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Background Sickle cell anemia (SCA) is a hereditary disease with defective hemoglobin (Hb) synthesis causing severe hemolytic anemia, pain crisis, and target organ damage. In SCA, several factors independently or in combination lead to derangement in iron stores. Some centers incorrectly prescribe iron therapy on the presumption that SCA would be associated with iron deficiency, but it is not always the case. This study attempts to evaluate the iron status in SCA patients and records the target organ damage present. Methodology A single-center cross-sectional study of 180 patients with sickle cell disease was carried out at a tertiary-care center in Western India. Patients >12 years of age were included in the study after confirming SCA using high-performance liquid chromatography (HPLC). The iron status of each patient was identified and patients were labeled as iron sufficient based on the following values: Hb (8.1-12 gm%), serum iron (S. iron) level (50-150 µg/dl), serum ferritin (S. ferritin) (50-200 ng/ml), and total iron binding capacity (TIBC) (251-450 µg/dl). The iron status of patients with different target organ damage was also analyzed. Results Demographic data revealed that 21-30 years was the most common age group affected by SCA along with a male preponderance. The most common presenting complaint was joint pain (68.9%), the most common sign was pallor (64.4%), most patients had a history of pain crisis (95.6%), and half of the patients had organomegaly (51.1%). Most of the patients had no complications, however, for those who did, hepatopathy (28.9%) was the most common. Conclusion While the majority of patients were iron sufficient, a considerable number had either iron deficiency or iron overload states, which emphasizes the necessity of investigating the iron status before deciding the course of treatment in SCA patients. Although the majority were unaffected, screening for end-organ damage should be carried out in all SCA patients.
RESUMEN
With more than 5 million fatalities and close to 300 million reported cases, COVID-19 is the first documented pandemic due to a coronavirus that continues to be a major health challenge. Despite being rapid, uncontrollable, and highly infectious in its spread, it also created incentives for technology development and redefined public health needs and research agendas to fast-track innovations to be translated. Breakthroughs in computational biology peaked during the pandemic with renewed attention to making all cutting-edge technology deliver agents to combat the disease. The demand to develop effective treatments yielded surprising collaborations from previously segregated fields of science and technology. The long-standing pharmaceutical industry's aversion to repurposing existing drugs due to a lack of exponential financial gain was overrun by the health crisis and pressures created by front-line researchers and providers. Effective vaccine development even at an unprecedented pace took more than a year to develop and commence trials. Now the emergence of variants and waning protections during the booster shots is resulting in breakthrough infections that continue to strain health care systems. As of now, every protein of SARS-CoV-2 has been structurally characterized and related host pathways have been extensively mapped out. The research community has addressed the druggability of a multitude of possible targets. This has been made possible due to existing technology for virtual computer-assisted drug development as well as new tools and technologies such as artificial intelligence to deliver new leads. Here in this article, we are discussing advances in the drug discovery field related to target-based drug discovery and exploring the implications of known target-specific agents on COVID-19 therapeutic management. The current scenario calls for more personalized medicine efforts and stratifying patient populations early on for their need for different combinations of prognosis-specific therapeutics. We intend to highlight target hotspots and their potential agents, with the ultimate goal of using rational design of new therapeutics to not only end this pandemic but also uncover a generalizable platform for use in future pandemics.
