ISSN: 0215-6334 | e-ISSN: 1907-770X The Southeast Asian Journal of Tropical Biology Vol.
32 No.
1, 2025: 266 - 276
DOI: 10.
11598/btb.
A COMPREHENSIVE REVIEW ON THE
THERAPEUTIC EFFICACY OF CURCUMIN AND ITS
NANOFORMULATIONS
Iffat Nayila*1.
Sumaira Sharif*2.
Muhammad Sarwar2.
Faima Atta Khan3.
Saima Zaheer4, and Aasma Iqbal5 Department of Pharmacy.
The University of Lahore.
Sargodha.
Pakistan Institute of Molecular Biology and Biotechnology.
The University of Lahore.
Lahore.
Pakistan University Institute of Diet & Nutritional Sciences.
Faculty of Allied Health Sciences.
The University of Lahore.
Sargodha.
Pakistan Department of Chemistry.
The University of Lahore.
Sargodha.
Pakistan Department of Zoology.
The University of Lahore.
Sargodha.
Pakistan A A A A HIGHLIGHTS
ABSTRACT
Curcumin shows strong antiinflammatory, antioxidant, and anticancer effects.
Nanoformulations improve curcuminAos stability, absorption, and effectiveness.
Curcumin nanoparticles may protect against cancer, heart, and brain disorders.
More clinical studies are needed to confirm curcuminAos full therapeutic potential.
Researchers have recently focused on the bioactive components present in natural products.
Over the past two decades, curcumin, the active compound derived from the Curcuma longa plant, has been extensively investigated due to its therapeutic potential as an anti-inflammatory, antioxidant, and anticancer agent.
This review article aims to present the potential and therapeutic activities of curcumin based on its medicinal significance and targeted Its antibacterial, neuroprotective, antioxidant, and anticancer properties are discussed in relation to the biological activities of curcumin.
Despite the promising findings, sufficient evidence supporting the adjunctive use of C.
longa and curcuminbased nanoparticles for the treatment of various inflammatory and infectious disorders is still lacking.
Several nanoformulations have been developed, and their effectiveness has been demonstrated in preclinical studies.
however, further validation through human clinical trials is required before their application in medicine can be established.
In this context, the current review provides an overview of curcumin nanoformulations that may serve as effective alternatives for targeted therapies in the management of various human disorders.
According to the reported literature, nano-gels, nanoemulsions, and nano-creams loaded with curcumin nanoparticles have been proposed for the management of several diseases.
The information presented in this review has been compiled from approximately 300 preclinical and clinical research papers and review articles.
Further studies should focus on optimizing the stability of nanoformulations, improving clinical translation, and enhancing the therapeutic efficacy of curcumin nanoparticles in order to evaluate their potential as candidates for novel drug development in the treatment of various diseases.
Article Information Received : 9 February 2025 Revised : 13 May 2025 Accepted : 21 May 2025 *Corresponding author, e-mail:
nayila5@gmail.
sharif@imbb.
Keywords: anti-inflammatory, anticancer, antimicrobial activity, curcumin nanoparticles, therapeutic activities Bioactive role of curcumin in diseases prevention - Nayila et al.
INTRODUCTION
Due to its numerous therapeutic and medicinal applications.
Curcuma longa is widely recognized not only in Asia but also globally.
Curcumin, the active compound of C.
longa, has been increasingly valued based on various reported studies and clinical trials for its role in managing a wide range of disorders, including diabetes, obesity, bacterial and protozoal infections, and wound healing (Priyadarsini 2.
It has been reported that several strategies have been employed to enhance the pharmacological activity and therapeutic potential of this compound (Fuloria et al.
The genus Curcuma, which has long been utilized for medicinal purposes, comprises approximately 133 species worldwide.
Commonly recognized species of this genus include Curcuma longa (Haridr.
Curcuma zanthorrhiza Roxb.
, and Curcuma zedoaria Rosc.
(Zedoar.
The species longa, a common tall perennial herb belonging to the family Zingiberaceae .
inger famil.
, is predominantly cultivated in tropical climates across Asia (Di Martino et al.
The wellestablished medicinal benefits of C.
longa have been extensively documented in Ayurveda, where it is described in the works of Dashemani as Kusthagna .
nti-dermatosi.
and Visaghna .
nti-poisonou.
(Adamczak et al.
Marchiani et al.
Curcumin, a polyphenol extracted from the turmeric plant (Curcuma long.
, has been extensively investigated for its wide range of pharmacological properties, including anti-ulcer, antioxidant, anti-tumor, anti-inflammatory, and anticancer activities (Islam et al.
CurcuminAos anticancer potential has been attributed to its ability to regulate various immune modulators, such as cytokines and reactive oxygen species (ROS) (Zoi et al.
Nanotechnology-based approaches have been proposed to overcome the limitations associated with conventional curcumin formulations and to facilitate its transition from laboratory research to clinical applications.
Several reputable studies have demonstrated that curcumin-loaded nanoformulations, including nanomedicine-based drug delivery systems, can maximize therapeutic benefits by enhancing pharmacokinetics and bioavailability (Chopra et Multiple curcumin-based nanoformulations have been reported, each with distinct clinical relevance, as they provide controlled drug release and strong biocompatibility.
However, certain limitations remain.
For example, polymeric nanoparticles, such as those derived from PLGA, may exhibit initial burst release problems.
Liposomes, which mimic cell membranes and enhance curcumin absorption, face challenges related to stability and encapsulation efficiency.
Solid lipid nanoparticles are considered highly safe and stable but have a relatively limited drugloading capacity.
Nanomicelles, characterized by their small size and enhanced solubility, are ideal for systemic distribution.
however, their stability under physiological conditions can be inconsistent (Kang et al.
Key formulation parameters, including biodistribution patterns, cytotoxicity in both cancerous and normal cells, and drug release profiles at physiological pH, have been proposed to guide the development of optimized curcuminbased nanocarriers.
Advancements in this area are expected to bridge significant translational gaps in curcumin nanomedicine and contribute substantially to targeted cancer therapy.
These innovations are anticipated to improve clinical outcomes and provide more effective cancer Furthermore, nano-curcumin supplementation has been reported to reduce cardiovascular disease risk by improving lipid profiles and lowering inflammatory markers, as demonstrated in a systematic clinical review (Lin et al.
Preclinical studies also suggest that curcumin nanoparticles may offer neuroprotective effects in neurodegenerative disorders, such as ParkinsonAos and AlzheimerAos diseases, by reducing oxidative stress and preventing protein aggregation (Kumararaja et al.
In addition, curcuminloaded nanoparticles have shown enhanced tumor suppression and reduced metastasis in models of nasopharyngeal and hepatic cancers (Xue et al.
Research is still ongoing to improve the safety, stability, and therapeutic efficacy of these formulations.
This review highlights the pharmacological activities of curcumin and provides a comprehensive overview of recent advancements in C.
longa research, with particular emphasis on the development of nano-carriers to enhance curcumin bioavailability and address existing challenges in drug delivery.
The purpose of this review paper is to provide researchers with easy and quick access to information regarding previously reported and utilized phytochemicals.
A comprehensive literature BIOTROPIA Vol.
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2, 2025
search was conducted using search engines such as Google Scholar.
Scopus.
ProQuest, and Molecules to compile this review on the phytochemistry and pharmacological applications of curcumin.
This review is intended to address existing research gaps and to highlight areas where new strategies need to be developed.
Furthermore, the article presents an extensive overview of numerous curcuminbased nanoformulations, both individually and in combination, according to their potential health benefits, mechanisms of action, and targeted pathways in the treatment of various diseases.
REVIEW
Therapeutic Applications It has been observed that curcumin can modulate a wide range of molecular targets that are associated with the underlying causes of numerous human Figure 1 illustrates the therapeutic potential of curcumin across major categories of medical illnesses.
The multifaceted properties of curcumin are emphasized, underscoring its relevance in the treatment and prevention of various Curcuma longa Linnaeus, commonly known as turmeric (Family: Zingiberaceae.
Genus: Curcuma.
Species: long.
within the Plantae kingdom and the Magnoliophyta division (Rai et al.
, has been widely studied for its medicinal value.
Curcumin, the principal bioactive compound of Curcuma longa, has been reported to possess diverse therapeutic applications, ranging from the treatment of cancer to the management of coughs and colds (Mundekkad & Cho 2.
Studies on curcumin-based formulations (Table .
have demonstrated that Curcuma longa exhibits multiple pharmacological benefits and exerts significant anticancer activities against various cell Anticancer Potential Curcumin has been reported to produce significant outcomes, including an increased percentage of drug sensitivity, in overcoming medication resistance frequently observed in breast, ovarian, lung, and other cancer types (Amaroli et al.
In breast cancer cell lines, the overexpression of flap endonuclease 1 (FEN.
has been associated with increased resistance to the chemotherapeutic drug cisplatin.
It has been discovered that curcumin enhances the sensitivity of breast cancer cells to cisplatin through the downregulation of FEN1 expression in vitro (Zou et al.
Apoptosis was also observed in MCF-7 Figure 1 Health benefits and therapeutic applications of curcumin Progress in the anti-proliferative activity Rats model HCT116 and MCF-7 cells CUR-loaded silk NPs Curcumin extract formulation Multiple myeloma animal model with Pancreatic cancer melanoma model NPs Curcumin in Pre-clinical Murine Curcumin-loaded BSA gastrointestinal tract In vitro simulated Mouse model Cur- NLCs Curcumin-zein/rhamnolipid complex HeLa cells in clinical trial CUR-Loaded Nano gels SSPS-NPs Longer the plasma circulation time Caco-2 cells Curcumin-dextran NP (Xue et al.
(Kang et al.
(Tran et al.
(Pan et al.
(Jianbing et al.
(Fan et al.
(Das et al.
Reference Reduced levels of urinary N-telopeptide and Bone (Golombick et al.
turnover Marker Curcumin dose .
g/da.
was detected as above the (Kanai et al.
extreme tolerated dose Increase in the survival rate and minimization in (Camargo et al.
tumor size Protect hydrophobic bioactive compounds Reducing the pro-inflammatory cytokines Enhanced therapeutic efficacy Better stability and antioxidant activity of curcumin Improved cellular uptake enhanced the cytotoxicity A549 cells Curcumin linked HSA NPs Significance Cell Line/animal model/cancer Curcumin formulation Table 1 A few clinical studies on curcumin formulations with potential outcomes Bioactive role of curcumin in diseases prevention - Nayila et al.
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and MCF-7-DDP cells treated with curcumin.
cells exposed to 2 g/mL cisplatin combined with 20 mol/L curcumin, a significantly higher degree of apoptosis was recorded in the combination treatment group compared to cisplatin treatment alone (P < 0.
These findings suggest that the combined use of cisplatin and curcumin may enhance the susceptibility of breast cancer cells to cisplatin (Ke et al.
Similarly, it has been demonstrated that curcumin, when used together with cisplatin, can overcome cisplatin resistance in lung cancer by promoting apoptosis and inhibiting cell proliferation (Priyadarsini 2.
With an ICCICA at the micromolar level, it was observed that curcumin significantly suppressed the proliferation of several cancer cell lines, including T47D.
MCF7, and MDA-MB-231 .
< 0.
These findings indicate that curcumin possesses strong anticancer properties.
Cell cycle arrest at the G2/M phase was reported following curcumin treatment, as determined through a comprehensive investigation of its mechanism of action (Shan et Among the numerous biological effects of curcumin, its ability to stimulate the production of phase II and antioxidant enzymes through Nrf2dependent pathways has been highlighted.
Due to its rapid metabolism and low bioavailability, curcumin has been extensively investigated in several clinical trials (Deck et al.
The outcomes were found to demonstrate modest hemolytic and cytotoxic activities against eukaryotic cells, along with enhanced antibacterial and anticancer properties (Adahoun et al.
was also discovered that neither the extract nor the synthetically prepared gold nanoparticles (GNP.
exhibited any cytotoxic effects on the HeLa or L929 cell lines (Das et al.
According to a study, in both scratch and Transwell migration tests, the curcuzederone molecule, a phytocompound of C.
longa, was found to significantly inhibit the migration of MDA-MB-231 cells (P < 0.
and reduce cancer cell proliferation (Al-Amin et al.
Based on these reported studies, curcumin is believed to exhibit anticancer properties through multiple mechanisms, including anti-angiogenic effects, induction of apoptosis, disruption of tumor cells, and prevention of tumor invasion into healthy Antioxidant Potential By improving mitochondrial function, reducing reactive oxygen species (ROS), and curcumin has been shown to alleviate conditions associated with oxidative stress and mitochondrial dysfunction (Roohi et al.
Recent studies have demonstrated that disorders related to mitochondrial dysfunction and oxidative stress can be mitigated by curcumin.
It has been indicated that curcumin may provide therapeutic benefits for certain metabolic disorders (Sathyabhama et al.
At low and intermediate doses, curcumin has been reported to decrease ROS either by upregulating Nrf2 protein levels or by enhancing the activities of SOD.
CAT, and GSH-Px.
The resulting increase in cellular capacity to eliminate ROS contributes to the preservation of oxidative stress resistance, potentially reducing apoptosis and improving cell survivability (Lin et al.
clinical models of neuroinflammation, diabetes, and cardiovascular disease, curcumin has been observed to significantly lower oxidative stress enzymes and ROS levels by directly scavenging free radicals and enhancing endogenous antioxidant defenses (Karamalakova et al.
In untrained, healthy men, oxidative damage is caused by sudden, intense exercise.
Oral administration of curcumin for one week has been shown to reduce lipid peroxidation and potentially enhance the intracellular antioxidant system (Roohi et al.
Antioxidant activity in the study was assessed using the 1,1-diphenyl2-picrylhydrazyl (DPPH) free radicalAescavenging The ethanolic extract of ChittagongAos mura was found to contain the highest concentrations of ascorbic acid .
09 mg/100 .
, polyphenols .
07%), and flavonoids .
66%) (Tanvir et al.
Several strategies can be employed to achieve this goal, in addition to using micelles for targeting curcumin to mitochondria.
For instance, the introduction of various nanocarriers and the development of curcumin derivatives that specifically target mitochondria have been explored (Hu et al.
The growth of stomach tumor cells has been inhibited by curcumin micelles both in vivo and in vitro.
This effect is believed to involve increased reactive oxygen species (ROS) production, disruption of redox homeostasis, and modulation of mitochondrial bioenergetics (Lin et al.
Numerous studies have reported Bioactive role of curcumin in diseases prevention - Nayila et al.
reductions in various inflammatory indicators, and the anti-inflammatory and antioxidant properties of curcumin are considered to mediate its beneficial effects on stress markers, inflammatory markers, ulcers, and osteoarthritis.
Anti-Ulcer Potential Curcumin has been proposed as a potential protective agent against inflammatory diseases, including cancer and ulcers.
These biological effects are attributed to its antioxidant, antimicrobial, and anti-inflammatory properties.
Based on the literature, it can be concluded that gastrointestinal ulcers are prevented by curcumin, and that the compound represents a unique therapeutic option for ulcer treatment (Yadav et al.
When compared to the control groups, the growth and colony formation of gastric tumor cells were dramatically reduced by curcumin micelles, and apoptosis was induced (Panda et al.
In the repair of indomethacin-induced gastric ulcers (GU), an oral administration of a chitosan-curcumin mixture was found to be more effective than curcumin, chitosan, or lansoprazole, a conventional antiulcer drug (Kuadkaew et al.
In a separate study, no acute toxicity was observed in rats treated with a metal-curcumin complex (MCC).
The results indicated that MCC acted as a more efficient scavenger than curcumin.
At an oral dose of 100 mg/kg, gastro-protective efficacy against ethanol-induced ulcers in rats was demonstrated by MCC (Joshi et al.
Further investigation revealed that curcumin micelles affected mitochondrial proteins in gastric tumor cells, altering mitochondrial function and influencing mitochondrial bioenergetics (Panda et Hepatoprotective Potential The antioxidant properties of curcumin are believed to prevent CClCE-induced secondary hepatic cytochrome P450 (CYP) damage.
It has been reported that curcumin functions as an antioxidant and inhibits NF-B activation, thereby preventing liver injury caused by CClCE (Perrone et Except at a concentration of 5 g/kg/day, no significant changes in hepatic cytochrome P450 levels or activity were observed following curcumin administration, according to a previous study (Sugiyama et al.
In contrast, the activity of these isoenzymes, particularly cytochrome P450 2E1 (CYP2E.
, was significantly reduced (P < .
by CClCE, resulting in elevated free radical Pretreatment with curcumin at a dose 5 g/kg/day markedly inhibited the effects of CClCE.
Liver protection was conferred by Curcuma longa L.
(CLL) extract, which also significantly decreased plasma bilirubin (BL), gamma-glutamyl transpeptidase (GGT), and lipid peroxidation Consequently, the CLL extract may be utilized as an antioxidant in the treatment of chronic hepatotoxicity (Karamalakova et al.
Furthermore, compared to free curcumin .
mg/k.
, silymarin .
mg/k.
, and self-recovery groups, curcumin-loaded solid lipid nanoparticles (C-SLN.
5 mg/kg significantly (P < 0.
reduced histological alterations and oxidative stress (Xu et al.
Hepatotoxicity was evidenced by histological alterations in the liver induced by arsenic, which also elevated serum aspartate and alanine aminotransferase activities.
In the liver, arsenic decreased the activities of glutathione reductase, catalase, and glutathione peroxidase, while increasing lipid peroxidation and depleting reduced glutathione.
The effects of arsenic were mitigated by curcumin and its nanoparticleencapsulated form (CUR-NP) in a preclinical trial, with the amelioration being more pronounced in the CUR-NP treatment.
These findings indicate that curcumin administered in nano-encapsulated form produces greater protective effects than free curcumin (Lin et al.
With stronger protective benefits demonstrated by CUR-NP, hepatotoxicity can be substantially reduced through restoration of antioxidant enzyme activity, reduction of lipid peroxidation, and improvement of liver histology.
The bioactive potential of curcumin in preventing hepatotoxicity may be further elucidated through carefully designed clinical trials (Perrone et al.
Moreover, in the context of ulcer and cancer treatment, such trials could provide critical insights into the optimal therapeutic use of curcumin, ultimately enhancing patient outcomes and overall well-being.
Anti-Coagulant Therapeutic Activity Blood coagulation occurs within arteries under various conditions, which can disrupt blood flow or cause internal bleeding that may occasionally be fatal.
Therefore, anticoagulants are typically administered to prevent blood clotting in such situations.
Additionally, inflammation has been shown to increase the risk of blood coagulation by activating molecules that promote clot formation (Chopra et al.
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trials, curcuminAos anticoagulant activity was demonstrated by comparing thromboplastin time and thrombin time analyses with control blood samples, revealing that curcumin prolongs blood clotting times.
Both curcumin and its derivative, bisdemethoxycurcumin, were found to significantly extend prothrombin time and activated partial thromboplastin time while inhibiting the activities of activated factor X and thrombin (Sirisidthi et al.
Similarly, the anticoagulant effect of curcumin has been investigated, revealing that the presence of its hydrophobic groups contributes to a reduction in clotting time in both prothrombin time (PT) and activated partial thromboplastin time (APTT) The ortho-methoxy group, also present in curcumin, has been shown to enhance its anticoagulant activity.
Furthermore, a decrease in white blood cell (WBC) count was observed, which consequently reduced platelet aggregation and inhibited the formation of fibrin deposits in the kidneys.
Therefore, curcumin, when combined with nanotechnology, is considered a potential anticoagulant and preventive agent for thrombotic disorders (Keihanian et al.
Neuroprotective Potential It has been suggested that effective prophylaxis is highly desirable, as neuroprotective strategies are most effective when applied prior to the onset of damage (Nebrisi 2.
Among its pleiotropic actions, curcumin exhibits anti-inflammatory properties, a favorable safety profile, and potential neuroprotective efficacy (Cole et al.
The pharmaco-therapeutic potential of curcumin in cerebral ischemia, including its molecular mechanisms of neuroprotection, has been reviewed in animal models, and it has been observed that curcumin represents a promising therapeutic candidate for cerebral ischemia, demonstrating parameters (Lalita & Bhakta 2.
Gold nanoparticles functionalized with curcumin have been shown to effectively interact with amyloid proteins and peptides, inhibit amyloid fibrillation, and disintegrate amyloid fibrils by acting as synthetic molecular chaperones (Yallapu et al.
The desolvation technique was successfully employed to produce curcuminloaded -lactalbumin (-LA) nanoparticles, targeting a particle size range of 100 - 150 nm.
The resulting formulation, -LA-Curcumin, has been demonstrated to provide protection against permethrin-induced neurotoxicity.
Upon application of -LA-Curcumin, the generation of ROS induced by permethrin was reduced, thereby mitigating cellular damage (Paulpandi et al.
NF-B mRNA expression was significantly downregulated following administration of caffeine-mediated nano-curcumin (N-CUR), while TNF- and IL-6 levels, as well as SOD activity, were significantly improved.
N-CUR has been reported to exert mild to moderate beneficial effects on caffeine-induced inflammatory responses, oxidative stress, and apoptosis in the brain (Morsy et al.
The neuroprotective effects of curcumin are believed to be mediated through multiple mechanisms, including modulation of oxidative stress, excitotoxicity, neuroplasticity, hypothalamic-pituitary-adrenal axis imbalances, and neurotransmitter levels (Nebrisi 2.
Therapeutic Efficacy Against Stroke The effectiveness of the curcumin formulation was evaluated using assessments of grip strength, locomotor activity, and brain chemistry (Yallapu et al.
Improvements in outcomes following brain injury have been reported to be potentially mediated by curcumin through the regulation of Th17 cell development.
Twenty-four hours after the onset of stroke.
T cells, which play a detrimental role in the ischemic response, were observed to infiltrate the region of ischemic damage.
The endogenous apoptosis pathway was shown to be directly influenced by the p53 signaling pathway through interactions with multi-domain members of the Bcl-2 family (Du et al.
Marques et al.
In a study, therapeutic potential in cerebral stroke was demonstrated by the epigenetic agent curcumin, which was delivered via 200 nmsized exosomes.
Behavioral, oxidative stress, and physiological parameters were effectively reduced by curcumin, indicating its protective effects against cerebral ischemic insult (Yallapu et al.
Although curcumin has shown promise in animal stroke models, the mechanisms by which it influences microglial polarization and promotes long-term stroke recovery remain unclear.
It was observed that, three days after dMCAO, cerebral ischemic damage was markedly reduced following curcumin post-treatment (Liu et al.
Bioactive role of curcumin in diseases prevention - Nayila et al.
Antitumor Potential Lysosomes represent a significant class of membrane-bound organelles within the intracellular membrane system.
They are involved in immunological modulation, cellular metabolism, and programmed cell death, among other biological processes that influence tumor development and Lysosomal activity has been shown to be modulated by curcumin, thereby affecting drug resistance, immune function, invasion, metastasis, and tumor proliferation (Zeng et al.
Tumor growth can be effectively inhibited by curcumin.
The transcription of ribosomal DNA .
DNA) into ribosomal RNA .
RNA), which promotes cell growth and proliferation, is regulated upstream by mTORC1.
Curcumin has been demonstrated to inactivate mTORC1 through the suppression of mTOR lysosomal localization (Xu et al.
The encapsulation of curcumin in Eudragit S100 polymer nanoparticles has been shown to influence cellular uptake and to enhance anticancer potential two-fold in the HT-29 human colorectal cell line.
Innovative formulations have enabled a multi-theranostic strategy, incorporating both therapeutic and imaging functions (Yallapu et Furthermore, chemo-resistance in tumor cells has been demonstrated to be re-sensitized by curcuminoids through the downregulation of Bcl-2 and DNA repair enzymes (Lin et al.
Additionally, further efforts should be devoted to the development of multimodal anticancer therapy strategies in future research by combining standard chemotherapy regimens with curcumin derivatives, analogs, and nano-formulations (Mohamadian et Antimicrobial Potential The synthesis, characterization, and application of curcumin-capped magnetic nanoparticles have been investigated.
It has been demonstrated that the interaction between curcumin and magnetic nanoparticles, which occurs through the carbonyl groups of the polyphenol structure, alters the structural, photochemical, and magnetic properties of the polyphenols using various analytical This novel material has been shown to possess the potential to photo-inactivate Grampositive bacteria, including Staphylococcus aureus (Cayon-Ibarra et al.
Compared to Escherichia coli and Bacillus cereus, a greater antibacterial activity in vitro has been exhibited by curcumin nanoparticles .
urcuminNP.
against Staphylococcus aureus.
Pathogens in chicken fingers were successfully suppressed by curcumin-NPs during storage for up to 27 After storage, reductions in total volatile basic nitrogen (TVB-N) levels were observed in chicken samples treated with curcumin-NPs.
The bioactive properties, antioxidant capacity, antibacterial activity, and chemical indicators of these experiments validated the efficacy of nanocurcumin at a dose of 10 g/g (Morsy et al.
Overall, nanotechnology has been shown to enhance material efficacy and address issues associated with the use of natural additives in the meat industry, which could otherwise alter the sensory qualities of meat products.
Consequently, improvements in the microbiological quality of poultry meat, including extended shelf life and reduced lipid oxidation, have been demonstrated by curcumin-NPs (Morsy et al.
Although the signaling pathways utilized by curcumin nanoformulations to treat human diseases are well characterized, appropriate human dosage evaluations remain unavailable and should be The therapeutic efficacy of curcumincontaining nanocomposites has been shown to surpass that of nanocurcumin or free curcumin (Chopra et al.
Numerous conceptual preclinical studies have been published.
these findings should be verified through higherlevel animal studies or clinical trials.
CONCLUSION
Curcumin nanoparticle-based formulations exhibit significant therapeutic potential, with demonstrated effects on anticoagulation, fibrinolysis, oxidative stress, antimicrobial activity, and cancer treatment.
The molecular mechanisms underlying these effects have been identified, and further research is required to advance curcuminAos development as a clinically effective therapeutic agent.
ACKNOWLEDGMENT
Gratitude is extended to Iffat Nayila for conceptualization and manuscript writing.
Sumaira Sharif and Muhammad Sarwar for providing resources.
to Iffat Nayila.
Sumaira Sharif, and Saima Zaheer for data curation and manuscript editing.
and to Sumaira Sharif.
Faima Atta Khan, and Aasma Iqbal for supervision and guidance throughout the study.
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REFERENCES