Potential Anti-SARS-CoV-2 Prodrugs Activated by Phosphorylation and Their Role in the Aged Population

The COVID-19 pandemic has flared across every part of the globe and affected populations from different age groups differently. People aged from 40 to 80 years or older are at an increased risk of morbidity and mortality due to COVID-19. Therefore, there is an urgent requirement to develop therapeutics to decrease the risk of the disease in the aged population. Over the last few years, several prodrugs have demonstrated significant anti-SARS-CoV-2 effects in in vitro assays, animal models, and medical practice. Prodrugs are used to enhance drug delivery by improving pharmacokinetic parameters, decreasing toxicity, and attaining site specificity. This article discusses recently explored prodrugs such as remdesivir, molnupiravir, favipiravir, and 2-deoxy-D-glucose (2-DG) and their implications in the aged population, as well as investigating recent clinical trials.

The most widely used medication during the COVID-19 pandemic has been remdesivir (RDV), an ester prodrug of G-5734 [32]. Currently, it is the only drug in the small molecule antiviral category which is approved by the US FDA to manage nonhospitalized high-risk COVID-19 patients [33]. It contains a single phosphate moiety that efficiently carries it through the biological membrane and is converted to the triphosphate form to Prodrugs can be chemically classified into carrier-linked prodrugs and bioprecursor prodrugs [51]. A carrier-linked prodrug consists of an active drug linked to an enzymatically removable carrier group. It can further be subclassified as a bipartite prodrug, where the carrier molecule is directly attached to an active drug; a tripartite prodrug, where the carrier molecule is attached to an active drug via a spacer or linker; or a mutual prodrug (codrug), which consists of two active drugs attached to each other, usually synergistic, where one will play a carrier role for the other and vice versa [52]. Finally, a bioprecursor prodrug is a compound that can be metabolized enzymatically to the active drug by molecular modification. Bioprecursor prodrugs can be converted into active forms by different mechanisms, such as biological oxidation mediated by CYP450 enzyme systems, proton activation, hydrolysis, elimination, reduction, nucleotide activation, phosphorylation, sulfation, and decarboxylation [53]. Here, we have discussed the synthesis of promising anti-SARS-CoV-2 bioprecursor prodrugs that can be activated by nucleotide activation (remdesivir, molnupiravir, and favipiravir) and by phosphorylation (2-deoxy-D-glucose).

Synthesis of Molnupiravir
Molnupiravir is a ribonucleoside prodrug composed of two structural fragments-Nhydroxycytosine and ribose sugar. Several synthetic routes to molnupiravir have recently been published using uridine, cytidine, or ribose as key starting materials [55]. Emory University was the first one to report a five-step synthetic method using uridine as a starting material, which has the drawback of very low yield and the use of the costly reagent 1,2,4-triazole (Scheme 3). This method starts with the synthesis of acetonide 16 by protecting the vicinal diol, followed by its reaction with isobutyric acid anhydride in the presence of 4-dimethylaminopyridine (DMAP) and triethylamine to obtain the corresponding isobutyryl ester 17. The subsequent steps are chlorination, coupling with 1,2,4-triazole (18), the formation of hydroxylamine analog (19), and finally, the deprotection of acetonide using formic acid to afford molnupiravir. Unfortunately, the yield after the five steps was very poor [56].
To overcome the problems associated with the above scheme, a facile, high-yield, and low-cost commercial potential manufacturing route was developed by Merck and Codexis [57]. It consists of a three-step process containing ribose as a key starting material (Scheme 3A). Ribose was first esterified enzymatically. The next step required the usage of four enzymes-phosphorylation by MTR kinase, nucleobase formation by uridine phosphorylase, regeneration of acetyl phosphate and ATP by acetate kinase, and then the addition of pyruvate oxidase to generate the penultimate intermediate (22). In the last step, the intermediate (22) acidic carbonyl group was converted into hydroxylamine to afford molnupiravir.

Synthesis of Favipiravir
The synthesis of favipiravir was first developed in 2000 by Furuta et al. from a Japanese company named Toyama Chemical Co., Ltd. [58]. Their method began with the synthesis of the methyl ester of 3-aminopyrazine-2-carboxylic acid (24), followed by bromination using N-bromosuccinimide, diazotization, alcoholysis, and Buchwald-Hartwig carboncarbon bond coupling to synthesize the intermediate (28). Furthermore, aminolysis of the methyl ester yielded aminopyrazine carboxamide (29). Finally, the diazotization of the resultant intermediate (29), followed by treatment with Olah's reagent (HF-pyridine) and demethylation of the methoxy group, afforded favipiravir (31). However, this method has the drawbacks of using a toxic reagent (Olah's reagent), multistep synthesis, purification, and an overall very poor yield (Scheme 4A). Toyama then collaborated with Nippon Soda to develop an improved and facile route that overcomes the problems associated with the earlier route (Scheme 4B) [59]. This six-step synthesis began with the reaction of 2-aminopropanediamide (32) with glyoxal in basic media to form the sodium salt of the intermediate (33). This was followed by bromination and subsequent chlorination, then reaction with N,N -diisopropylethylamine in chlorobenzene at a reflux temperature to obtain 3,6-dichloro pyrazine-2-carbonitrile3,6dichloro pyrazine-2-carbonitrile (35). This was then treated with a fluorinating agent to produce 3,6-difluoropyrazine-2-carbonitrile (36) and further reacted with potassium acetate and hydrogen peroxide to obtain favipiravir.

Synthesis of 2-Deoxy-D-Glucose
Besides the recent use of 2-DG in COVID-19, it is effective against various other diseases, including cancer, dermatitis, polycystic kidney disease, and neurological disorders. Considering its promising therapeutic relevance, chemists have developed various strategies to synthesize 2-DG. The various routes of its synthesis have been previously reviewed and compiled by Marzabadi et al. [60] and Wijayasinghe et al. [61]. The methods that use inexpensive and readily available D-glucose as a starting material may be the most promising of all of the reported synthetic methods. W. Xu et al. reported a synthetic protocol which bears a 62% yield at the last step (Scheme 5) [62]. In this method, D-glucose is first acetylated to generate penta-O-acetyl-D-glucose, then treated with phosphorus tribromide (PBr 3 ) to afford 1-bromo-2,3,4,6-tetra-O-acetyl-D-glucose. It is then reduced to triacetyl-O-D-glucal using Zn and monosodium phosphate (NaH 2 PO 4 ). These steps are followed by subsequent hydrolysis, bromination, and reduction to obtain 2-DG with high yield and purity. Earlier, Vaidyanathaswamy et al. also reported the synthesis of 2-DG using D-glucose, with a 60% yield in the last step [63].

Remdesivir
The FDA authorized Remdesivir (Veklury) as the initial antiviral therapy for COVID-19 on 22 October 2020 [64]. A nucleoside analog under research named Remdesivir (GS-5734; Gilead Sciences Inc., Foster, CA, USA) functions as a competitive inhibitor of viral RdRp [65]. It is a prodrug of the adenosine nucleotide analog, which undergoes phosphorylation to form the nucleoside triphosphate analog after being converted to nucleoside monophosphate ( Figure 1). With a precision mass of 602.23 Da and the molecular formula C 27 H 35 N 6 O 8 P, RdRp, a key enzyme for viral replication, interfaces with native ATP, and thus, is beneficial for the utilization of the nucleoside triphosphate derivative. Remdesivir is transformed within the body into GS-441524, an active molecule with the molecular formula C 12 H 13 N 5 O 4 (291.10 Da) [66]. Mechanism of Remdesivir has been shown in Figure 1. Remdesivir should bind to SARS-CoV-2 RdRp with great affinity, according to molecular docking research, supporting its molecular mode of action [67]. Remdesivir has demonstrated low cytotoxicity in cultured cells and broad-spectrum antiviral efficacy by inhibiting the replication of several RNA viruses, including filoviruses, paramyxoviruses, pneumonia viruses, arenaviruses, and coronaviruses [68]. Several clinical trials are being conducted to fully evaluate the effectiveness of remdesivir in nations such as the USA, Norway, Canada, France, and China. Remdesivir is used in two dosages, with the first dose being 200 mg and the subsequent doses being 100 mg for the duration of the program. On 29 April 2020, the results of the first multicenter, randomized, double-blind, and placebocontrolled clinical trial were released [69]. The study's main endpoint was the average time that a patient took to perceive a significant improvement. It involved 237 patients in China (158 received remdesivir and 79 received a placebo). The outcomes demonstrated that the time it took for a patient to see an improvement in symptoms was not substantially shortened by using remdesivir. Remdesivir may have provided few clinical benefits due to COVID-19 patients' high mortality and slow virus clearance rates [70]. Additionally, there are not enough data on remdesivir, particularly in drug-gene and drug-disease intercommunication. Both in vitro and in vivo investigations have demonstrated its antiviral activity against SARS-CoV-2 [71,72]. Remdesivir has been prescribed as an emergency medication in several nations for COVID-19 patients, and some of these individuals exhibited better clinical results. However, extensive clinical trials must still be carried out to demonstrate the effectiveness of remdesivir in treating SARS-CoV-2 patients. Remdesivir effectively combatted novel varieties, including B.1.17 and B.1.351 [32,73,74]. In Table 1, some clinical trials which were performed in aged populations are listed. The in vitro neutralization of omicron and its subvariants is still possible using remdesivir. Remdesivir can be completely infected by the omicron and delta versions of COVID-19. As a triphosphate metabolite, it directly inhibits the SARS-CoV-2 RdRp enzyme [74]. Andrea et al. studied the effect of remdesivir in people with SARS-CoV-2. It was administered to patients aged 40 years and older, with 60 patients in the control group and 18 people in the case group. The analysis showed that treatment with remdesivir and heparin led to lower mortality [75]. The SARS-CoV-2 variants have not been discovered to have any known ns12 mutations. Remdesivir is administered intravenously as an injection (100 mg) to COVID-19 adult and pediatric patients who must weigh at least 40 kg. However, significant contraindications have emerged, including anaphylaxis, hypersensitivity, shivering, bradycardia, dermatitis, nausea, etc. Remdesivir causes premature rupture, preterm birth, and fetal mortality; thus, pregnant women should not use it [76]. The most vulnerable group in society is elderly patients; however, the efficacy and safety of remdesivir for elderly patients have been checked in clinical trials. The efficacy of remdesivir in a real-world cluster of elderly patients hospitalized in Spain with COVID-19 was studied prior to the start of the vaccination programme. Per the study, patients under the age of 80 who received remdesivir had a 15.7% lower 30-day all-cause mortality rate and a 60% lower adjusted mortality risk than untreated patients. Even though they were most likely among those who should have received it, remdesivir was only given to a few patients with moderate to severe dependence and dementia [77]. Older patients had a lower chance of exhibiting raised severity scores than younger patients [78]. The risk of death for SARS-CoV2-infected individuals above the age of 80 is significantly higher than the risk for patients under the age of 80, according to recent epidemiological figures. Fever, cough, dyspnea, fatigue, and myalgia are the most common symptoms in elderly individuals, and only a small percentage of them develop acute respiratory distress syndrome (ARDS) [79].

Molnupiravir
The drug Molnupiravir (EIDD-2801) is the first orally available ribonucleoside which contains an isopropyl ester prodrug of N4-hydroxycytidine (NHC/EIDD-1931) with broadspectrum antiviral activity against SARS-CoV-2 and other RNA viruses, as well as a high barrier to resistance development [80]. Similarly, to remdesivir, it also inhibits virus replication by inhibiting RdRp. It was first synthesized by the Emory Institute for Drug Development and was later taken up by Merck for further development [81]. Molnupiravir, a medicine which was co-developed by Merck and Ridgeback Biotherapeutics, was revealed on 1 October 2021. It can significantly diminish the risk of hospitalization or mortality in patients with mild or moderate COVID-19, which has sparked great interest in the drug among the scientific community [82]. Several studies have elucidated the mechanisms of Molnupiravir, emphasizing its critical role in the suppression of SARS-CoV-2 infection [83,84]. First, Molnupiravir is hydrolyzed to N4-hydroxycytidine and then phosphorylated to N4-hydroxycytidine triphosphate (MTP) with the help of host kinases ( Figure 2). MTP can cause mutations in viral synthesis and inactivate virus offspring by participating in viral replication and increasing the G to A and C to U substitutions [40]. A normal complementary base pairing would pair G with C (G:C), and A would pair with U or T (A: U/A: T), while MTP could pair either with A or G. After being integrated into the template strand, C: G or U: A can moderately impede the extension of MTP: G or MTP: A products, although this inhibition can be decreased when the concentration of MTP is sufficiently high [83]. As a result of the strong antiviral action of Molnupiravir, mutations from G to A (G: NHC: A) and C to U (C: G: NHC: A: U) have also been observed in subsequent replication [84]. Detailed mechanism of action of Molnupiravir has been give in Figure 2. In addition, Angelica Jayk Bernal and coworkers analyzed the effect of Molnupiravir as an oral treatment in non-hospitalized patients. They concluded that early treatment with Molnupiravir will reduce the risk of death and hospitalization in unvaccinated patients with COVID-19 [80]. Molnupiravir has been tested in preclinical studies as an orally bioavailable nucleoside analog prodrug of NHC. Being a prodrug, it demonstrates enhanced stability. Furthermore, it exhibits higher oral bioavailability in ferrets, nonhuman primates, and mice than the prototype metabolite NHC. [85,86]. In addition, according to preclinical studies, Molnupiravir has shown a low risk of genotoxicity [83,84,87]. Table 2 describes the ongoing clinical trials on Molnupiravir.
Molnupiravir provides broad antiviral action against various genetically unrelated coronaviruses, including the recently identified SARS-CoV-2 variants of concern (alpha, beta, gamma, delta, and omicron) [86,88]. Recent research has revealed that Molnupiravir can suppress the omicron variant both in vitro and in vivo [89,90]. Nevertheless, the data on its effectiveness and safety in the omicron-infected population are still insufficient. Andrea et al. studied the safety and efficacy of molnupiravir in 192 patients with a mean age from 70.4 to 15.4 years among 144 patients over 60 years. The early onset of antiviral treatment avoids disease progression and reduces comorbidities such as cardiovascular disease, chronic lung disease, obesity, and diabetes. In addition, molnupiravir has no interaction with other chronic treatments [91]. One study assessed the efficacy of molnupiravir in hospitalized COVID-19 patients. Among 11,822 patients, molnupiravir was administered to 203 patients, whereas 387 did not receive any antiviral therapy and thus required dexamethasone and baricitinib therapy. Treatment with molnupiravir reduced mortality, and it was evident in patients over 80 years of age that were treated in the first five days of the disease that molnupiravir therapy did not affect the frequency of need for ventilation. Nevertheless, patients treated with molnupiravir required oxygen supplementation less frequently [92]. Molnupiravir was effective when provided orally to adults aged 80 and up, potentially enhancing the results. Furthermore, this medicine efficiently stopped human transmission of the SARS-CoV-2 virus in hospital wards. There were no deaths within 30 days, demonstrating its effectiveness. Only 55% of the target patients experienced mild adverse events within seven days of internal administration. Only nausea was noted; no other serious side effects were observed, indicating that the medicine can be safely given to elderly individuals. Early Molnupiravir treatment reduced the likelihood of death in older people at risk for COVID-19. Because the sample size was so small, it was insufficient as reliable evidence [93].

Favipiravir
Favipiravir is a prodrug with antiviral properties and is used to treat COVID-19. It has a low molecular weight of 157.1 g/mol [94]. Favipiravir is a purine base analog; after oral administration, favipiravir is converted into its active metabolite, favipiravir ribofuranosyl-5B-triphosphate (Favipiravir-RTP), by intracellular phosphor-ribosylation [95]. It acts as a selective inhibitor of RdRp of RNA viruses. Favipiravir has a broad spectrum of antiviral properties that enable various RdRps in several types of RNA viruses. The favipiravir RTP adds pressure on coronavirus nucleotides, which already have low cytosine in their SARS-CoV-2 genome. With an increased frequency of mutation, favipiravir RTP has a positive effect on the virus cytopathic effect, which induces a reduction in viral RNA. It has a long binding affinity to RdRp; hence, it targets SARS-CoV-2 and ultimately prevents viral transcription and replication [96]. Mechanism of action of Favipiravir has been shown in Figure 3. The effect of favipiravir on SARS-CoV-2-infected people was studied by performing a placebo-controlled phase 2 trial. Before starting this trial, a non-randomized study of favipiravir in patients aged 18 and above were found the drug to exhibit more than a 90% viral clearance [97]. The clinical trial data found that favipiravir was beneficial over a placebo regarding secondary progression in infected patients. Upon oral administration, it inhibited viral replication, and its pharmacokinetic properties also act on the virologic activity [98].
Another randomized, open-label phase 3 clinical study was undertaken in patients aged 18-75 years to determine the safety and efficacy of the drug. For oral administration of favipiravir, RT-PCR negativity was 28.7% earlier in moderate COVID-19 patients. The antiviral effect was 40% faster than that of a placebo, and it was found to be safe and welltolerated in open-label clinical trials [99]. Yuan et al. performed another study to evaluate favipiravir's clinical efficacy and safety in patients with severe fever with thrombocytopenia syndrome (SFTS). A total of 23,350 patients aged < 70 years, between 60 and 70 years, and >70 years were involved in the study. Favipiravir significantly reduced case fatality rates from 20% to 9%; however, a significant effect was observed among patients aged <70 years with a therapy duration of >5 days. Instant favipiravir therapy could help SFTS patients aged 60-70 years; however, these therapies cause hyperuricemia and thrombocytopenia in >70-year-old patients [100]. A clinical study was conducted in China to study favipiravir's effectiveness against SARS-CoV-2 patients, especially in elderly individuals that were 65 years and older. Patients received 1600 mg twice a day on day 1, and 600 mg twice a day from day 2 to day 14, and the primary outcome was monitored by computed tomography to evaluate the efficiency of the drug [101]. Ivashcenko et al. conducted an open-label study with 60 patients that were above 60 years of age or older. Patients received 1800-1600 mg on the first day and 800-600 mg on the second day, which resulted in decreased viral load and normalized body temperature, and approximately 62.5% and 92.5% of patients had a negative PCR result on day 5 and day 10, respectively [102].
Patients received either a placebo or 1800 mg of favipiravir BID (two times a day) on day 1 and 800 mg of favipiravir BID from days 2 to 13. Although there were more patients over 65 years of age in the placebo group, there were higher-or medium-risk patients in the favipiravir group. A 2020 observational study by Fujita Health University found that symptoms deteriorated more frequently in patients 60 and older than in younger patients and that senior patients saw improvements in fewer cases than younger individuals. The numbers of patients in trials testing favipiravir as a COVID-19 medication were modest, and a tiny percentage of people that were 65 and older took part in the trials [103,104].
A recent in vitro study by Wang et al. reported that favipiravir and oseltamivir combination therapy might facilitate clinical recovery in patients and reduce SARS-CoV-2 infection [105]. The viral clearance rate for AVIFAVIR versus the standard of care in hospitalized SARS-CoV-2 patients was nearly 62.5% when investigated in phase 2 and phase 2/3 trials. Two different doses, 1600/600 mg and 1800/800 mg, were given and showed similar virologic responses. On day 10, viral clearance was achieved in 92.5% of patients who received AVIFAVIR and 80% of patients who received SOC [106]. Further analysis and safety data were obtained from phase 2 and 3 clinical studies of favipiravir. It could be reliable and endurable in a short span of use; however, more evidence is required for longer-term treatments [107]. Table 3 describes the ongoing trials on favipiravir.

2-Deoxy-D-Glucose
2-DG is a glucose analog which is effective as an antiviral agent and was approved by the Indian Council of Medical Research (ICMR) in May 2021 for the treatment of SARS-CoV-2 infection. It is essentially a glucose molecule in which the 2-hydroxyl group is replaced by hydrogen [108]. The glucose analog enters the cytosol and is phosphorylated to 2-DG-6P (2-deoxy-D-glucose-6-phosphate) by the enzyme hexokinase, which is further metabolized by phosphate-glucose isomerase, leading to the accumulation of 2-DG-6P in cells and the depletion of cellular ATP [31]. Specifically, in infected lung cells, it decreases glycolysis and energy production and inhibits viral replication. Thus, the cell survival rate decreases and the cell death pathway is activated [109]. Further, 2-DG is more stable than its active metabolite, 2-DG-6P, and has a longer shelf life. The drug 2-DG-6P is a potent inhibitor of glycolysis, which is a central metabolic pathway in cells. The direct administration of 2-DG-6P can result in systemic toxicity. In Figure 4, Detailed information has been shown with their mechanism of action. However, by administering 2-DG as a prodrug, the cells and tissues regulate the conversion to the active metabolite, which can help to minimize toxicity. The Drug Controller General of India (DCGI) approved its emergency use as an adjuvant therapy in coronavirus patients on 17 May 2021. It reduces viral load and the need for oxygen supplement therapy [110]. Preliminary in vitro studies have shown that 2-DG can potentially reduce the viral load in host cells [111]. Vero and Vero E6 cell lines were used as in vitro model systems to study the effect of fluorescent 2-DG against SARS-CoV-2 infection. It was discovered that 2-DG treatment of Vero cells compromised SARS-CoV-2's infection and multiplication efficiency, reducing the ability to infect newer cells and showing overall effective inhibition of virus growth [112]. In addition, it was discovered that 2-DG possessed a binding energy of −140.05 kcal/mol with 3CLpro. Furthermore, bioanalytical and toxicity studies suggest that 2-DG produces sufficient oral bioavailability without side effects or toxicity [113].
Moreover, 2-DG also has multiple pharmacological effects and controls SARS-CoV-2 infection by improving the host immune response. According to a fractional-order optimal control problem (FOCP) study, 2-DG generates better results in preventing and controlling SARS-CoV-2 infection [114]. In addition, Verma et al. concluded that 2-DG could enhance the efficacy of low-dose radiation therapy (LDRT) in COVID-19 pneumonia patients by preventing lung damage. Furthermore, low doses could decrease the cytokine storm by inducing anti-inflammatory responses [115]. Table 4 describes the ongoing clinical trials on 2-DG.

NCT05009563
The Institute of Nuclear Medicine and Allied Sciences (INMAS) and a DRDO scientist initiated phase 2 clinical trials in May 2020 [116]. The phase 2 study found substantial recovery progress in 2.5 median days in normalizing vital parameters between the 2-DG arm and progress to the SoC arm. A further phase 3 trial enrolled various Indian states and was recently approved in May 2021 by the DCGI for the emergency use of 3-DG as an adjoining therapy in patients with moderate to severe COVID-19 [117]. A randomized, open-label phase 2 clinical trial evaluated the efficacy, safety, and tolerability of 2-DG. A total of 110 patients between the ages of 18 and 65 with moderate to severe COVID-19 were involved in this study. A dose of 63 mg/kg/day, 90 mg/kg/day, or 126 mg/kg/day of 2-DG was given to the patients; among these doses, 90 mg/kg/day showed a beneficial effect in the treatment of severe to moderate COVID-19 [118].

Impact of Prodrugs on Vaccinated COVID-19 Patients
Various treatment options have been investigated to prevent the catastrophic progression of COVID-19 in communities. Vaccinated patients have also been monitored regarding the use of antiviral prodrugs to reduce the progression of disease symptoms. Recently, a matched-pair retrospective study was conducted to assess the role of remdesivir and vaccination in preventing severe clinical outcomes [119]. The nonhospitalized vaccinated patients who received a three-day course of remdesivir had a 75% lower risk of hospitalization and a 95% lower risk of respiratory failure. In addition, the study concluded that, in high-risk, nonhospitalized patients, vaccination combined with a three-day course of remdesivir significantly prevented severe clinical progression of COVID-19.
To evaluate the efficacy of another antiviral prodrug, molnupiravir, a phase 2 experimental study called AGILE CST-2 was conducted in vaccinated and unvaccinated COVID-19 patients [120]. The study included 180 participants with an average age of 43 years. Most of them had already received their first dose of the COVID-19 vaccine. The experiment included patients with alpha (37 of 180), delta (72 of 180), omicron (38 of 180), and EU1 (28 of 180) variants. Participants in the molnupiravir group received negative PCR results faster (8 days) than those in the placebo group (11 days). Thus, molnupiravir was found to have antiviral activity in vaccinated and unvaccinated individuals infected with a wide range of SARS-CoV-2 variants, although this evidence is inconclusive.
A longitudinal study covering the role of vaccine, favipiravir, and micronutrient supplementation was conducted to evaluate post-COVID symptoms [121]. The study included 923 people (18.2% were fully vaccinated). One of the most frequently reported post-COVID symptoms was fatigue. The combination of micronutrients such as vitamins C and D and favipiravir did not affect all post-COVID symptoms. When infected with SARS-CoV-2, a full COVID-19 vaccination prevents the disease and the development of residual symptoms. As a result, it is critical to reconsider the prescription of micronutrients or adjust the dose of favipiravir in the current guidelines.

Conclusions and Future Perspectives
The scientific community has made significant progress in generating potential antiviral medications; however, effective anti-SARS-CoV-2 therapies are still not accessible. COVID-19 can be treated effectively with broad-spectrum anti-SARS-CoV-2 prodrugs. Aging generates various biochemical changes in the immune system which have been associated with age-related disorders and susceptibility to infectious infections. The likelihood of developing severe symptoms increases with age, with people aged 40 and older having the greatest risk of developing major symptoms. Several prodrugs have demonstrated significant anti-SARS-CoV-2 effects in vitro, in animal models, and in medical practice; their effectiveness in avoiding mortality is limited. Various factors should be considered for prodrug treatment, such as modes of drug administration, optimized combination treatment, prodrug-based lead optimization, and rationalized doses. Because of its rapid viral clearance, improved clinical recovery rate, and availability as an oral medicine with an evidenced safety profile, it is a promising treatment which can be repurposed to treat COVID-19. All prodrugs used for the treatment of aged people reduce the risk of death and hospitalization in unvaccinated and vaccinated patients with COVID-19. Therefore, all prodrugs are suggested for use in patients with the highest risk of hospital admission. Continuing clinical trials on prodrugs worldwide will provide further information on their clinical effectiveness, safety, and therapeutic role in the overall care of COVID-19.
All potential anti-SARS-CoV-2 prodrugs that are activated by phosphorylation play an important role in the treatment of COVID-19. In the majority of systematic reviews, including meta-analyses, remdesivir was not confirmed to be the best antiviral for SARS-CoV-2 infection; nevertheless, a reduction in hospitalization and adverse events in COVID-19 patients was demonstrated. Remdesivir did not significantly reduce mortality or the need for mechanical ventilation, especially compared to a placebo. Furthermore, additional pharmacological trials are being conducted to examine the molecule's efficacy in treating COVID-19. In vitro studies of favipiravir have shown high efficacy against COVID-19 infection using concentrated and safe therapeutic doses. Favipiravir encourages quicker viral clearance, treatment outcomes, and enhanced radiological imaging in hospitalized patients. However, it may not be beneficial for those that are not hospitalized. Monitoring hyperuricemia while taking favipiravir will help to ensure that the medication is terminated as soon as possible. Molnupiravir is only required for a short period (five days) and is easier to administer in an outpatient setting, resulting in higher compliance. The benefit of molnupiravir is that it may be manufactured on a larger scale and does not require cold transportation or administration in hospital settings, unlike other EUA-approved COVID-19 medicines. However, it remains unclear whether molnupiravir is a "miracle" drug. The drug 2-DG was approved for emergency use by the Indian drug authority. It accumulates in virus-infected cells, inhibiting viral reproduction by preventing viral synthesis and energy output. Establishing an online data repository for recording the efficacy and side effects of 2-DG would be tremendously useful in combining data on 2-DG administration in COVID-19. To confirm the early findings, a multicentric study with a larger population and from other geographical regions is needed.