5 results on '"Wenlei Jiang"'
Search Results
2. iBCS: 1. Principles and Framework of an Inhalation-Based Biopharmaceutics Classification System
- Author
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Jayne E. Hastedt, Per Bäckman, Antonio Cabal, Andy Clark, Carsten Ehrhardt, Ben Forbes, Anthony J. Hickey, Guenther Hochhaus, Wenlei Jiang, Stavros Kassinos, Philip J. Kuehl, David Prime, Yoen-Ju Son, Simon Teague, Ulrika Tehler, and Jennifer Wylie
- Subjects
Pharmaceutical Preparations ,Solubility ,Administration, Inhalation ,Drug Discovery ,Administration, Oral ,Pharmaceutical Science ,Molecular Medicine ,Permeability ,Biopharmaceutics - Abstract
For oral drugs, the formulator and discovery chemist have a tool available to them that can be used to navigate the risks associated with the selection and development of immediate release oral drugs and drug products. This tool is the biopharmaceutics classification system (giBCS). Unfortunately, no such classification system exists for inhaled drugs. The perspective outlined in this manuscript provides the foundational principles and framework for a classification system for inhaled drugs. The proposed classification system, an inhalation-based biopharmaceutics classification system (iBCS), is based on fundamental biopharmaceutics principles adapted to an inhalation route of administration framework. It is envisioned that a classification system for orally inhaled drugs will facilitate an understanding of the technical challenges associated with the development of new chemical entities and their associated new drug products (device and drug formulation combinations). Similar to the giBCS, the iBCS will be based on key attributes describing the drug substance (solubility and permeability) and the drug product (dose and dissolution). This manuscript provides the foundational aspects of an iBCS, including the proposed scientific principles and framework upon which such a system can be developed.
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- 2022
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3. Evaluation of the Physicochemical Properties of the Iron Nanoparticle Drug Products: Brand and Generic Sodium Ferric Gluconate
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Marc B. Taraban, Wenlei Jiang, Jason D. Rodriguez, Sharon Batelu, Maureen A. Kane, Sarah L. J. Michel, Joel E P Brandis, Kyle C. Kihn, David P. Goldberg, Yihua Bruce Yu, Timothy L. Stemmler, Julia Schnorr, Dajun Sun, Alex M. Confer, James E. Polli, and Peter Langguth
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Quality Control ,Drug ,Chemistry, Pharmaceutical ,media_common.quotation_subject ,Iron oxide ,Pharmaceutical Science ,Equivalence Trials as Topic ,02 engineering and technology ,Ferric Compounds ,030226 pharmacology & pharmacy ,Gel permeation chromatography ,03 medical and health sciences ,chemistry.chemical_compound ,0302 clinical medicine ,Pharmacokinetics ,Dynamic light scattering ,Generic drug ,Drug Discovery ,Drugs, Generic ,Humans ,Inductively coupled plasma mass spectrometry ,media_common ,Anemia, Iron-Deficiency ,021001 nanoscience & nanotechnology ,Small molecule ,Dynamic Light Scattering ,chemistry ,Chromatography, Gel ,Nanoparticles ,Molecular Medicine ,0210 nano-technology ,Ultracentrifugation ,Nuclear chemistry - Abstract
Complex iron nanoparticle-based drugs are one of the oldest and most frequently administered classes of nanomedicines. In the US, there are seven FDA-approved iron nanoparticle reference drug products, of which one also has an approved generic drug product (i.e., sodium ferric gluconate (SFG)). These products are indicated for the treatment of iron deficiency anemia and are administered intravenously. On the molecular level, iron nanomedicines are colloids composed of an iron oxide core with a carbohydrate coating. This formulation makes nanomedicines more complex than conventional small molecule drugs. As such, these products are often referred to as nonbiological complex drugs (e.g., by the nonbiological complex drugs (NBCD) working group) or complex drug products (e.g., by the FDA). Herein, we report a comprehensive study of the physiochemical properties of the iron nanoparticle product SFG. SFG is the single drug for which both an innovator (Ferrlecit) and generic product are available in the US, allowing for comparative studies to be performed. Measurements focused on the iron core of SFG included optical spectroscopy, inductively coupled plasma mass spectrometry (ICP-MS), X-ray powder diffraction (XRPD), 57Fe Mossbauer spectroscopy, and X-ray absorbance spectroscopy (XAS). The analysis revealed similar ferric-iron-oxide structures. Measurements focused on the carbohydrate shell comprised of the gluconate ligands included forced acid degradation, dynamic light scattering (DLS), analytical ultracentrifugation (AUC), and gel permeation chromatography (GPC). Such analysis revealed differences in composition for the innovator versus the generic SFG. These studies have the potential to contribute to future quality assessment of iron complex products and will inform on a pharmacokinetic study of two therapeutically equivalent iron gluconate products.
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- 2021
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4. Snapshots of Iron Speciation: Tracking the Fate of Iron Nanoparticle Drugs via a Liquid Chromatography–Inductively Coupled Plasma–Mass Spectrometric Approach
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Jeffrey C. Fink, Nan Zheng, Ann B. Zimrin, Dajun Sun, James E. Polli, Maureen A. Kane, Sarah L. J. Michel, Joel E P Brandis, Wenjing Li, Anne M.C. Williams, Wenlei Jiang, Sergei A Alexishin, and Heather M. Neu
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Drug Compounding ,Iron ,Pharmaceutical Science ,Nanoparticle ,02 engineering and technology ,Sodium ferric gluconate ,Ferric Compounds ,Sensitivity and Specificity ,030226 pharmacology & pharmacy ,Mass Spectrometry ,Article ,03 medical and health sciences ,0302 clinical medicine ,Pharmacokinetics ,Drug Discovery ,Drugs, Generic ,Humans ,Nanotechnology ,Chromatography ,Chemistry ,021001 nanoscience & nanotechnology ,Small molecule ,Mass spectrometric ,Healthy Volunteers ,Data Accuracy ,Iron nanoparticle ,Nanomedicine ,Nanoparticles ,Molecular Medicine ,Administration, Intravenous ,Inductively coupled plasma ,0210 nano-technology ,Chromatography, Liquid - Abstract
Nanomedicines are nanoparticle-based therapeutic or diagnostic agents designed for targeted delivery or enhanced stability. Nanotechnology has been successfully employed to develop various drug formulations with improved pharmacokinetic characteristics, and current research efforts are focused on the development of new innovator and generic nanomedicines. Nanomedicines, which are often denoted as complex or nonbiological complex drugs, have inherently different physicochemical and pharmacokinetic properties than conventional small molecule drugs. The tools necessary to fully evaluate nanomedicines in clinical settings are limited, which can hamper their development. One of the most successful families of nanomedicines are iron-carbohydrate nanoparticles, which are administered intravenously (IV) to treat iron-deficiency anemia. In the U.S., the FDA has approved six distinct iron-carbohydrate nanoparticles but only one generic version (sodium ferric gluconate for Ferrlecit). There is significant interest in approving additional generic iron-carbohydrate drugs; however, the lack of a direct method to monitor the fate of the iron nanoparticles in clinical samples has impeded this approval. Herein we report a novel liquid chromatography–inductively coupled plasma–mass spectrometry (LC–ICP–MS) method that allows for the direct quantification of the iron-carbohydrate drugs in clinical samples, while simultaneously measuring the speciation of the iron released from the nanoparticles in biological samples. To our knowledge, this is the first time that iron nanoparticles have been observed in clinical samples, opening the door for direct pharmacokinetic studies of this family of drugs. This method has potential applications not only for iron-nanoparticle drugs but also for any nanomedicine with an inorganic component.
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- 2019
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5. A PEGylation-Free Biomimetic Porphyrin Nanoplatform for Personalized Cancer Theranostics
- Author
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Cheng S. Jin, Wenlei Jiang, Qiaoya Lin, Fan Wang, Gang Zheng, Nidal Muhanna, Juan Chen, Huang Huang, Liyang Cui, Jonathan C. Irish, and Lili Ding
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Male ,Models, Molecular ,Biodistribution ,Fluorescence-lifetime imaging microscopy ,Porphyrins ,Materials science ,medicine.medical_treatment ,General Physics and Astronomy ,Photodynamic therapy ,Nanotechnology ,02 engineering and technology ,010402 general chemistry ,01 natural sciences ,Protein Structure, Secondary ,Theranostic Nanomedicine ,Mice ,chemistry.chemical_compound ,Biomimetic Materials ,Cell Line, Tumor ,Neoplasms ,PEG ratio ,medicine ,Animals ,Humans ,Tissue Distribution ,General Materials Science ,Precision Medicine ,Apolipoprotein A-I ,Optical Imaging ,General Engineering ,Pet imaging ,021001 nanoscience & nanotechnology ,Porphyrin ,0104 chemical sciences ,3. Good health ,Photochemotherapy ,Surgery, Computer-Assisted ,chemistry ,Positron-Emission Tomography ,Blood circulation ,PEGylation ,Female ,0210 nano-technology - Abstract
PEGylation (PEG) is the most commonly adopted strategy to prolong nanoparticles' vascular circulation by mitigating the reticuloendothelial system uptake. However, there remain many concerns in regards to its immunogenicity, targeting efficiency, etc., which inspires pursuit of alternate, non-PEGylated systems. We introduced here a PEG-free, porphyrin-based ultrasmall nanostructure mimicking nature lipoproteins, termed PLP, that integrates multiple imaging and therapeutic functionalities, including positron emission tomography (PET) imaging, near-infrared (NIR) fluorescence imaging and photodynamic therapy (PDT). With an engineered lipoprotein-mimicking structure, PLP is highly stable in the blood circulation, resulting in favorable pharmacokinetics and biodistribution without the need of PEG. The prompt tumor intracellular trafficking of PLP allows for rapid nanostructure dissociation upon tumor accumulation to release monomeric porphyrins to efficiently generate fluorescence and photodynamic reactivity, which are highly silenced in intact PLP, thus providing an activatable mechanism for low-background NIR fluorescence imaging and tumor-selective PDT. Its intrinsic copper-64 labeling feature allows for noninvasive PET imaging of PLP delivery and quantitative assessment of drug distribution. Using a clinically relevant glioblastoma multiforme model, we demonstrated that PLP enabled accurate delineation of tumor from surrounding healthy brain at size less than 1 mm, exhibiting the potential for intraoperative fluorescence-guided surgery and tumor-selective PDT. Furthermore, we demonstrated the general applicability of PLP for sensitive and accurate detection of primary and metastatic tumors in other clinically relevant animal models. Therefore, PLP offers a biomimetic theranostic nanoplatform for pretreatment stratification using PET and NIR fluorescence imaging and for further customized cancer management via imaging-guided surgery, PDT, or/and potential chemotherapy.
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- 2015
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