A BIORELEVANT IN VITRO MODEL TO CHARACTERIZE IN VIVO RELEASE OF BONE MORPHOGENETIC PROTEIN-2 (rhBMP-2)

BISWAS, DEBLINA

01 January 2017

Biorelevant in vitro release/dissolution tests are designed to predict the in vivo behavior of a drug and are crucial in understanding its in vivo performance. Currently, there is no standardized compendial in vitro release testing methods or regulatory guidance’s for release/dissolution testing of implants due to their complex physiological locations.Furthermore, existing compendial methods do not capture the local release profile of ‘novel’ parenterals in physiological low fluid volume surrounding areas. Long acting and in situ forming implants with orthobiologic proteins and peptides have increased over the past few decades due to a better understanding of genetic engineering. One of these products, INFUSE® Bone Graft (Medtronics, MN, USA), is an implant which helps in bone regeneration at the trauma site and is comprised of a) an absorbable collagen sponge (ACS) and b) recombinant human bone morphogenetic protein-2 (rhBMP-2). INFUSE® Bone Graft is an FDA approved product for acute, open shaft tibial fractures, lumbar spinal fusions and sinus or ridge augmentations in the jaws. The evaluation of implant products such as INFUSE® Bone Graft requires a good understanding of local and systemic release in vivo in order to ensure safe, effective, and predictable product performance. The primary goal of this study is to develop a predictive ‘biorelevant’ release model, which factors in clinically relevant physiological parameters suitable for studying and effectively predicting extended release of implants, using INFUSE Bone Graft® as our model implant. A novel biorelevant in vitro model was designed and tested. The model was observed to be discriminatory between two different carrier formulations of rhBMP-2 using a model independent approach - similarity factor (f2). Additionally, a high throughput assay to quantify rhBMP-2 release using high performance liquid chromatography with UV/VIS detection was also developed and validated. Successful completion of this study facilitated an in vitro release study design that incorporated the complex biorelevant parameters of implant dosage forms, the model will offer crucial insights into biological performance, and aid in developing methods to characterize release of other similar dosage forms.

biorelevant

rhBMP-2

model

IVIVR

implants

in vitro

protein

parenteral

novel

Pharmaceutics and Drug Design

Chemical Investigation of Antarctic Marine Organisms & Their Role in Modern Drug Discovery

Fries, Jacqueline Lee

23 February 2016

The chemicals produced by biological systems, whether proteins, peptides, or terpenes, will always provide an intriguing topic for researchers. Invisibly controlling every aspect of nature, these molecules are responsible for life, evolution, and death. Specifically, here is described the secondary metabolites produced by Antarctic marine organisms as well as others, and how they are used to defend or attract other animals while potentially providing health benefits to mankind. This is done through collection, extraction, and separation of individual specimens. The respective mixtures of compounds after isolation are then analyzed via spectroscopic methods such as nuclear magnetic resonance spectroscopy, mass spectrometry, and X-ray crystallography. Once identified, these compounds are tested in biological assays to provide a hypothesis for their use in nature or evidence that there may be a use for them in medicine. For this thesis, the Antarctic organisms described are an alga, Pocamium cartilagineum, an amphipod, Paradexamine fissicauda, a sponge, Dendrilla membranosa, and one undescribed and two known deep sea coral species, Briareopsis aegeon and Plumarella delicatissima. Beyond these specific specimens, their chemistry as well as natural products from other origins were combined to create a diverse compound library for biological screening against human pathogens. This was done using computational modeling and statistical analysis of the compound library and its comparison to other known chemical libraries. The diversity and impact of these molecules are assessed.

Natural Products

Cheminformatics

Ecology

Metabolomics

Deep Sea

Octocorals

Algae

Plocamium

Plumarella

Chemistry

Medicinal Chemistry and Pharmaceutics

Organic Chemistry

INVESTIGATION OF FACTORS INFLUENCING PROTEIN STABILITY IN LYOPHILIZED FORMULATIONS USING SOLID-STATE NMR SPECTROSCOPY

Lay-Fortenbery, Ashley

01 January 2019

Many proteins are unstable in solution and must be formulated in the solid state. This has led to an increase in the use of lyophilized dosage forms. Lyophilization is a complicated processing method consisting of three major steps: freezing, primary drying, and secondary drying. This can lead to several formulation stability challenges including changes in ionization within the matrix, phase separation of the protein drug from added stabilizers, sufficient mobility within the system for movement of reactive species and protein side chains, and crystallization of excipients upon storage. Solid-State Nuclear Magnetic Resonance Spectroscopy (SSNMR) is used to characterize many important properties of lyophilized formulations including crystalline vs. amorphous content, polymorphic form, ionization profile, interaction between formulation components with domain sizes, and mobility within the cake matrix. In order to study ionization changes in lyophilized solids, SSNMR and UV/Vis Diffuse Reflectance spectroscopy were used. 13C-labeled fumaric, succinic, and butyric acids were added to formulations at various pH levels, and were used to quantify change in the ionization of the matrix by monitoring the ionization ratios of the carboxylic acid peaks using SSNMR. pH indicators were also added to the formulations and their ionization ratio was determined using UV/Visible Diffuse Reflectance Spectroscopy. The ionization profile in the solid state was compared with that in solution before lyophilization. A rank ordering of ionization shift was made in pharmaceutically relevant buffers. SSNMR proton relaxation times (1H T1 and 1H T1rho) for each formulation component can be compared to determine homogeneity within the lyophilized matrix. The concept of spin diffusion is used in order to determine the length scale on which the components are either homogeneous or phase separated. The domain size is typically 20-50 nm or 2-10 nm for 1H T1 and 1H T1rho, respectively. PVP and dextran polymers were phase separated on both domains for physical mixtures and lyophilized mixtures. BSA and lysozyme were both lyophilized with formulations containing sucrose, trehalose, or mannitol as the stabilizer. Mannitol crystallized, and the relaxation times showed phase separation. Sucrose and trehalose both formed homogeneous systems at both length scales when formulated in a 1:1 ratio with BSA or lysozyme. Aspartame was shown to be phase separated from trehalose. The SSNMR proton relaxation times were also used to measure the local mobility in the lyophilized matrix, as a timescale of picoseconds to nanoseconds is associated with the 1H T1 relaxation time. Mobility was monitored in formulations containing a fixed amount of sucrose and mannitol, but with a variable amount of an IgG2 protein. The 1H T1 relaxation times decreased as protein content increased. The formulations with the highest relaxation time (lowest mobility), was the most stable in accelerated temperature conditions as monitored by size exclusion chromatography and capillary isoelectric focusing. This method can be used to rank order the most stable formulations at time-zero. Anti-plasticization was also studied by formulating sorbitol in various ratios with trehalose. The 1H T1 relaxation times increased with increasing sorbitol content, while the glass transition temperature decreased. Sorbitol and trehalose glasses were also exposed to different temperature storage conditions. Sorbitol appears to promote aging, as the formulations with higher sorbitol content showed larger increases in proton relaxation time.

Lyophilization

Solid-State Acidity

Phase Separation

Local Mobility

Pharmaceutics and Drug Design

Investigation of the Tailoring Steps in Pradimicin Biosynthesis

Napan, Kandy L.

01 May 2016

The actinobacteria Actinomadura hibisca synthesizes the natural products pradimicin A-C through a type II polyketide biosynthetic pathway. Eight tailoring enzymes in pradimicin biosynthesis have been investigated in this work, including PdmJ, PdmW, PdmN, PdmT, PdmO, PdmS, PdmQ and PdmF. PdmJ and PdmW were characterized as cytochrome P450 hydroxylases that catalyze the incorporation of two hydroxyl groups at C-5 and C-6, respectively. These enzymes worked synergistically and their co-expression significantly improved the efficiency of the hydroxylation steps. PdmN is an amino acid ligase that accepts a variety of substrates and ligates a D-alanine moiety to C-16 to form the corresponding derivatives. PdmS and PdmQ were functionally identified as Oglycosyltransferases. Disruption of pdmS in the genome of A. hibisca generated a biosynthetic precursor without sugar moieties, which validated that PdmS is the first glycosyltransferase that attaches the first sugar to the 5-OH of pradimicins. In contrast, disruption of pdmQ led to the synthesis of pradimicin B, confirming that PdmQ was responsible for attaching the D-xylose moiety to the 3'-OH of the first sugar portion in pradimicins. Naturally, the first sugar moiety 4',6'-dideoxy-4'-amino-D-galactose of pradimicin A and B is methylated at 2'-NH. When the expression of PdmO was compromised, the mutant strain produced mainly pradimicin C, which contains the 4',6'- dideoxy-4'-amino-D-galactose in its structure. This suggested that PdmO was responsible for the N-methylation of the amino sugar. PdmF was identified as the C-11 Omethyltransferase. Moreover, PdmT was confirmed to be an O-methyltransferase through gene disruption and in vitro biochemical reactions. PdmT methylates the 7-OH to form a methoxy group that in a later step is removed to generate the pradimicin aglycon. In summary, this research has identified eight important pradimicin biosynthetic enzymes that are involved in various tailoring steps in pradimicin biosynthesis. Several new pradimicin analogues has been generated by manipulating these enzymes. Their enzymatic properties and collaborative actions were investigated. These results not only provide new insights into type II polyketide biosynthetic pathways, but also enable rational engineering of the pradimicin biosynthetic pathway to create new analogues for drug development.

Actinomadura hibisca

biosythetic pathway

natural product

polyketide

pyradimicin

tailoring enzymes

Medicinal Chemistry and Pharmaceutics

Molecular Biology

Investigation of the Structure and Dynamics of Regioisomeric Eu³⁺ and Gd³⁺ Chelates of NB-DOTMA: Implications for MRI Contrast Agent Design

Webber, Benjamin Charles

18 November 2013

The detection of disease and abnormal pathology by magnetic resonance imaging (MRI) has been aided significantly by the use of gadolinium (Gd3+)-based contrast agents (CAs) over the past three decades. MRI and MRI CAs play a critical role in diagnosing tumors and diseases of the central nervous system. The agents used clinically have been shown to safely increase MRI contrast despite the toxicity of Gd3+, owing to the high kinetic and thermodynamic stability of these chelates. However, current CAs enhance contrast at a small fraction of what is theoretically possible. This leads to the necessity of introducing high CA doses in practice in order to afford sufficient contrast. Lanthanide (Ln3+) chelates based on 1,4,7,10–tetraazacyclododecane–1,4,7,10–tetraacetate (DOTA) have been shown to be particularly stable and effective. Chelates of DOTA exist in two interconverting coordination geometries which have varying water exchange rates. Researchers have envisioned a way to increase the per-dose efficacy both by control of the Gd3+–inner–sphere water exchange rate and via binding specificity (i.e. to tumors). The efficacy gains using these approaches have thus far been modest. A thorough structural characterization of europium (Eu3+) chelates of a DOTA-derivative which cannot undergo conformational exchange was carried out. These studies show that a single enantiomer of the ligand (S)–2–(4-nitrobenzyl)–1,4,7,10–tetraazacyclododecane–1,4,7,10–tetra(α–methyl)acetate (NB–DOTMA) can yield chelates which are both diastereoisomeric (previously reported) and regioisomeric (not previously speculated). Molecular mechanics simulations generated from the characterization data indicate that the nitrobenzyl (NB) substituent is oriented in different directions for the two possible regioisomers. The NB group can be chemically converted to confer macromolecular binding capability, and the orientation of the NB substituent may have a significant impact on the binding and/or relaxation behavior of a prototypical CA. The nuclear magnetic resonance (NMR) spectra of Eu–NB–DOTMA at various temperatures were compared. Unexpectedly, the chelates showed time-averaged structures which differ with a change in water exchange rate — the faster the rate, the greater the deviation from the expected structure. Consideration of the structures of Ln3+ chelates without accounting for their dynamic behavior does not yield an accurate value for the time-averaged hydration state. These observations suggest the "optimal" water exchange rate calculated using Solomon-Bloembergen-Morgan (SBM) theory may not lead to the highest-efficacy CAs. Binding and relaxometric studies of macromolecule-targeting derivatives of Gd–NB–DOTMA both by the author and in another lab showed that the coordination isomer with the slower water exchange rate should lead to more effective contrast, in direct opposition to the prevailing view of water exchange in the MRI community. Preliminary data do not indicate that regioisomeric chelates have significantly different relaxivity or macromolecular binding behavior. The ratios between regioisomeric Ln–NB–DOTMA chelates formed were shown to be dependent on the concentration and pH of the chelation reaction, but conditions were not found which led to the production of a single regioisomer. Attempts to carry out an efficient synthesis of a Ln3+ chelate with no potential for regioisomerism were unsuccessful.

Chelates -- Conformation -- Research

Magnetic resonance imaging -- Research

Diagnosis

Medicinal Chemistry and Pharmaceutics

Radiochemistry

Formulation and evaluation of amorphous clarithromycin tablets for enhanced dissolution

Mongalo, Sello Herlot

January 2022

Thesis (M. Pharmacy ((Pharmaceutics)) -- University of Limpopo, 2022 / According to the biopharmaceutical classification system, Clarithromycin is considered a class II molecule with low solubility. Poorly soluble drugs result in low bioavailability. Various techniques have been studied to improve the solubility of drugs and subsequently bioavailability. Of these techniques, preparation of amorphous form is the preferred method because it is a more effortless and convenient way to improve the aqueous solubility and dissolution of poorly water soluble drugs. The only disadvantage of amorphous materials is that they are less thermodynamically stable and can recrystallize during processing and storage. Aim: The aim of this study is to prepare amorphous form of clarithromycin to improve its solubility, dissolution rate, and, subsequently, bioavailability. Methods: In this study, preparation of amorphous form of clarithromycin was conducted using the quench cooling method in which the purchased anhydrous crystalline clarithromycin was spread on an aluminum foil and heated to a melting point (217˚C - 220˚C) and then rapidly cooled. Various techniques were conducted to characterize the prepared amorphous clarithromycin, and these include Differential Scanning Calorimetry (DSC), Fourier-Transform Infrared Spectroscopy (FTIR), and X-Ray Powder Diffraction (XRPD). In addition, tablets were formulated using the amorphous clarithromycin mixed with selected excipients from compatibility studies, and in vitro dissolution and stability studies were conducted over a period of 6 months. Results: The DSC thermogram results confirmed that the material prepared using the quench cooling process is an amorphous solid-state. Furthermore, the XRPD confirmed an amorphous solid-state with scattering halo peaks. The FTIR also depicted some broader and lower intensity peaks that indicated a formation of an amorphous material. The dissolution rate of amorphous clarithromycin tablets improved by more than 30% when compared to commercial crystalline clarithromycin tablets. The study revealed a drop in dissolution rate at months 3 to 6 under accelerated conditions due to recrystallization. The 6 monthly stability study at long term conditions showed no change in the integrity of the tablets and their contents. Conclusion: As indicated by the study, it can be concluded that the amorphous clarithromycin remained stable during processing and storage under long-term stability for 6 months. Furthermore, based on dissolution results, it can be concluded that amorphous solids have an improved dissolution rate. / Medical Research Council CHIETA

Clarithromycin

Amorphous

Stability

Dissolution

Solution-mediated

Phase transformation

Pharmaceutics

Amorphous substances

Solubility

Solid dosage forms

Drugs -- Solubility -- Testing

The Combined Neuropharmacology and Toxicology of Major 'Bath Salts' Constituents MDPV, Mephedrone, and Methylone

Allen, Serena

01 May 2018

The synthetic cathinones, 3,4- methylenedioxypyrovalerone (MDPV), 4-methylmethcathinone (mephedrone), and 3,4- methylenedioxymethcathinone (methylone), gained worldwide notoriety as the psychoactive components of ‘bath salts;’ a marketing term used to circumvent federal drug laws and permit their legal sale. Previous studies have shown that these drugs share pharmacological characteristics with cocaine and the amphetamines, however, descriptions of their neurotoxic properties are limited. Moreover, while forensic analysis has revealed that the most frequently abused bath salts ‘brands’ contain binary and ternary mixtures of MDPV, mephedrone, and methylone, the majority of preclinical research has focused on explicating the individual effects of these drugs. Therefore, the present dissertation aimed to address this limitation and characterize the acute and chronic effects of combined synthetic cathinone exposure on dopaminergic tone in mesolimbic and nigrostriatal brain regions. To accomplish this, male Swiss-Webster mice were administered MDPV, mephedrone, and methylone, individually or concomitantly, 1 time or 7 times over the course of two weeks and the corresponding effects of each treatment on mesolimbic and nigrostriatal brain tissue levels of dopamine (DA) and DA metabolites were analyzed using a high performance liquid chromatography – electrochemical detection (HPLC-ECD) assay. Additionally, motor-stimulant activity was evaluated after both dosing regimens using locomotor activity assays, while immunoblot and immunostaining techniques were used to evaluate the chronic effects of co-synthetic cathinone exposure on tissue levels of tyrosine hydroxylase (TH), dopamine transporter (DAT), monoamine oxidase B (MAO-B), catechol-O-methyltransferase (COMT), and glial fibrillary acidic protein (GFAP). Results from these studies provide evidence of a significant pharmacological interaction among major bath salt constituents, MDPV, mephedrone, and methylone. This was observed acutely as enhanced DA responses and chronically as functional toxicity at the DA synapse. Furthermore, such interactions may contribute to the deleterious effects reported by bath salt users. Together, these findings have shown that the composition of bath salts preparations can significantly influence their psychostimulant and toxic effects, substantiating the importance of modeling bath salts as drug mixtures.

synthetic cathinones

neurotoxicity

pharmacological interactions

dopamine

dopamine transporter

Medicinal Chemistry and Pharmaceutics

Neuroscience and Neurobiology

Pharmacology

Pharmacy and Pharmaceutical Sciences

Toxicology

Increasing Expression of Hepatitis B Surface Antigen in Maize Through Breeding

Miller, Erin Suzanne

01 March 2015

The hepatitis B virus (HBV) is a common virus, with two billion people infected worldwide. It causes approximately 600,000 deaths each year, despite the availability of an effective vaccine since 1982. Maize as a platform for oral vaccination can supply a heat stable vaccine, which does not require syringes or trained personnel to administer. The Hepatitis B Surface antigen was transformed into maize and this seed was used to evaluate expression levels through the breeding process. The transgene was transferred into two elite maize inbreds by backcrossing. Highest expressing ears were selected each generation until approximately 99% commercial parent was obtained with a single gene coding for the vaccine present. Selected individuals were crossed to create hybrid plants. This work was done to create high expressing high yielding lines that could be used as a plant-based oral vaccine for Hepatitis B.

plant breeding

hepatitis B

corn

oral vaccination

hybrid

plant based

Agriculture

Biology

Biotechnology

Genetics and Genomics

Medicinal Chemistry and Pharmaceutics

Plant Sciences

THE PHARMACOKINETICS OF METAL-BASED ENGINEERED NANOMATERIALS, FOCUSING ON THE BLOOD-BRAIN BARRIER

Dan, Mo

01 January 2013

Metal-based engineered nanomaterials (ENMs) have potential to revolutionize diagnosis, drug delivery and manufactured products, leading to greater human ENM exposure. It is crucial to understand ENM pharmacokinetics and their association with biological barriers such as the blood-brain barrier (BBB). Physicochemical parameters such as size and surface modification of ENMs play an important role in ENM fate, including their brain association. Multifunctional ENMs showed advantages across the highly regulated BBB. There are limited reports on ENM distribution among the blood in the brain vasculature, the BBB, and brain parenchyma. In this study, ceria ENM was used to study the effect of size on its pharmacokinetics. Four sizes of ceria ENMs were studied. Five nm ceria showed a longer half-life in the blood and higher brain association compared with other sizes and 15 and 30 nm ceria had a higher blood cell association than 5 or 55 nm ceria. Because of the long circulation and high brain association of 5 nm ceria compared with other sizes, its distribution between the BBB and brain parenchyma was studied. The in situ brain perfusion technique showed 5 nm ceria (99%) on the luminal surface of the BBB rather than the brain parenchyma. For biomedical applications in the central nervous system (CNS), it is vital to develop stable and biocompatible ENMs and enhance their uptake by taking advantage of their unique properties. Cross-linked nanoassemblies entrapping iron oxide nanoparticles (CNA-IONPs) showed controlled particle size in biological conditions and less toxicity in comparison to Citrate-IONPs. CNA-IONPs considerably enhanced MRI T2 relaxivities and generated heat at mild hyperthermic temperatures (40 ~ 42°C) in the presence of alternating magnetic field (AMF). Numerous researchers showed mild whole body hyperthermia can increase BBB permeability for potential brain therapeutic application. Compared to conventional hyperthermia, AMF-induced hyperthermia increased BBB permeability with a shorter duration of hyperthermia and lower temperature, providing the potential to enhance IONP flux across the BBB with reduced toxicity. Overall, ENMs with optimized physicochemical properties can enhance their flux across the BBB into the brain with desirable pharmacokinetics, which provide great potential for diagnosis and therapy in the CNS.

Metal-based engineered nanomaterials

ENMs

blood-brain barrier (BBB)

ceria ENM

iron oxide nanoparticles

pharmacokinetics

Pharmaceutics and Drug Design

Pharmacy and Pharmaceutical Sciences

SALVIANOLIC ACID B FOR PULMONARY DELIVERY TOWARDS REVERSAL OF EMPHYSEMA

Dhapare, Sneha

01 January 2017

A new pathobiologic hypothesis has recently emerged that the alveolar structural destruction and loss in emphysema are caused by the deficiency of vascular endothelial growth factor (VEGF). Therefore, this project hypothesized that such pathobiologic VEGF deficiency of emphysematous lungs can be recovered with a natural caffeic acid tetramer, salvianolic acid B (SalB), through activation of signal transducer and activator of transcription 3 (STAT3), so that emphysema can be reversed as a result of inhibition of induced cell death, stimulation of cell proliferation and migration, and promotion of stem cell recruitment to the lungs. SalB was first shown to be potently anti-oxidative (IC50 = 3.7 μM), but devoid of anti-elastase activity. SalB was then administered to the lungs of healthy rats at 0.2 mg/kg for two weeks, verifying ~1.7-fold increased lung tissue expressions of phosphorylated STAT3 (pSTAT3; an activated form of STAT3) and VEGF. Subsequently, SalB was examined in the anti-cell death assay, cell proliferation and migration assays, and trans- endothelial stem cell recruitment assay in the in vitro lung epithelial (A549) and endothelial (HMVEC-L) cell systems. SalB at 25 μM exerted significant 48-88 % inhibitory activities against cell death induced with oxidative stress and VEGF receptor blockade (with SU5416) in both cell systems, measured by the trypan blue exclusion and propidium iodide-based flow cytometry assays. SalB at 25 μM also stimulated A549 and HMVEC-L cell proliferation by ~1.4-fold and promoted cell migration by ~1.6-fold, while recovering stem cell recruitment impaired with SU5416 by 60 %. The anti-cell death, and proliferation and migration stimulatory activities of SalB were significantly opposed by pharmacological inhibitors of JAK2 (Janus kinase 2; an upper signal of STAT3), STAT3 and VEGF. SalB was then examined for its in vivo reversal activities in emphysema induced with porcine pancreatic elastase (PPE) and cigarette smoke extract (CSE) in rats. Upon establishment of emphysema on day 21, SalB was administered to the lungs three times weekly over three weeks. SalB at 0.2 mg/kg significantly recovered ~85 %-impaired treadmill exercise endurance by 57-82 %; and reduced abnormal airspace enlargement by 59-75 %. In the PPE-induced emphysematous rats, SalB also reduced the 4-fold greater alveolar destruction index by 61 %. The lung tissue protein expression by Western blot analysis found that cleaved caspase 3 (cell apoptotic marker) was induced by 13-fold, and VEGF was reduced by 60 % in the PPE -induced emphysematous rats. However, pulmonary treatment with SalB at 0.2 mg/kg normalized these proteins, and also significantly increased the expression of a cell proliferation marker, proliferative cell nuclear antigen (PCNA) by 2.6-fold. Note however that SalB treatment did not reduce the neutrophilic myeloperoxidase activity in the lungs induced in the PPE-induced rats. Taken all together, this study has demonstrated that SalB potently inhibited lung cell death, stimulates lung cell proliferation and migration, and restores stem cell migration with its mechanism of STAT3 activation and VEGF elevation and reversed established emphysema in rat models.

Emphysema

salvianolic acid B

cell death

cell proliferation

cell migration

Cell Biology

Medicinal Chemistry and Pharmaceutics

Pharmacology