior recovery profiles of propofol-based regimen as compared to isoflurane-based regimen in patients undergoing craniotomy for primary brain tumor excision: a retrospective study. Journal of anesthesia. 2012;26(5):721–727. pmid:22581143
  29. 29. Ishii K, Makita T, Yamashita H, et al. Total intravenous anesthesia with propofol is associated with a lower rate of postoperative delirium in comparison with sevoflurane anesthesia in elderly patients. Journal of clinical anesthesia. 2016;33:428–431. pmid:27555205
  30. 30. Wong SSC, Chan WS, Irwin MG, Cheung CW. Total intravenous anesthesia (TIVA) with propofol for acute postoperative pain: a scoping review of randomized controlled trials. Asian Journal of Anesthesiology. 2020;58(3):79–93. pmid:33176410
  31. 31. Kelly DF, Griffiths CF, Takasumi Y, Rhee J, Barkhoudarian G, Krauss HR. Role of endoscopic skull base and keyhole surgery for pituitary and parasellar tumors impacting vision. Journal of Neuro-ophthalmology. 2015;35(4):335–341. pmid:26576016
  32. 32. Dusick JR, Esposito F, Malkasian D, Kelly DF. Avoidance of carotid artery injuries in transsphenoidal surgery with the Doppler probe and micro-hook blades. Operative Neurosurgery. 2007;60(suppl_4):ONS-322–ONS-329. pmid:17415170
  33. 33. Sivakumar W, Barkhoudarian G, Lobo BM, et al. Strategy and Technique of Endonasal Endoscopic Bony Decompression and Selective Tumor Removal in Symptomatic Skull Base Meningiomas of the Cavernous Sinus and Meckel’s Cave. World neurosurgery. 2019;131:e12–e22. pmid:31226453
  34. 34. Fatemi N, Dusick JR, Mattozo C, et al. Pituitary hormonal loss and recovery after transsphenoidal adenoma removal. Neurosurgery. 2008;63(4):709–719. pmid:18981881
  35. 35. Dusick JR, Fatemi N, Mattozo C, et al. Pituitary function after endonasal surgery for nonadenomatous parasellar tumors: Rathke’s cleft cysts, craniopharyngiomas, and meningiomas. Surgical neurology. 2008;70(5):482–490. pmid:18482750
  36. 36. Badenes R, Prisco L, Maruenda A, Taccone FS. Criteria for Intensive Care admission and monitoring after elective craniotomy. Current Opinion in Anesthesiology. 2017;30(5):540–545. pmid:28682828
  37. 37. Florman JE, Cushing D, Keller LA, Rughani AI. A protocol for postoperative admission of elective craniotomy patients to a non-ICU or step-down setting. Journal of neurosurgery. 2017;127(6):1392–1397. pmid:28298034
  38. 38. de Almeida CC, Boone MD, Laviv Y, Kasper BS, Chen CC, Kasper EM. The utility of routine intensive care admission for patients undergoing intracranial neurosurgical procedures: a systematic review. Neurocritical care. 2018;28(1):35–42. pmid:28808901
  39. 39. Beer-Furlan A, Priddy BH, Jamshidi AO, et al. Improving Function in Cavernous Sinus Meningiomas: A Modern Treatment Algorithm. Frontiers in Neurology. 2020;11. pmid:32793095
  40. 40. Gozal YM, Alzhrani G, Abou-Al-Shaar H, Azab MA, Walsh MT, Couldwell WT. Outcomes of decompressive surgery for cavernous sinus meningiomas: long-term follow-up in 50 patients. Journal of neurosurgery. 2019;132(2):380–387. pmid:30771770
  41. 41. Lan Q, Sughrue M, Hopf NJ, et al. International expert consensus statement about methods and indications for keyhole microneurosurgery from International Society on Minimally Invasive Neurosurgery. Neurosurgical review. 2019:1–17. pmid:31754934
  42. 42. Cinotti R, Bruder N, Srairi M, et al. Prediction score for postoperative neurologic complications after brain tumor craniotomy: a multicenter observational study. Anesthesiology. 2018;129(6):1111–1120. pmid:30234580
  43. 43. Kommers I, Ackermans L, Ardon H, et al. Between-hospital variation in rates of complications and decline of patient performance after glioblastoma surgery in the dutch Quality Registry Neuro Surgery. Journal of Neuro-Oncology. 2021:1–10. pmid:33511509
  44. 44. Richardson AM, McCarthy DJ, Sandhu J, et al. Predictors of successful discharge of patients on postoperative day 1 after craniotomy for brain tumor. World neurosurgery. 2019;126:e869–e877. pmid:30862575
  45. 45. Nunno A, Li Y, Pieters TA, et al. Risk factors and associated complications of symptomatic venous thromboembolism in patients with craniotomy for meningioma. World neurosurgery. 2019;122:e1505–e1510. pmid:30468929
  46. 46. Fluss R, Kobets AJ, Inocencio JF, et al. The incidence of venous thromboembolism following surgical resection of intracranial and intraspinal meningioma. A systematic review and retrospective study. Clinical Neurology and Neurosurgery. 2021:106460. pmid:33444944
  47. 47. Nettleton J, Jelski J, Ahmad A. Reducing readmissions and improving patient experience following urological surgery, through early telephone follow-up. BMJ open quality. 2020;9(2):e000533. pmid:32303500
  48. 48. Jalilvand A, Suzo A, Hornor M, et al. Impact of care coaching on hospital length of stay, readmission rates, postdischarge phone calls, and patient satisfaction after bariatric surgery. Surgery for Obesity and Related Diseases. 2016;12(9):1737–1745. pmid:27320222
  49. 49. Marigil M, Bernstein M. Outpatient neurosurgery in neuro-oncology. Neurosurgical focus. 2018;44(6):E19. pmid:29852775
  50. 50. Venkatraghavan L, Bharadwaj S, Au K, Bernstein M, Manninen P. Same-day discharge after craniotomy for supratentorial tumour surgery: a retrospective observational single-centre study. Canadian Journal of Anesthesia/Journal canadien d’anesthésie. 2016;63(11):1245–1257. pmid:27510463
  51. 51. Hughes MA, Culpin E, Darley R, et al. Enhanced recovery and accelerated discharge after endoscopic transsphenoidal pituitary surgery: safety, patient feedback, and cost implications. Acta neurochirurgica. 2020:1–6.
  52. 52. Pecorelli N, Nobile S, Partelli S, et al. Enhanced recovery pathways in pancreatic surgery: state of the art. World journal of gastroenterology. 2016;22(28):6456. pmid:27605881
  53. 53. Díaz F, de La Peña E, Hernández V, et al. Optimization of an early discharge program after laparoscopic radical prostatectomy. Actas Urológicas Españolas (English Edition). 2014;38(6):355–360. pmid:24529540
  54. 54. Mt Laan, Roelofs S, Van Huet I, Adang EM, Bartels RH. Selective intensive care unit admission after adult supratentorial tumor craniotomy: complications, length of stay, and costs. Neurosurgery. 2020;86(1):E54–E59. pmid:31541243