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Article

Clinical Outcomes in the Second versus First Pandemic Wave in Italy: Impact of Hospital Changes and Reorganization

by Antonio Voza 1,2,*, Antonio Desai 1,2, Sabino Luzzi 3,4, Alice Giotta Lucifero 3, Elena Azzolini 2,5, Maria Kogan 1, Giulia Goretti 1, Daniele Piovani 2, Stefanos Bonovas 2, Giovanni Angelotti 6, Victor Savevski 6, Alessio Aghemo 2,7, Massimiliano Greco 2,8, Elena Costantini 8, Ana Lleo 2,7, Claudio Angelini 9, Mauro Giordano 10, Salvatore Badalamenti 9 and Maurizio Cecconi 2,8
1
Emergency Department, IRCCS Humanitas Research Hospital, Via Manzoni 56, 20089 Milan, Italy
2
Department of Biomedical Sciences, Humanitas University, Via Rita Levi Montalcini 4, 20090 Milan, Italy
3
Neurosurgery Unit, Department of Clinical-Surgical, Diagnostic and Pediatric Sciences, University of Pavia, 27100 Pavia, Italy
4
Neurosurgery Unit, Department of Surgical Sciences, Fondazione IRCCS Policlinico San Matteo, 27100 Pavia, Italy
5
Health Directorate, IRCCS Humanitas Research Hospital, Via Manzoni 56, 20089 Milan, Italy
6
Artificial Intelligence Center, IRCCS Humanitas Research Hospital, Via Manzoni 56, 20089 Milan, Italy
7
Department of Internal Medicine and Hepatology, IRCCS Humanitas Research Hospital, Via Manzoni 56, 20089 Milan, Italy
8
Department and Anaesthesia and Intensive Care, IRCCS Humanitas Research Hospital, Via Manzoni 56, 20089 Milan, Italy
9
Department of Nephrology, IRCCS Humanitas Research Hospital, via Manzoni 56, 20089 Milan, Italy
10
Department of Advanced Medical and Surgical Sciences, University of Campania “L. Vanvitelli”, 81100 Naples, Italy
*
Author to whom correspondence should be addressed.
Submission received: 1 September 2021 / Revised: 29 September 2021 / Accepted: 4 October 2021 / Published: 8 October 2021

Abstract

:
The region of Lombardy was the epicenter of the COVID-19 outbreak in Italy. Emergency Hospital 19 (EH19) was built in the Milan metropolitan area during the pandemic’s second wave as a facility of Humanitas Clinical and Research Center (HCRC). The present study aimed to assess whether the implementation of EH19 was effective in improving the quality of care of COVID-19 patients during the second wave compared with the first one. The demographics, mortality rate, and in-hospital length of stay (LOS) of two groups of patients were compared: the study group involved patients admitted at HCRC and managed in EH19 during the second pandemic wave, while the control group included patients managed exclusively at HCRC throughout the first wave. The study and control group included 903 (56.7%) and 690 (43.3%) patients, respectively. The study group was six years older on average and had more pre-existing comorbidities. EH19 was associated with a decrease in the intensive care unit admission rate (16.9% vs. 8.75%, p < 0.001), and an equal decrease in invasive oxygen therapy (3.8% vs. 0.23%, p < 0.001). Crude mortality was similar but overlap propensity score weighting revealed a trend toward a potential small decrease. The adjusted difference in LOS was not significant. The implementation of an additional COVID-19 hospital facility was effective in improving the overall quality of care of COVID-19 patients during the first wave of the pandemic when compared with the second. Further studies are necessary to validate the suggested approach.

1. Introduction

The Coronavirus Disease 2019 (COVID-19) outbreak had a significant impact on the global health system in Italy and worldwide, as a pandemic of this scale had not been observed in the past 100 years. The Lombardy region, in northern Italy, was the epicenter of the pandemic on the Italian national territory and one of the most afflicted areas worldwide [1,2,3,4,5]. Herein, the irrepressible spread of the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) infection created the immediate necessity for logistic, organizational, and management adjustments within most hospitals, which were caught unprepared for an event without precedent in the national health system [6,7,8,9,10,11,12,13,14]. Several public and private hospitals responded to the increased demand by internal rearrangements of their routine daily activities. Some hospitals built extra capacity in preparation for a second wave. Our hospital built a new hospital facility on the hospital campus in 8 weeks intending to increase capacity and optimize infection containment in the hospital. To our knowledge, this is the first European COVID-19 hospital built in response to the pandemic.
Furthermore, the description of these rare adjustments at the hospital level still lacks in the literature, in terms of their effects on overall mortality and in-hospital length of stay (LOS). After the first wave of COVID-19, a hospital facility was strategically built in southern Milan by Humanitas Clinical and Research Center (ICH), a private hospital contracted to the National Health System and has a vast catchment area, to face the second and potential following waves. The new hospital facility, called Humanitas Emergency Hospital 19 (EH19), is in a different urban area from the ICH. Inaugurated on 27 July 2020, EH19 was equipped with 17 inpatient rooms, a dedicated emergency department, a radiology unit, an operating room, and an intensive care unit (ICU) consisting of 12 beds. Moreover, a high-dependency unit, in charge of the Emergency Department team, equipped with eight beds was also built. These eight beds had the potential to be used as ICU beds in case of necessity during a surge. The rationale of EH19 was to provide logistic support to the multidisciplinary team of specialists engaged in the treatment of COVID-19 patients and simultaneously facilitate an immunological research program for the cure of SARS-CoV-2 infection. The key resident teams were the Emergency Medicine team and the ICU team. Other teams were available on a consultation basis and deployed by the nearby main hospital. These teams worked closely together to ensure patients received the best care and evaluate each decision on a case-by-case basis.
From an operational standpoint, EH19 was inspired by the evidence-based and worldwide accepted “Lean method”, which was practically realized through a stepwise process now known by the term “Lean-ing” [7,15,16].
The present study aimed to assess whether the implementation of an additional COVID-19 facility in a tertiary Milan hospital, such as EH19, and its use of Lean-ing were effective in improving the overall quality of care of patients with SARS-CoV-2 infection in the second wave of COVID-19 when compared with the first one.

2. Methods

2.1. Study Design

The present single-center retrospective cohort study was conducted at the Humanitas Clinical and Research Center, Milan, Lombardy Region, northern Italy, and obtained the approval of the local ethical committee, in agreement with the principles of the Helsinki declaration [17].
All the patients admitted to the Emergency Department (ED) from 1 March 2020, to 1 February 2021, were derived from an electronic database. Only patients who underwent testing with a nasopharyngeal swab at admission due to a suspected diagnosis of COVID-19 were selected. Patients were divided into two groups based on the date of the admission and intra- and inter-hospital management protocol, as depicted below.
The first group included patients who were admitted at HCRC between 1 March 2020, and 31 May 2020; at the time the EH19 hospital facility was still unavailable. Patients who presented with COVID-19 symptoms at triage level were transferred to a grey area in which pulse oximetry and nasopharyngeal swab were performed. The peripheral oxygen saturation (SpO2) guided patient allocation to a high-, medium-, or low-intensity area, whereas, in the case of positivity for SARS-CoV-2 infection ascertained with polymerase chain reaction, the patients were assigned to a COVID-19 ICU or ward in the same hospital. The second group was comprised of the patients admitted at HCRC from 1 October 2020, to 1 February 2021. It was allocated based on the same model, but patients were transferred to and managed in EH19 if suspected of SARS-CoV-2 infection. From a temporal point of view, the groups were samples of the first and second waves of COVID-19, in northern Italy, respectively. Diagrams 1 and 2 summarize the management algorithms used in groups 1 and 2, respectively (Figure 1 and Figure 2). In both groups, the age, gender, signs and symptoms at hospital admission, comorbidities, blood routine, infection-related biomarkers, blood biochemistry, and coagulation profile data were collected. To assess the overall quality of care of COVID-19 patients between the first and second wave, data were compared regarding the mortality rate and in-hospital LOS.

2.2. Statistical Analysis

Descriptive statistics included means with standard deviations (SD) and medians with interquartile ranges (IQR) for continuous variables and counts (percentages) for categorical variables. For the univariable comparison of demographic, clinical, and laboratory variables among the two groups (first vs. second wave), a non-parametric Wilcoxon rank-sum test was used for numeric variables, and a χ2 test was used for categorical variables. A propensity score belonging to the first or second wave of COVID-19 was estimated from a multivariable logistic regression model including patient age, gender, presence of hypertension, cardiovascular diseases, diabetes, malignancies, neurological diseases, respiratory diseases, and chronic kidney diseases. Considering that age and underlying comorbidities are strongly associated with mortality and LOS, and that they were unbalanced between the first and second waves of COVID-19 patients, an overlap propensity score weighting was performed to address potential confounding factors [18,19].
The overlap propensity score-weighted logistic regression model investigated the in-hospital mortality and LOS in the patients of groups 1 and 2. As the distribution of the LOS was severely skewed, including the residuals deriving from the multivariable regression, we logged this outcome variable to achieve normalization. Stata 15.0 software (Stata Corp., College Station, TX, USA) and R (https://www.r-project.org accessed on 1 February 2021) were used to analyze the data. p-values < 0.05 were considered statistically significant. All tests were two-sided.

3. Results

The data set consisted of 1593 COVID-19 patients with complete follow-ups who were admitted to the Humanitas Research Hospital, Italy.
The mean (SD) age was 69.0 (14.6) years (median 71, IQR: 59–80), and 64.2% were males. A substantial proportion of patients was affected by at least one comorbidity at baseline (75.9%), including, in particular, hypertension (50.7%), cardiovascular diseases (26.6%), diabetes (19.4%), malignancy (19.4%), neurological diseases (17.3%), respiratory diseases (14.4%) and chronic kidney diseases (9.4%). Among these hospitalized patients, 10.1% received continuous positive airway pressure therapy (CPAP), 12.3% were admitted to the intensive care unit, and 24.0% died. The mean (SD) LOS was 16.2 (15.6) days (median 11, IQR: 7–19). The mean LOS during the first wave were 12.3 days and 18.4 days in the emergency ward and ICU, respectively. On the contrary, during the second wave, the mean LOS in the emergency ward was 14.1 days, and 11.6 in the ICU.

3.1. Patients’ Characteristics and Interventions Received in the First and Second Wave

Of the 1593 included in the analyses, 690 (43.3%) were admitted during the first wave and 903 (56.7%) during the second wave. We reported baseline characteristics at the admission of the two cohorts of patients including demographic, clinical, and laboratory findings in Table 1. Patients in the second wave were a median of six years older and had significantly more pre-existing comorbidities than those hospitalized in the first wave. Additionally, the proportion of women was higher in the second wave. Laboratory characteristics confirmed the substantial difference between these two cohorts of patients with significantly different values in lymphocytes, eosinophils, hemoglobin, interleukin-6, serum ferritin, c-reactive protein, gamma-glutamyl transpeptidase, creatine kinase, triglycerides, international normalized ratio, and fibrinogen, Table 1. The new internal organization resulted in a lower proportion of patients admitted to the ICU in the second wave (first vs. second wave, 16.9%, and 8.75%, p < 0.001) mostly substituted by a sub-intensive type of care. The proportion of patients receiving invasive oxygen therapy (3.8% vs. 0.23%, p < 0.001) was significantly lower in the second wave, while the proportion of those receiving other types of oxygen support was significantly higher (54.3% vs. 63.1%, p = 0.001). The use of CPAP was not significantly different between the two waves (11.9% vs. 9.1%, p = 0.189).

3.2. Unadjusted and Overlap Propensity Scores Weighted Patients’ Outcomes

The crude mortality was 22.6% in the first and 25.1% in the second wave, with no statistically significant difference (second vs. the first wave, crude RR 1.11; 95% CI, 0.93–1.32; p = 0.24). After overlap propensity score weighting, the adjusted mortality was 24.9% in patients admitted during the first wave and 21.4% in those admitted during the second wave (second vs. the first wave, adjusted RR 0.86; 95% CI, 0.73–1.02; p = 0.082), showing suggestive evidence of a potential small decrease in mortality, Table 2.
The unadjusted median length of stay was 10 days (IQR: 7–17) during the first wave and 12 days (IQR: 7–22) during the second wave, with a statistically significantly longer stay in the second wave (Wilcoxon rank-sum test; p = 0.023). After overlap propensity score weighting, the adjusted difference in length of stay between the two waves was not statistically significant (p = 0.28).

4. Discussion

The present study describes the organizational aspects of EH19 as a way to better manage the COVID-19 pandemic. According to our experience, EH19 was very effective in facing the first and second waves as evidenced by a decrease in mortality and LOS, ultimately improving the overall quality of care. Based on data about global COVID-19 cases by John Hopkins CSSE updated at the end of the first wave, Italy was the third most-affected country of the world, only preceded by the US and Spain, accounting for 159,516 confirmed cases and 20,465 deaths [20]. Overall, the Lombardy region was the epicenter of the Italian pandemic, with 37.4% of total cases registered in the national territory and more than 50% of the total number of deaths (http://www.salute.gov.it accessed on 1 March 2021) [21,22,23].
The large number of cases in northern Italy overwhelmed the health care system and created a demand for an imminent change on the containment of the infection. After the implementation of EH19 and the Lean operational algorithm, the adjusted mortality rate was reduced, despite a seven-year increase in median patients’ age and higher comorbidity rate in the second wave. Meanwhile, on the contrary, the need for HFO2 support increased. Moreover, the average in-hospital LOS was not prolonged in the second wave, resulting in a substantial advantage in terms of cost-effectiveness. These data may be explained by the overall improvement in the quality of care.
As reported by several authors, the implementation of an additional hospital facility has a primary role in centralizing the professional figures specifically trained in the cure of COVID-19 patients [24,25,26]. COVID-19-dedicated hospitals have been proven to be effective in flattening the infection curve and slowing the spread of the virus worldwide—these being the major strengths of these facilities [24,25,26,27]. It should be mentioned that the ICU admission rate decreased in group 2 (16.9% vs. 8.75%, p < 0.001).
This could also be explained by considering that, in our newly born facility, besides the ordinary ward beds and the ICU beds, we had eight high-dependency unit beds at our disposal that could be easily converted to ICU or ordinary ward beds according to our needs with maximal flexibility.
The main sequelae of the COVID-19 spread included the alarming collapse of the clinic caseload and the consequent delays of elective medical and surgical activity. Roifman and colleagues recently stressed these concerns regarding the significant reduction in optimal cardiovascular health care delivery in Canada, basically consisting of a substantial deferral of elective cardiovascular procedures [28]. The same alarm has been reported for cardiac surgery [29], and as many apprehensions do exist for specialties other than the cardiovascular field, these reports highlight a negative trend in health care delivery, even in critical care [30,31,32,33,34]. A further advantage of the implementation of a satellite hospital dedicated to COVID-19 patients is that it aids in the decongestion of the main hospital, allowing the theoretical elective caseload to remain unaffected. EH19 also facilitated an environment where an in-depth anamnestic investigation of the patients’ medical history, with a focus on comorbidities, was possible. This could explain the higher comorbidity rate among patients in the second wave when compared to the first. In other words, it avoids delaying the care of time-dependent pathologies and chronic diseases. Furthermore, due to ICH Cancer Center, patients with malignancies, who during the first wave of COVID-19 had been shielding inside their homes, have recently been accessing hospital care at an increasing rate, which allows for the continuity of treatment. This can partially explain the above-mentioned phenomenon.
Ferrara rightly emphasized the urgent need for a major reorganization of health care systems, in Italy and in other parts of the world, to allow the management of already anticipated waves as well as the continuity of the vaccination campaign from a medical and social point of view [35]. In line with this aim, the tactical build of COVID-19 facilities such as EH19 perfectly fits the aforementioned necessities. Additionally, strategic operational algorithms are mandatory, today and in the future, to optimize and further improve the quality of care of both COVID-19 and non-COVID-19 patients. The Lean model was adopted by our hospital, mainly because of its recognized high reliability, feasibility, and effectiveness [7,15,16,36,37,38,39]. It was reported as “an integrated socio-technical system whose main objective is to eliminate waste by concurrently reducing or minimizing supplier, customer, and internal variability” [40]. The motivating principles of this operative model make it an optimal choice for the management of the COVID-19 outbreak. It allowed for the successful screening of a large number of patients and for their proper allocation on Emergency Department arrival. There are clear limitations of this study due to its retrospective nature and the relatively small sample size. All of these limitations are common to other studies and are also caused by the exceptional situation generated by the SARS-CoV-2 pandemic.

Limitations

The present study has some limitations mainly due to its retrospective nature, the relatively limited number of patients managed, and the lack of randomization. Lastly, further limitations are the advances in treatment guidelines, which occurred in the second wave. The strengthening of target therapies and interventional strategies against COVID-19 could influence the LOS, ICU admission, and overall mortality during the second wave compared with the first one.

5. Conclusions

Limited to the experience of a tertiary hospital in northern Italy, the implementation of an additional COVID-19 hospital facility and a strategic operative protocol were effective in the creation of logistic and organizational support designed to improve the overall quality of care of COVID-19 patients during the first wave of the pandemic when compared with the second.
The Lean model resulted in health care optimization through an improvement of the operative flows and the prevention of overcrowding in the ED.
Further studies are necessary to validate the presented approach relative to the containment of the SARS-CoV-2 infection, spreading, flattening of the curves, and avoidance of delays in the cure of non-COVID-19 patients.

6. Keypoints

The Lombardy region in northern Italy was the epicenter of the Coronavirus Disease 2019 (COVID-19) outbreak in the Italian national territory and one of the most afflicted areas worldwide.
The pandemic triggered the urgent need for logistic, organizational, and management adjustments within most hospitals.
Humanitas Clinical and Research Center built a new hospital facility, Emergency Hospital 19 (EH19), during the second wave of the pandemic to increase capacity and optimize infection containment.
The implementation of an additional COVID-19 hospital facility was effective in improving the overall quality of care during the first wave of the pandemic compared with the second wave.

Author Contributions

Conceptualization, A.V., A.D., S.L. and A.G.L.; methodology, E.A., M.K. and G.G.; validation, A.V., S.L. and S.B. (Stefanos Bonovas); formal analysis, D.P., S.B. (Stefanos Bonovas) and G.A.; investigation, V.S., A.A. and M.G. (Mauro Giordano); resources, A.V., E.C., A.L. and C.A.; data curation, A.D., V.S., G.A., A.A. and A.G.L.; writing—original draft preparation, A.V. and S.L.; writing—review and editing, S.L., M.G. (Massimiliano Greco), S.B. (Salvatore Badalamenti) and M.C.; visualization, A.V. and M.C.; supervision, A.V., M.C., V.S., S.B. (Stefanos Bonovas) and S.L.; project administration, A.V. and M.C. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

All procedures performed in the study were in accordance with the ethical standards of the institution and with the 1964 Helsinki Declaration and its later amendments or comparable ethical standards.

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Patient and Public Involvement

It was not appropriate or possible to involve patients or the public.

Data Availability Statement

All data are included in the main text.

Conflicts of Interest

All authors report no conflict of interest relevant to this article.

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Figure 1. Operational algorithm used during the first wave of COVID-19.
Figure 1. Operational algorithm used during the first wave of COVID-19.
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Figure 2. Operational algorithm used during the second wave of COVID-19.
Figure 2. Operational algorithm used during the second wave of COVID-19.
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Table 1. Demographic, clinical, and laboratory characteristics of hospitalized COVID-19 patients (n = 1593).
Table 1. Demographic, clinical, and laboratory characteristics of hospitalized COVID-19 patients (n = 1593).
First Wave (n = 690)Second Wave (n = 903)p-Value
Mean ± SD; Median (IQR) or n (%)Mean ± SD; Median (IQR) or n (%)
Demographic Characteristics
Age (years)66.21 ± 14.44; 67.00 (56.00–77.00)
(n = 690)
71.17 ± 14.30; 73.00 (61.00–82.00)
(n = 903)
<0.01
≥65296 (42.9)
(n = 690)
272 (30.1)
(n = 903)
<65394 (57.1)
(n = 690)
631 (69.9)
(n = 903)
Gender 0.006
Female221 (32.0)
(n = 690)
350 (38.8)
(n = 903)
Male469 (68.0)
(n = 690)
553 (61.2)
(n = 903)
Clinical Characteristics
Signs and Symptoms at Admission
Systolic blood pressure (mmHg)134.55 ± 156.80; 125.79 (116.88–138.17)
(n = 612)
177.25 ± 1414.32; 127.00 (117.50–137.25)
(n = 821)
0.415
Pulse (beats per minute)84.35 ± 11.86; 83.79 (76.00–91.73)
(n = 612)
84.35 ± 27.40; 81.67 (74.20–91.05)
(n = 823)
0.012
Respiratory rate (breaths per minute)19.15 ± 3.22; 18.33 (17.50–20.00)
(n = 586)
18.87 ± 3.46; 18.00 (17.40–19.50)
(n = 769)
0.076
Pulse oximetry (%)93.51 ± 11.66; 95.33 (92.00–97.00)
(n = 550)
92.33 ± 6.48; 94.00 (90.00–96.57)
(n = 765)
< 0.01
Glasgow coma scale14.75 ± 1.38; 15.00 (15.00–15.00)
(n = 615)
14.83 ± 0.86; 15.00 (15.00–15.00)
(n = 820)
0.140
Comorbid Conditions
Any comorbidity482 (70.6)
(n = 683)
722 (80.0)
(n = 903)
<0.01
Hypertension321 (47.1)
(n = 682)
482 (53.5)
(n = 901)
0.013
Cardiovascular diseases168 (24.6)
(n = 683)
252 (28.1)
(n = 898)
0.137
Diabetes147 (21.5)
(n = 683)
160 (17.8)
(n = 899)
0.100
Malignancy113 (16.5)
(n = 683)
194 (21.6)
(n = 899)
0.015
Neurological diseases97 (14.3)
(n = 679)
176 (19.6)
(n = 897)
0.007
Respiratory diseases92 (13.5)
(n = 683)
136 (15.1)
(n = 900)
0.396
Chronic kidney diseases54 (7.9)
(n = 681)
94 (10.4)
(n = 900)
0.107
Laboratory Characteristics
Blood Routine
White blood cells (×10⁹/L; normal range 4.0–10.0)8.45 ± 7.33; 6.89 (5.22–10.08)
(n = 638)
8.83 ± 12.85; 7.40 (5.39–10.12)
(n = 866)
0.998
Eosinophils (×10⁹/L; normal range 0.0–0.5)0.03 ± 0.09; 0.00 (0.00–0.00)
(n = 650)
0.02 ± 0.06; 0.00 (0.00–0.00)
(n = 881)
0.027
Monocytes (×10⁹/L; normal range 0.2–0.8)0.63 ± 0.65; 0.50 (0.40–0.80)
(n = 650)
0.70 ± 2.17; 0.50 (0.40–0.80)
(n = 881)
0.059
Basophils (×10⁹/L; normal range 0.0–0.1)0.01 ± 0.04; 0.00 (0.00–0.00)
(n = 650)
0.02 ± 0.04; 0.00 (0.00–0.00)
(n = 881)
0.330
Lymphocytes (×10⁹/L; normal range 1.0–4.0)1.31 ± 5.31; 0.90 (0.60–1.30)
(n = 650)
1.40 ± 11.12; 0.90 (0.60–1.20)
(n = 881)
<0.01
Platelets (×10⁹/L; normal range 150–400)228.09 ± 105.68; 212.00 (158.00–275.50)
(n = 651)
228.83 ± 106.86; 211.00 (161.00–277.00)
(n=881)
0.338
Hemoglobin (g/dL; normal range 13.0–16.0)13.44 ± 2.04; 13.70 (12.30–14.80)
(n = 651)
13.22 ± 2.13; 13.40 (12.00–14.60)
(n = 881)
0.001
Infection-Related Biomarkers
Procalcitonin (ng/mL; normal range 0.05–0.5)0.89 ± 3.23; 0.21 (0.10–0.50)
(n = 550)
2.33 ± 19.30; 0.20 (0.10–0.54)
(n = 695)
0.312
Interleukin–6 (pg/mL; normal range < 6.4)86.49 ± 148.17; 45.00 (19.00–93.00)
(n = 453)
72.37 ± 152.93; 40.00 (19.00–76.25)
(n = 772)
<0.01
Serum ferritin (ng/mL; normal range 23.9–336.2)740.96 ± 799.50; 500.40 (209.00–962.97)
(n = 570)
704.97 ± 905.69; 456.35 (215.55–884.62)
(n = 800)
0.002
C-reactive protein (mg/dL; normal range < 1.0)10.23 ± 8.98; 8.17 (2.80–15.01)
(n = 615)
9.49 ± 8.17; 8.34 (2.64–13.34)
(n = 848)
0.020
Blood Biochemistry
Alanine aminotransferase (U/L; normal range < 51)38.88 ± 45.86; 27.00 (18.00–44.00)
(n = 624)
40.69 ± 60.82; 26.00 (17.00–45.00)
(n = 846)
0.046
Aspartate aminotransferase (U/L; normal range < 51)48.15 ± 49.07; 36.00 (25.00–54.00)
(n = 567)
48.52 ± 56.80; 35.00 (25.00–51.00)
(n = 764)
0.410
Gamma-glutamyl transpeptidase (U/L; normal range < 55)68.57 ±78.67; 43.00 (22.00–81.25)
n = 576)
80.35 ± 133.35; 45.00 (25.00–85.00)
(n = 679)
<0.01
Alkaline phosphatase (U/L; normal range 40–150)101.29 ± 120.89; 80.00 (63.00–110.00)
(n = 562)
103.99 ± 71.22; 85.00 (67.00–115.00)
(n = 773)
0.316
Total bilirubin (mg/dL; normal range 0.3–1.2)0.79 ± 0.75; 0.70 (0.50–0.90)
(n = 571)
0.86 ± 1.08; 0.70 (0.50–0.90)
(n = 762)
0.283
Direct bilirubin (mg/dL; normal range < 0.3)0.27 ± 0.46; 0.20 (0.10–0.30)
(n = 507)
0.30 ± 0.74; 0.20 (0.10–0.30)
(n = 660)
0.103
Indirect bilirubin (mg/dL; normal range 0.05–1.10)0.63 ± 0.39; 0.50 (0.40–0.70)
(n = 546)
0.62 ± 0.62; 0.50 (0.40–0.70)
(n = 652)
0.431
Serum creatinine (mg/dL; normal range 0.67–1.17)1.19 ± 1.05; 0.93 (0.75–1.21)
(n = 627)
1.25 ± 1.10; 0.96 (0.78–1.30)
(n = 853)
0.866
Creatine kinase (U/L; normal range < 172)222.78 ± 454.01; 101.00 (56.00–203.00)
(n = 623)
179.11 ± 313.68; 87.00 (49.00–161.75)
(n = 846)
<0.01
Lactate dehydrogenase (U/L; normal range < 248)363.22 ± 205.89; 314.50 (240.00–416.25)
(n = 558)
358.71 ± 256.98; 312.00 (243.00–416.50)
(n = 756)
0.284
Triglycerides (mg/dL; normal range 10–150)139.10 ± 88.36; 120.00 (92.00–157.00)
(n = 540)
137.10 ± 80.02; 120.00 (94.00–162.00)
(n = 773)
0.009
Coagulation Function and Other Biomarkers
International Normalized Ratio (normal range 0.9–1.18)1.24 ± 0.65; 1.11 (1.05–1.22)
(n = 612)
1.16 ± 0.49; 1.08 (1.02–1.16)
(n = 821)
< 0.01
Fibrinogen (mg/dL; normal range 160–400)561.69 ± 183.65; 542.00 (436.00–665.00)
(n = 577)
597.48 ± 196.11; 586.00 (451.00– 718.75)
(n = 782)
0.024
D-dimer (μg/mL; normal range 0.2–0.35)2.02 ± 5.92; 0.54 (0.33–1.00)
(n = 502)
1.86 ± 5.69; 0.46 (0.30–0.98)
(n =646)
0.455
Troponin-I (ng/L; normal range 1–19.8)129.92± 905.77; 10.20(4.30–28.00)
(n = 558)
107.68 ± 721.67; 11.80 (6.60–28.20)
(n =829)
0.307
Table 2. Overlap propensity score–weighted characteristics and in-hospital death among patients hospitalized for COVID-19 during the first or the second epidemic wave.
Table 2. Overlap propensity score–weighted characteristics and in-hospital death among patients hospitalized for COVID-19 during the first or the second epidemic wave.
First Wave aSecond Wave a
Age (years)68.268.2
Male (%)65.165.1
Hypertension (%)49.549.5
Cardiovascular diseases (%)25.825.8
Diabetes (%)20.120.1
Malignancy (%)18.818.8
Neurological diseases (%)16.616.6
Respiratory diseases (%)13.913.9
Chronic kidney diseases (%)8.58.5
In-hospital death24.921.4
RR (95% CI)0.86 (0.73–1.02)
OR (95% CI)0.82 (0.66–1.03)
a Reported is either the overlap propensity score–weighted mean or proportion for each group.OR: Odds Ratio; RR: Relative Risk.
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Voza, A.; Desai, A.; Luzzi, S.; Giotta Lucifero, A.; Azzolini, E.; Kogan, M.; Goretti, G.; Piovani, D.; Bonovas, S.; Angelotti, G.; et al. Clinical Outcomes in the Second versus First Pandemic Wave in Italy: Impact of Hospital Changes and Reorganization. Appl. Sci. 2021, 11, 9342. https://0-doi-org.brum.beds.ac.uk/10.3390/app11199342

AMA Style

Voza A, Desai A, Luzzi S, Giotta Lucifero A, Azzolini E, Kogan M, Goretti G, Piovani D, Bonovas S, Angelotti G, et al. Clinical Outcomes in the Second versus First Pandemic Wave in Italy: Impact of Hospital Changes and Reorganization. Applied Sciences. 2021; 11(19):9342. https://0-doi-org.brum.beds.ac.uk/10.3390/app11199342

Chicago/Turabian Style

Voza, Antonio, Antonio Desai, Sabino Luzzi, Alice Giotta Lucifero, Elena Azzolini, Maria Kogan, Giulia Goretti, Daniele Piovani, Stefanos Bonovas, Giovanni Angelotti, and et al. 2021. "Clinical Outcomes in the Second versus First Pandemic Wave in Italy: Impact of Hospital Changes and Reorganization" Applied Sciences 11, no. 19: 9342. https://0-doi-org.brum.beds.ac.uk/10.3390/app11199342

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