Chronic Inflammation’s Transformation to Cancer: A Nanotherapeutic Paradigm
Abstract
:1. Introduction
2. Inflammatory Factors Involved in Cancer Transformation
2.1. Macrophages and Denticles Cells
- By enhancing the angiogenic tumor potential factors such as IL-8, VEGF, and MIF, and by promoting lymph-angiogenesis
- Progression in the growth of tumor
- Tumor cell invasion, migration, and intravasation at primary sites JAM, and they act on endothelial cells, further promoting the tumor’s neovascularization [23].
2.2. Proinflammatory Cytokinesis
2.3. Tumor Necrosis Factor α
2.4. Interleukin
3. Inflammatory Signaling Pathways
3.1. Intrinsic Pathway
3.2. Extrinsic Pathway
3.3. Transcription Factors (NF-kB)
3.4. JAK/STAT Pathway
3.5. COX Pathway
4. Cancer-Associated Inflammatory Diseases and Nanotherapy
4.1. Hepatitis
Cancer-Linked Inflammatory Disease and Cancer | Nanoparticles | Size | Probe/Target | Action | References |
---|---|---|---|---|---|
Hepatitis | ZnO NPs | 5–50 nm | Zinc NPs binds to viral RNA | Promising in the inhibition of viral replication, when examined on HUH 7 cells against hepatitis C and E viruses | [81] |
Hepatitis B | Au NPs | 50 nm | Gold NPs-antibody detect hepatitis viral antigen | They target hepatitis B antigen surface to detect the hepatitis B virus present in human serum, via antibody-antigen interaction assays | [82] |
Hepatitis C | Amphimedon-Ag NPs | 8.22–14.30 nm | NA | They have outstanding anti-HCV, Non-structural protein S drug activity | [83] |
Hepatitis B | Ag NPs | 10 nm | Silver NPs binds to viral RNA and halts replication | They were found to reduce the formation of extracellular HBV DNA and inhibit RNA and virions when observed on HepAD38 cells | [84] |
Hepatic Cancer | Ag NPs | 13 ± 1 nm | NA | Inhibition of cytotoxic effects of hepatic cancer at a concentration of 10–200μg/mL on Hep-G2 cells and MCF-7 cells | [85] |
Hepatitis | Ag/thiol graphene dots nanocomposite | NA | Riboflavin as a probe | Detection of hepatitis core antigen and use of riboflavin as a redox core probe | [86] |
Hepatic cancer | Ag NPs | 20–50 nm | NA | They have a potent Cytotoxic effect on human hepatic cancer cells (Huh-7 cells and CHANG) at 0, 5, 20, 40, and 100μg/mL concentration | [87] |
IBD | P@QD-MdC NPs | 150 nm | Antibody (Anti-MAd CAM-1) | Holds promising outcomes for IBD diagnosis and imagining at an early stage | [88] |
IBD | Ginger-derived NPs | ~230 nm | Ginger NPs found to have lipids, proteins that binds to cancer cells receptor | They are prominent in the reduction of the effect of acute colitis, repair of intestinal cells, and prevention of chronic colitis-associated cancer | [89] |
IBD | Eudragit-Mesoporous Silica nanocomposite | ~150 nm | Polymer Eudragit | At an oral dose of 0.2 mg/kg, found to prevent and improve IBD and colitis-associated cancer treatments, reduce the mRNA expression of cytokines (IL-1β, IL-10 and 17), and be effective in the therapy of IBD | [90] |
IBD and gastrointestinal disease | Dextran-coated cerium oxide NPs | 17.5 ± 0.7 nm and 4.8 ± 1.2 nm (core) | Ceramic oxide encapsulated | For imagining IBD and as a computed tomography agent to give an image of the gastrointestinal tract affected with IBD | [91] |
Pancreatic Cancer | Ag NPs | 2.6 and 18 nm | NA | Decreased cellular proliferation in PANC-1 cells and higher cytotoxic effect of Ag NPs on human pancreas ductal adenocarcinoma (PANC-1 cells) | [92] |
Pancreatic Cancer | Au Nanorods | >6 nm | Polymer (bovine serum albumin) and SiO2 encapsulated | They have applications in bio-imagining and cancer therapy | [93] |
Pancreatic Cancer | PEG-ZnO NPs | 21.8 ± 0.86 nm | Polyethylene glycol encapsulated | Observe to down-regulate the expression of anti-apoptotic BCL2 and up-regulated pro-apoptotic BAX, and found to have excellent anti-cancer activity on PANC-1 cells | [94] |
Pancreatic Cancer | Au NPs | 20 nm | Citrate-capped Au NPs | Inhibits proliferation and tumor growth in both pancreatic cancer cells and pancreatic stellate cells | [95] |
4.2. Pancreatic Cancer
Nanoparticle | Size | Role of Action | References |
---|---|---|---|
PLGA NPs | 350–410 nm | It provides immunotolerance to cancer. It was found to induce anti-tumor therapeutic effects. CD8 T cells secreted interferons at the site of lymph nodes and spleen, and vaccinated mice were treated with PLGA NPs. | [104] |
β-Glucan NPs (BG34-Fe3O4 conjugated carbon nanotubes) | 80–100 nm (Length) 10–20 nm (Diameter) | β-glucan from the cell wall of natural sources such as plants and fungi, have appeared to enhance anti-tumor responses through direct interaction with immune cells such as macrophages and others. It acts as an immune modulator in optimizing tumor microenvironments. | [105] |
Anti-PD-L-1 targeted nanoplatform consists of Au-SPIO@PLGA NPs | 500 nm | It was found to achieve the promotion of polarization of TAM to M1 (classically activated macrophages) and reverse the cause of immunosuppression by TAM and block the programmed death-ligand 1/Programmed cell death pathway. | [106] |
F Conjugated–PLGA NPs | 500 nm | The efficient and specific T-cell targeting drug delivery binding system in vitro in human cells. In vivo, it allows specific targeted delivery of an inhibitor of TGFβR1 and TLR 7/8 agonist, found to delay the growth of tumors in mice, when delivered via Programmed cell death-1 protein targeting NPs. | [107] |
CD44TA-LIP NPs (Liposomes targeting CD44 receptor using Thioaptamers) | 204.9 | Found to exhibit a host defense mechanism against invading pathogens (TB immunopathogenesis) activate lymphocytes, and provide immunity against tuberculosis in mice. | [108] |
Zn-pyrophosphate NPs loaded with photosensitizer pyrolipid (Zn P@Pyro) | NA | It can kill tumor cells, induces apoptosis, and tumor-specific cytotoxic T-cell responses, and disrupt tumor vasculature. It significantly prevents the metastasis of tumors to the lungs of mice. | [109] |
PLGA NPs-based vaccine | 350–410 nm | It induces specific anti-tumor T-cell responses and activates INF-γ secretion at lymph nodes by activation of CD8+, TRP2 specific T-cells of vaccinated mice bearing melanoma B16 tumors. | [104] |
Cytosine-phosphate-guanine coated NPs | NA | It shows rapid accumulation by Antigen-presenting cells and triggers the release of cytokines (IL-10). Induces strong anti-inflammatory responses, enhances TH1/TH2 responses, and eliminates tumor cells. | [110] |
Nano-artificial APC iron-dextran coated NPs | 50–100 nm | It was found to enhance antigen-specific T-cell proliferation in vitro and inhibition/clearance of tumor growth | [111] |
4.3. Inflammatory Bowel Disease (IBD)
5. Conclusions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
Sample Availability
References
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Sohrab, S.S.; Raj, R.; Nagar, A.; Hawthorne, S.; Paiva-Santos, A.C.; Kamal, M.A.; El-Daly, M.M.; Azhar, E.I.; Sharma, A. Chronic Inflammation’s Transformation to Cancer: A Nanotherapeutic Paradigm. Molecules 2023, 28, 4413. https://doi.org/10.3390/molecules28114413
Sohrab SS, Raj R, Nagar A, Hawthorne S, Paiva-Santos AC, Kamal MA, El-Daly MM, Azhar EI, Sharma A. Chronic Inflammation’s Transformation to Cancer: A Nanotherapeutic Paradigm. Molecules. 2023; 28(11):4413. https://doi.org/10.3390/molecules28114413
Chicago/Turabian StyleSohrab, Sayed Sartaj, Riya Raj, Amka Nagar, Susan Hawthorne, Ana Cláudia Paiva-Santos, Mohammad Amjad Kamal, Mai M. El-Daly, Esam I. Azhar, and Ankur Sharma. 2023. "Chronic Inflammation’s Transformation to Cancer: A Nanotherapeutic Paradigm" Molecules 28, no. 11: 4413. https://doi.org/10.3390/molecules28114413
APA StyleSohrab, S. S., Raj, R., Nagar, A., Hawthorne, S., Paiva-Santos, A. C., Kamal, M. A., El-Daly, M. M., Azhar, E. I., & Sharma, A. (2023). Chronic Inflammation’s Transformation to Cancer: A Nanotherapeutic Paradigm. Molecules, 28(11), 4413. https://doi.org/10.3390/molecules28114413