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Zinc (?)-immune pediatric virucidal activities for 2019-nCoV prevention and therapeutic effects of COVID-19 bronchitis and pneumonia

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Mini-Review | DOI: https://doi.org/10.31579/2692-9406/012

Zinc (?)-immune pediatric virucidal activities for 2019-nCoV prevention and therapeutic effects of COVID-19 bronchitis and pneumonia

  • Sci. Tsuneo Ishida 1*

*Corresponding Author: Sci. Tsuneo Ishida, 2-3-6, Saido, Midori-Ku, Saitama-Shi, Saitama-Ken, 〒336-0907, Japan.

Citation: Sci. Tsuneo Ishida. (2020) Bats: Zinc (Ⅱ)-immune pediatric virucidal activities for 2019-nCoV prevention and therapeutic effects of COVID-19 bronchitis and pneumonia. Biomedical Research and Clinical Reviews. 1(2); DOI: 10.31579/2692-9406/012

Copyright: ©2020 Sci. Tsuneo Ishida, This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Received: 01 July 2020 | Accepted: 25 July 2020 | Published: 29 July 2020

Keywords: zinc-induced immune pediatric intake; 2019-cov prevention; covid-19 bronchitis and pneumonia; serum zinc level; zn2+-coordinated pattern

Abstract

Zinc (Ⅱ)-immune pediatric virucidal activities for children with 2019-nCoV prevention and COVID-19 bronchitis and pneumonia are discussed, and these Zn2+-immune pediatric virucidal effects result in the following.

Zinc intakes by zinc induced immunity are required 3 mg/day for 7 month to 3 years, 5 mg/day for 4~ 8 years, and 8 mg/day for 9 ~13 years in children. Zinc supplementation have been assessed, from 15 mg to 140 mg/week, with the upper range exceeding the recommended daily infection (RDI) for children of 2 mg/day for children less than one year of age and up to 7 mg/day for children between 1 to 3 years.

Zinc induced pediatric preventing respiratory 2019-nCoV is required that supplementation with zinc gluconate 20 mg in Zn deficient children resulted in a nearly twofold reduction of acute lower respiratory infections as well as the time to recovery.  Zinc supplementation in children is associated with a reduction in the incidence and prevalence of pneumonia. Preventing 2019-nCoV pneumonia is required that zinc supplementation alone (10 to 20 mg) for more than 3 months significantly reduces in the rate of pneumonia.

Prophylactic zinc supplementation for two weeks may reduce the morbidity due to acute lower respiratory infections.  Zinc gluconate supplement may result in significant reduction in respiratory morbidity among children with acute lower respiratory infections.  In addition. as serum zinc level of Acute Respiratory Infection (ARI)-children was very low, higher zinc concentration treatments as low sociodemographic factors, poor nutritional status and male children were prevalently associated with higher incidence of acute respiratory infections.

Adjuvant treatment with 20 mg zinc/day accelerates recovery from severe pneumonia in children.  Primary outcome was recovery from pneumonia and 30 mg/day of zinc supplementation reduces pneumonia in children with chronic kidney disease (CKD).  Zinc supplementation + Chloroquine (CQ)/hydroxychloroquine (HCQ) may be more effective in reducing COVID-19 morbidity and mortality than CQ or HCQ in monotherapy.  The serum zinc level returned to a normal level (median, 53.20 μmol/L) on day 12±2 in the treatment. There was no statistical difference in the pediatric critic illness score, lung injury score, length of hospital stay, and duration of mechanical ventilation between the zinc treatments. The oxidative stress in pediatric diseases causes an oxidative burst that results in a respiratory burst and rapid ROS production.

Thus, zinc pediatric intake may be required to be effective range 10~20 mg/d for 2019-CoV prevention, 10~30 mg/d for reduction of COVID-19 bronchitis, and 20~30 mg/d for recovery from COVID-19 pneumonia, in which Zn2+ could bind with viral surface proteins by Zn2+ions-centered tetrahedrally coordination pattern.

Abbreviations:

ARI=acute respiratory infection, ARDS=acute respiratory distress syndrome, ALRI=acute lower respiratory infection, BCG=Bacille Calmette-Guerin, CQ=Chloroquine, CKD=chronic kidney disease,COVID-19=Coronavitrus disease-19, HCQ=hydroxychloroquine, MERS= Middle East Respiratory Syndrome, NADPH= nicotinamide adenine dinucleotide phosphate, Nox=NADPH oxidases, PICU=pediatric intensive care unit, RDI=recommended daily intake, ROS=reactive oxygen species, RR=Risk Ratio, SARS=Severe Acute Respiratory Syndrome, SARS-CoV-2=Severe Acute Respiratory Syndrome-Coronavirus-2, XO=xanthine oxidase.

Introduction

Epidemiological characteristics and clinical features of pediatric patients with coronaviruses disease-19  (COVID-19) infection are exhibited that the infected children had coinfection with other common respiratory pathogens and the pediatric patients have prolonged fecal shedding of Severe Acute Respiratory Syndrome-Coronavirus-2 (SARS-CoV-2) RNA during the convalescent phase that most pediatric patients had relatively mild disease with good prognosis, which could be seen in children infected with SARS-CoV respiratory viruses with innate immunity in response to pathogen [1].  COVID-19 in children is relatively mild that it is easy to miss the diagnosis in the early stages when present with a non-respiratory disease. The other, severe COVID-19 can also occur in children with underlying or coexisting diseases that the possibility of SARS-CoV-2 infection should be suspected when children show digestive tract symptoms, especially with  a severe systemic inflammatory reaction, fever and/or exposure history [2]. Pediatric cases of coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2 are relatively fewer cases of COVID-19 among children compared to cases among adult patients. The mild disease in children may be related to trained immunity that refers to the use of certain vaccines such as Bacille Calmette-Guerin (BCG) to train innate immunity to generate immune memory [3].  On the case of severe pediatric COVID-19 infection, severe thrombocytopenia and acute respiratory distress syndrome (ARDS) are presented, including patient’s severe disease course was associated with thrombocytopenia and elevated inflammatory markers. The patient’s severe respiratory disease did not improve on IVIg, steroids, azithromycin, and hydroxychloroquine that hyperin flammation may be important in the pathophysiology of COVID-19 severe acute respiratory syndrome. Finally, randomized placebo controlled clinical trials was used to study drugs like tocilizumab and remdesivir to include children in addition to adults with COVID-19 [4].

On the other hand, zinc utilization to pediatric antivitus activity becomes effective for childrrn health that zinc-binding proteins such as the metallothioneins may possess antiviral roles, although their specific function remains uncertain [5]. Zinc deficiency is associated with increased respiratory morbidity. Zinc is an antioxidant that protects cells from the damaging effects of oxygen radicals generated during immune activation.  The adverse effects of zinc deficiency on the immune system are likely to increase the susceptibility of children and lead to a zinc-deficient state. Therefore, zinc supplementation could conceivably modulate the immune and inflammatory responses to viruses in a way that are beneficial to the host [6]. The demonstrated preventive therapeutic effect of zinc in treatment of childhood pneumonia is conflicting. Despite the earlier observed reduction of treatment failure risk and case fatality in children with severe pneumonia, a more recent study demonstrated that Zn supplementation in 2-24 months old children with radiologically verified pneumonia did not result in significant improvement of risk reduction of treatment failure. Moreover, Zn supplementation in Zn-deficient children with pneumonia until achievement of normal serum Zn levels did not improve clinical appearance of the disease [7].

In this mini-review, firstly, zinc induced intake-immune children are described,  secondly zinc-immune peridiatic virucidal activities for 2019-nCoV prevention, COVID-19 respiratory ailment and pneumonia are discussed, and lastly, zinc induced ROS generation in COVID-19 infection is argued, including with molecular mechsnism which Zn2+ ions could bind with COVID-19 RNA viral surface proteins by Zn2+-centered tetrahedrally coordination pattern.

Zinc-induced immune children

Zinc intakes by zinc induced immunity are known to be required 3 mg/day for 7 month to 3 years,  5 mg/day for 4~ 8 years, and 8 mg/day for 9 ~13 years in children.  Zinc deficiency was very mild (3 to 5.0 mg Zn intake during the zinc-restricted period), the plasma zinc concentration remained more or less within the normal range and it decreased only after 4~5 months of zinc restriction. The other, zinc concentrations in lymphocytes, granulocytes, and platelets decreased within 8~12 weeks, suggesting that the assay of cellular zinc provided a more sensitive criterion for diagnosing mild deficiency of zinc, in which zinc enhances the upregulation of mRNA, which in both young adults and elderly subjects, zinc supplementation decreased oxidative stress markers and generation of inflammatory cytokines [8]. A range of zinc supplementation has been assessed, from 15 mg to 140 mg/week, with the upper range exceeding the recommended daily intake (RDI) for children of 2 mg/day for children less than one year of age and up to 7 mg/day for children between 1 to 3 years [9].

Zinc-immune pediatric prevention for respiratory ailment and pneumonia against 2019-nCoV infection

Zn supplementation significantly decreased the incidence of acute lower respiratory infection (ALRI) defined according to specific clinical criteria in children aged <5 years that zinc reduced childhood with ALRI, but the effect was null if lower specificity case definitions were applied. However, the factor was remained unexplained [10] 

Zinc induced pediatric preventing respiratory 2019-nCoV is required as supplementation with 10 mg zinc gluconate in Zn deficient children resulted in a nearly twofold reduction of the number of episodes of acute lower respiratory infections as well as the time to recovery [11]. Among paediatric populations zinc supplementation for more than 3 months could be effective in preventing pneumonia in children younger than 5 years of age, although the evidence was not robust enough to advocate prophylactic properties if given for shorter periods of time [12].  Given the rising burden of child mortality due to respiratory infections, particularly pneumonia, and considering its decreasing impact with zinc supplementation, further reviews should be considered in which the effectiveness of zinc supplementation should be assessed for acute pneumonia provided that cases are well-defined by strict clinical criteria. Thus, zinc supplementation in children is associated with a reduction in the incidence and prevalence of pneumonia [13].

Preventing pneumonia is required that zinc supplementation alone (10 to 20 mg), for more than 3 months, was associated with a significant reduction in the rate of pneumonia by 19%, with Risk Ratio (RR) of 0.81 (95% CI 0.73 to 0.90).  Mortality was not statistically different (RR = 0.85; 95% CI 0.65 to 1.11) [14].

Antiviral avtivity of Zn2+ ions for the children with respiratory COVID-19 infection

The role of zinc for adult patients with 2019-nCoV infection may be chiefly efficient at the preventions of 2019-CoV, COVID-19 bronchitis and pneumonia, and at the recovery from COVID-19 acute inflammatory lung [15]. However, the influence of zinc on children patients with 2019-nCoV infection may be not necessarily simmilar to adult patients. 

Zn supplementation of 30 mg/day in Thai children reduced significantly severity of acute lower respiratory tract infections resulting in faster disease cessation and shorter hospital stay [16].  

A decrease of 15% (0.78-0.94) in days and 12% (0.78-0.94) in duration of episode in acute respiratory infections was observed. Incidence of acute lower respiratory infections decreased by 62% (0.26-0.36) and the effect remained for full five months of follow up. Prophylactic zinc supplementation for two weeks may reduce the morbidity due to acute lower respiratory infections but not overall rate of acute respiratory infections in infants aged 6~11 months in similar populations [17].  Effectiveness of zinc gluconate supplementation for 2 months period compared to placebo in reducing respiratory morbidity in acute lower respiratory infected children up to 5 years of age living in zinc poor population. Zinc supplement may result in significant reduction in respiratory morbidity among children with acute lower respiratory infections [11].

Serum zinc level was very low (25.19 ± 15.49 μgmol/L) with acute respiratory infection (ARI) children as compared that (55. 51 ± 31.15 μgmol/L) with non-ARI children, in which environment and nutritional status were found to be prevalently associated with higher incidence of acute respiratory infections and serum zinc content had been varied with corresponding sociodemograpic, nutritional and health care profile [18]. 

Antiviral avtivity of Zn2+ ions for the children with COVID-19 pneumonia

Pneumonia is one of the most common implications of lower respiratory tract involvement. The pneumonia is an inflammation on pulmonary parenchyma resulting in exutative solidification of pulmonary tissue of the effect of zinc on the clinical course of pneumoniain 3 to 60-month-old children hospitalized in pediatric wards.  Adjuvant treatment with 20 mg zinc per day accelerates recovery from severe pneumonia in children, and could help reduce antimicrobial resistance by decreasing multiple antibiotic exposures, and lessen complications and deaths where second line drugs are unavailable.  The mean reduction is equivalent to 1 hospital day for both severe pneumonia and time in hospital. All effects were greater when children with wheezing were omitted from the analysis.20 mg zinc per day can accelerate the recovery from severe pneumonia in children [19].

The effect of zinc on clinical course of 3 to 60-month children hospitalized due to pneumonia was assumed that this element (zinc) was effective in resolving clinical symptoms and duration of hospitalization. Zinc supplements given during an acute episode are not beneficial in short-term clinical recovery from severe pneumonia in hospitalized children. Primary outcome was recovery from pneumonia which included the incidence and resolving clinical symptoms and duration of hospitalization [20].  Zinc may bebene-ficial for nutritional status in children and adolescent with chronic kidney disease (CKD) due to the fact that participants may have improved their nutritional status through the slight but significant gain in their body mass, especially with 30 mg/day of zinc supplementation.  30 mg/day of zinc supplementation reduces pneumonia in children with CKD [21]. Zinc + Chloroquine (CQ)/ hydroxychloroquine (HCQ) may be more effective in reducing COVID-19 morbidity and mortality than CQ or HCQ in monotherapy [22].

The serum zinc level returned to a normal level (median, 53.20 μmol/L) on day 12 ± 2 in the treatment. There was no statistical difference in the pediatric critic illness score, lung injury score, length of hospital stay, and duration of mechanical ventilation between the zinc treatments [23].  The mean serum zinc in patients was normal (80.77 + 25.3 μg/dL) yet, the mean serum zinc level in pediatric intensive care unit (PICU) patients was lower than that of general ward patients that the lower the serum zinc level, the higher the grade of respiratory distress among children with pneumonia [24].  Moreover, treatment of zinc sulfate plus hydroxychloroquine may play a role in therapeutic management for COVID-19 petients without PICU [25].

Zinc-induced ROS generation in COVID-19 respiratory ailment and pneumonia

Respiratory viruses are known to induce reactive oxygen species (ROS)-generating enzymes, including nicotinamide adenine dinucleotide phosphate oxidases (NADPH oxidases, Nox) and xanthine oxidase (XO) and to disturb antioxidant defenses. ROS generation can induce cell death and the release of virions representing possible proviral role of enhanced ROS production and altered redox balance. The oxidative stress is an antiviral immune response. too strong immune responses lead to a cytokine storm and severe inflammation, which may disturb lung function and antioxidant supplementation is expected to ameliorate the consequ-ences of infection [26].

Zinc induced ROS generation in respiratory and pulmonary COVID-19 infected cells is that the univalent reduction of oxygen generates superoxide •O2−,  hydrogen peroxide H2O2, and hydroxyl radicals •OH, all of which are reactive oxygen species (ROS). The ROS production and its elimination by the anti-oxidant defense system in cells is a highly modulated process for maintaining normal physiological function in the body, in which the nicotinamide adenine dinucleotide phosphate (NADPH) oxidases are a group of plasma membrane-associated enzymes which catalyze the production of superoxide •O2−  from oxygen by using NADPH as the electron donor.  Thus, zinc acts as a potent agent by inhibition of ROS production and inflammation [27]. The oxidative stress in pediatric diseases causes an oxidative burst that results in a respiratory burst and rapid ROS production, including superoxide and hydrogen peroxide [28].  However, ROS production in zinc(Ⅱ)-immune pediatric patient with COVID-19 bronchitis and pneumonia cannot be elucidated yet.

In addition, the role of zinc to pediatric vaccine plays an important 2019-nCoV RNA viral degradation, whether a transcriptional step may be involved in zinc-caused inhibition of vaccinia virus growth, zinc-ions (at lower concentration) could inhibit the infection by viral mRNAs degradation, and zinc-ions could inhibit 2019-nCoV by recruiting both the 5’ and 3’ mRNA degradation to specifically promote the degradation [29].

As mentioned above, Zn2+ ions-induced pediatric virucidal activities for 2019-nCoV prevention and COVID-19 bronchitis and pneumonia are summarily represented in Table 1.

In conclusion, zinc pediatric intake may be required to be effective range 10~20 mg/d for 2019-CoV prevention, 10~30 mg/d for reduction of COVID-19 bronchitis, and 20~30 mg/d for recovery from COVID-19 pneumonia, in which the molecular mechanism may possess that Zn2+ ions could bind with viral surface proteins by Zn2+-centered tetrahedrally coordination pattern [30].

Table 1: Zn2+ ions-induced pediatric virucidal activities for children prevention, respiratory ailment and pulmonary disease against COVID-19 infection

Conclusions

Zinc (Ⅱ)-immune pediatric virucidal activities for children with 2019-nCoV prevention and therapeutic effect of COVID-19 bronchitis and pneumonia are discussed, and these pediatric virucidal activity effects result in the following.

Zinc intakes by zinc induced immunity are required 3 mg/day for 7 month to 3 years,  5 mg/day for 4~ 8 years, and 8 mg/day for 9 ~13 years in children. Supplementation have also been assessed, from 15 mg to 140 mg/week, with the upper range exceeding the RDI for children of 2 mg/day for children less than one year of age and up to 7 mg/day for children between 1 to 3 years.

Zinc deficiency was very mild (3 to 5.0 mg Zn intake during the zinc-restricted period), the plasma zinc concentration remained more or less within the normal range and it decreased only after 4~5 months of zinc restriction.  On the other hand, zinc concent-rations in lymphocytes, granulocytes, and platelets decreased within 8~12 weeks, suggesting that the assay of cellular zinc provided a more sensitive criterion for diagnosing mild deficiency of zinc, in which zinc enhances the upregulation of mRNA, which in both young adults and elderly subjects,zinc supplementation decreased oxidative stress markers and generation of inflammatory cytokines.

Zinc supplementation reduced the incidence of childhood with ALRI defined by relatively specific clinical criteria, but the effect was null if lower specificity case definitions were applied. The choice of ALRI case definition may substantially influence inferences from community trials regarding the efficacy of preventive interventions.   Zinc induced pediatric preventing respiratory 2019-nCoV is that specifically, supplementation with zinc gluconate 10 mg in Zn deficient children resulted in a nearly twofold reduction of the number of episodes of acute lower respiratory infections as well as the time to recovery.   Zinc supplementation in children is associated with a reduction in the incidence and prevalence of pneumonia.

Preventing pneumonia is required that zinc supplementation alone (10 to 20 mg), for more than 3 months, was associated with a significant reduction in the rate of pneumonia by 19%, with an RR of 0.81 (95% CI 0.73 to 0.90) when compared with the control group (placebo, vitamins, other minerals).

Supplementation (30 mg/day) in Thai children significantly reduced severity of acute lower respiratory tract infections resulting in faster disease cessation and shorter hospital stay. Prophylactic zinc supplementation for two weeks may reduce the morbidity due to acute lower respiratory infections but not overall rate of acute respiratory infections in infants aged 6~11 months in similar populations.  Zinc gluconate may result in significant reduction in respiratory morbidity among children with acute lower respiratory infections in zinc poor population.  In addition. as serum zinc level of Acute Respiratory Infection (ARI)-children was very low, higher zinc concentration treatments as low sociodemographic factors, poor nutritional status and male children were prevalently associated with higher incidence of acute respiratory infections.

Pneumonia is an inflammation on pulmonary parenchyma resulting in exutative solidification of pulmonary tissue, having the effect of zinc on the clinical course of pneumoniain 3 to 60-month-old children hospitalized in pediatric wards. Adjuvant treatment with 20 mg zinc per day accelerates recovery from severe pneumonia in children.  Primary outcome was recovery from pneumonia which included the incidence and resolving clinical symptoms and duration of hospitalization.  Zinc supplementation 30mg/day reduces pneumonia in children with CKD.  Zinc + CQ/HCQ may be more effective in reducing COVID-19 morbidity and mortality than CQ or HCQ in monotherapy.

The serum zinc level returned to a normal level (median, 53.20 μmol/L) on day 12±2 in the treatment. There was no statistical difference in the pediatric critic illness score, lung injury score, length of hospital stay, and duration of mechanical ventilation between the zinc treatment.  Respiratory viruses are known to induce ROS-generating enzymes and lead to an oxidative stress thatthe oxidative stress in pediatric diseases causes an oxidative burst that results in a respiratory burst and rapid ROS production, including superoxide and hydrogen peroxide.

Accordingly, zinc pediatric intake may be required to be effective range 10~20 mg/d for 2019-CoV prevention, 10~30 mg/d for reduction of COVID-19 bronchitis, and 20~30 mg/d for recovery from COVID-19 pneumonia, in which the molecular mechanism may possess that Zn2+ ions could bind with viral surface proteins by Zn2+-centered tetrahedrally coordination pattern.

Conflicts of Interest

 The author declares there is no conflicts of interest.

Sources of funding: None

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