| Literature DB >> 31035595 |
Fedora Grande1, Giuseppina Ioele2, Maria Antonietta Occhiuzzi3, Michele De Luca4, Elisabetta Mazzotta5, Gaetano Ragno6, Antonio Garofalo7, Rita Muzzalupo8.
Abstract
An in-depth analysis of nanotechnology applications for the improvement of solubility, distribution, bioavailability and stability of reverse transcriptase inhibitors is reported. Current clinically used nucleoside and non-nucleoside agents, included in combination therapies, were examined in the present survey, as drugs belonging to these classes are the major component of highly active antiretroviral treatments. The inclusion of such agents into supramolecular vesicular systems, such as liposomes, niosomes and lipid solid NPs, overcomes several drawbacks related to the action of these drugs, including drug instability and unfavorable pharmacokinetics. Overall results reported in the literature show that the performances of these drugs could be significantly improved by inclusion into nanosystems.Entities:
Keywords: HIV; antiretrovirals; drug degradation; drug protection; nanoformulations
Year: 2019 PMID: 31035595 PMCID: PMC6572254 DOI: 10.3390/pharmaceutics11050197
Source DB: PubMed Journal: Pharmaceutics ISSN: 1999-4923 Impact factor: 6.321
Relevant information of currently used RTI. *Year of FDA approval; LS = Lipid Solubility; OB = Oral Bioavailability; t/2 = Plasma Half-life.
| Drug Class | Name | Year* | LS | OB | t/2 (hours) | Side Effects |
|---|---|---|---|---|---|---|
| NRTIs | Stavudine (STV) | 1996 | low | 86 | 1.3–1.4 | Peripheral neuropathy, pancreatitis, asymptomatic acidosis, lipoatrophy, hepatic steatosis |
| Zidovudine (AZT) | 1986 | low | 60 | 0.5–3 | Neutropenia, anemia, nausea, vomiting, asthenia, headache, insomnia, skin hyperpigmentation, acidosis, hepatic steatosis | |
| Lamivudine (3TC) | 1995 | low | 86 | 5–7 | Cough, diarrhea, fatigue, headache, malaise, nasal symptoms, lactic acidosis, hepatic steatosis | |
| Abacavir (ABV) | 1998 | low | 83 | 0.8–1.5 | Systemic respiratory hypersensitivity, gastrointestinal symptoms, fever, tiredness, sore throat | |
| Emtricitabine (FTC) | 2006 | low | 93 | 8–10 | Headache, nausea, upset stomach, diarrhea, trouble sleeping, dizziness, skin rash, strange dreams, cough, runny nose | |
| Zalcitabine (ZCT) | 1992 | low | 85 | Peripheral neuropathy, stomatitis, esophageal ulcerations, acidosis, hepatic steatosis | ||
| Didanosine (DDN) | 1991 | low | 30 | 2 | Gastrointestinal intolerance, peripheral neuropathy, pancreatitis, asymptomatic acidosis, lipoatrophy, hepatic steatosis | |
| Tenofovir (TDF) | 2001 | low | 25-39 | 12–15 | Nausea, depression, confusion, headache, hitching, weakness, kidneys problems | |
| NNRTIs | Nevirapine (NVR) | 1996 | moderate | 92 | 25–30 | Rash, Stevens-Johnson syndrome, elevated transaminases blood level, hepatitis, severe hypersensitivity reaction |
| Efavirenz (EFV) | 1998 | high | 50 | 40–55 | Rash, Stevens-Johnson syndrome, sleep disturbances, dizziness, vertigo, depression, euphoria, difficulty concentrating, hallucination. | |
| Etravirine (ETV) | 2008 | high | -- | 30–40 | Rash, Stevens-Johnson syndrome, toxic epidermal necrosis and multiform erythema, hypersensitivity reactions, hepatic failure | |
| Rilpivirine (RPV) | 2011 | high | 50 | 19 | Rash, depression, liver problems, mood changes |
Figure 1Drug delivery systems for RTI nanoformulations.
Targets of DDS designed for anti-HIV therapy.
| DDS | TARGET | |
|---|---|---|
| Matrix | Surface | |
| Liposome NPs | Mannose | Liver, spleen, lung, brain, macrophages |
| Liposomes | Galactose | Liver |
| Chitosan NPs | Glycyrrhizin | Liver |
| NPs | Transferrin | Brain, endothelial cells |
| NPs | Serum albumin | Brain, liver, spleen |
| SLN | Phenylalanine | Blood brain barrier |
| Polymeric micelles | Anti-GP2 antibody | M-cell of gut-associated lymphoid tissue |
| Dendrimers | Tuftsin | Macrophages, monocytes, polymorph nuclear leukocytes |
Figure 2Representative delivery modalities for NRTI/NNRTI nanosystems to HIV reservoirs.
Advantages and limitations of anti-HIV DDS.
| DDS | Advantages | Limitations |
|---|---|---|
|
| Co-delivery of hydrophilic and lipophilic drug | Low drug loading capacity |
|
| Chemical stability | Physical instability during the storage |
|
| High drug loading capacity | Fast burst release |
|
| Higher stability and biological compatibility than liposomes and polymeric NPs | Low drug solubility in lipid matrix and loading capacity |
|
| Uniform particle size | Toxicity problems |
Figure 3Chemical structures of NRTIs.
Figure 4(a) RT catalyzes the conversion of viral RNA into pro-viral DNA before its incorporation into the target cell genome; (b) NRTIs are incorporated into the DNA causing chain termination; (c) NNRTIs bind the enzyme inhibiting its function.
Figure 5Chemical structures of NNRTI.