Amorphous drug preparation using ball milling

Chieng Heng Liang, Norman, n/a

January 2008

Polymorphism and crystallinity are now recognised as important issues in drug development. This is shown by the increased amount of research in this area over recent years. In pharmaceutical development milling is an important unit operation for size reduction to improve powder handling, processing and dissolution rate. The aim of this thesis was to investigate the effect of ball milling (and cryo-milling) on the solid state properties, including amorphous drug formation, of pharmaceutical solids. Milling was carried out using an oscillatory ball mill (Mixer Mill MM301, Retsch GmbH & Co., Germany). In cryo-milling the milling jars were immersed in liquid nitrogen for three min before milling. XRPD was used as the main technique to evaluate the milled samples. Ranitidine hydrochloride (RAN) and indomethacin (INDO) were the model drugs used in this study. It was found that upon milling, RAN form 1 converts to RAN form 2 via an amorphous phase. A faster amorphization rate was observed when the crystalline samples were cryo-milled. Amorphous ranitidine hydrochloride was characterized to have a glass transition (T[g]) range of 13 to 30 �C and a crystallization exotherm (T[c]) between 30 and 65 �C. Conversion was found to occur faster when the temperature of the solid powder was greater than the T[c]. Under various storage conditions, similarly, crystallization of the amorphous phase mainly led to RAN form 2. However, some form 1 and amorphous phase was also detected on the XRPD diffractograms. Using partial least squares regression, the amount of solid form components in the ternary RAN mixtures were successfully quantified. RAN form 2 did not convert to form 1 under any milling (including cryo-milling) or storage conditions used in this study. Overall, RAN form 2 was found to be the thermodynamically stable form and the two (RAN) polymorphs are likely to be a monotropic pair. In a co-milling study of INDO and RAN, the two crystalline drugs were successfully converted into a single amorphous phase after 60 min of co-milling in a cold room (4 �C). The T[g] range (26-44 �C) was also characterized for these mixtures. DRIFTS spectra of the co-milled amorphous samples indicated an interaction had occurred between the carboxylic acid carbonyl (HO-C=O) and benzonyl amide (NC=O) of the INDO molecule with the aci-nitro (C=NO₂) of RAN. Depending on the ratio of INDO to RAN, in general, the amorphous mixtures were stable at 4 �C after 30 days of storage. Crystallization was faster when the binary mixtures were stored at higher temperature or contained higher amounts of RAN in the mixture. Although XRPD and DRIFTS suggested an interaction between the two drugs, co-crystal formation was not observed between INDO and RAN. Ball milling can be used to produce amorphous drug. The rate and extent of amorphization is dependent on the milling conditions. A faster rate of amorphization was observed when the crystalline drugs were cryo-milled. Amorphous drug formation can be made either alone or in combination with another crystalline drug. Amorphization could offer a significant improvement on the dissolution profile and the bioavailability of the poorly water soluble drug - indomethacin. Furthermore, ball milling can also be used to produce a homogenous mix between solids. The �goodmix� effect can be used for seed-induced crystallization or, when the XRPD or Raman data were combined with partial least squares regression, to create a reliable calibration model for quantitative analysis.

drugs design

drug development

ball mills

amorphous substances

Application of neural networks in the first principles calculations and computer-aided drug design

Hu, Lihong., 胡麗紅.

January 2004

published_or_final_version / Chemistry / Doctoral / Doctor of Philosophy

Neural networks (Computer science)

Drugs - Design - Data processing.

Escalation with overdose control for phase I drug-combination trials

Shi, Yun, 施昀

January 2013

The escalation with overdose control (EWOC) method is a popular modelbased dose finding design for phase I clinical trials. Dose finding for combined drugs has grown rapidly in oncology drug development. A two-dimensional EWOC design is proposed for dose finding with two agents in combination based on a four-parameter logistic regression model. During trial conduct, the posterior distribution of the maximum tolerated dose (MTD) combination is updated continuously in order to find the appropriate dose combination for each cohort of patients. The probability that the next dose combination exceeds the MTD combination can be controlled by a feasibility bound, which is based on a prespecified quantile for the MTD distribution such as to reduce the possibility of over-dosing. Dose escalation, de-escalation or staying at the same doses is determined by searching the MTD combination along rows and columns in a two-drug combination matrix. Simulation studies are conducted to examine the performance of the design under various practical scenarios, and illustrate it with a trial example. / published_or_final_version / Statistics and Actuarial Science / Master / Master of Philosophy

Clinical trials - Statistical methods.

Pharmaceutical arithmetic.

Drugs - Design.

Drug development.

The formulation, manufacture and evaluation of capsules containing freeze-dried aqueous extracts of Leonotis Leonorus or Mentha Longifolia.

Ma, Haiqiu

January 2006

<p>Leonotis leonorus and Mentha longifolia are two herbs commonly used in South Africa, mostly in oral liquid dosage forms. Several disadvantages are associated with these traditional dosage forms which can perhaps be remedied by using an appropriate oral solid dosage form, provided the actual plant material in the latter still resemble, as closely as possible, the traditionally used material and provide products of suitable pharmaceutical quality. The objectives of this study were to prepare and evaluate the pharmaceutical suitability of the freeze-dried aqueous extracts of Leonotis Leonorus and Mentha Longifolia as plant raw material for the capsule dosage of these two therapies and to formulate and manufacture capsules of Leonotis Leonorus and Mentha Longifolia aqueous extract that would contain amounts of the plant materials equivalent to that found in their traditional liquid dosage forms, and have immediate release characteristics and suitability stability.</p>

Pharmaceutical chemistry

Drug design

Drugs, Design

Materia medica, Vegetable.

Amorphous drug preparation using ball milling

Chieng Heng Liang, Norman, n/a

January 2008

Polymorphism and crystallinity are now recognised as important issues in drug development. This is shown by the increased amount of research in this area over recent years. In pharmaceutical development milling is an important unit operation for size reduction to improve powder handling, processing and dissolution rate. The aim of this thesis was to investigate the effect of ball milling (and cryo-milling) on the solid state properties, including amorphous drug formation, of pharmaceutical solids. Milling was carried out using an oscillatory ball mill (Mixer Mill MM301, Retsch GmbH & Co., Germany). In cryo-milling the milling jars were immersed in liquid nitrogen for three min before milling. XRPD was used as the main technique to evaluate the milled samples. Ranitidine hydrochloride (RAN) and indomethacin (INDO) were the model drugs used in this study. It was found that upon milling, RAN form 1 converts to RAN form 2 via an amorphous phase. A faster amorphization rate was observed when the crystalline samples were cryo-milled. Amorphous ranitidine hydrochloride was characterized to have a glass transition (T[g]) range of 13 to 30 �C and a crystallization exotherm (T[c]) between 30 and 65 �C. Conversion was found to occur faster when the temperature of the solid powder was greater than the T[c]. Under various storage conditions, similarly, crystallization of the amorphous phase mainly led to RAN form 2. However, some form 1 and amorphous phase was also detected on the XRPD diffractograms. Using partial least squares regression, the amount of solid form components in the ternary RAN mixtures were successfully quantified. RAN form 2 did not convert to form 1 under any milling (including cryo-milling) or storage conditions used in this study. Overall, RAN form 2 was found to be the thermodynamically stable form and the two (RAN) polymorphs are likely to be a monotropic pair. In a co-milling study of INDO and RAN, the two crystalline drugs were successfully converted into a single amorphous phase after 60 min of co-milling in a cold room (4 �C). The T[g] range (26-44 �C) was also characterized for these mixtures. DRIFTS spectra of the co-milled amorphous samples indicated an interaction had occurred between the carboxylic acid carbonyl (HO-C=O) and benzonyl amide (NC=O) of the INDO molecule with the aci-nitro (C=NO₂) of RAN. Depending on the ratio of INDO to RAN, in general, the amorphous mixtures were stable at 4 �C after 30 days of storage. Crystallization was faster when the binary mixtures were stored at higher temperature or contained higher amounts of RAN in the mixture. Although XRPD and DRIFTS suggested an interaction between the two drugs, co-crystal formation was not observed between INDO and RAN. Ball milling can be used to produce amorphous drug. The rate and extent of amorphization is dependent on the milling conditions. A faster rate of amorphization was observed when the crystalline drugs were cryo-milled. Amorphous drug formation can be made either alone or in combination with another crystalline drug. Amorphization could offer a significant improvement on the dissolution profile and the bioavailability of the poorly water soluble drug - indomethacin. Furthermore, ball milling can also be used to produce a homogenous mix between solids. The �goodmix� effect can be used for seed-induced crystallization or, when the XRPD or Raman data were combined with partial least squares regression, to create a reliable calibration model for quantitative analysis.

drugs design

drug development

ball mills

amorphous substances

The development of sialidase inhibitors using structure-based drug design

Rogers, Graeme W.

January 2017

The sialidases/neuraminidases represent a family of enzymes whose function is important in the pathogenicity of bacteria and the virulence of influenza. Relenza and Tamiflu represent two drugs that were developed using structure-based drug design (SBDD) and computational-assisted drug design (CADD). These drugs target the active site of the influenza neuraminidase A and B (GH-34 family). Sialidases in the GH-33 family could represent novel drug targets for the treatment of bacterial or parasitic infection. SBDD was employed to develop chemical tools of two GH-33 sialidases, NanB and TcTS. NanB is a potential drug target for S. pneumoniae. The chemical tool developed for NanB follows on from work within the Taylor and Westwood research groups, in which a molecule of CHES and a glycerol were found serendipitously bound within a water channel at an allosteric site. Using this information as a basis for SBDD an allosteric inhibitor of NanB, Optactin was developed. Within this work, synthesis of this inhibitor was achieved and optimised. Optactin was then modified to improve potency. This proceeded through an amide analogue and addition of an arene resulting in a mid- micromolar inhibitor (IC50: 55.4±2.5 μM). Addition of polar substituents improved potency further resulting in a low micromolar inhibitor of NanB, Optactamide (IC50: 3.0±1.7 μM). Application of this tool in vitro demonstrated that NanB and NanA have a role in invasion of S. pneumoniae into lung epithelial cells. TcTS is a potential drug target for the treatment of Chagas disease. A CADD approach using a fragment library was unsuccessful at identifying an allosteric inhibitor of TcTS despite structural similarity with NanB. A re-task of the CADD approach towards the active site was successful in identifying an inhibitor of TcTS and a fragment useful for further development. This work sets the groundwork for the development of a chemical tool targeting TcTS.

Anti-tuberculosis drug design based on a possible mimicry between host and pathogen lipids

Sebatjane, Selaelo Ivy

05 May 2005

The need for new anti- TB drugs is increasingly rising because of the resistance of M. tuberculosis to existing drugs. The mycobacterial cell wall serves as an impermeable protective barrier for the bacilli from toxins and chemotherapeutic agents, mainly due to the mycolic acids waxy outer layer. The mycolic acids play an important role in the architecture and physical properties of the mycobacterial cell wall. This study was based on the observed mimicry and association between the host cholesterol and the mycolic acids. This may present yet another way in which the TB bacilli survives by manipulating its host and using some of its components for its survival. The research focused on whether the cholesterol-like molecules on the mycobacterial cell surface can be targeted for effective delivery of anti-mycobacterial agents. In order to exploit the ability of M tuberculosis to accumulate cholesterol or interact with it, a cholesterol¬binding molecule was used for targeting an anti- TB drug to the mycobacterial cell wall or to the cell membrane of infected macrophages. It was observed that the drug does possess anti-mycobacterial activities even though higher concentrations of the compound were required. This supports the idea that the ability of cholesterol to interact with the mycobacterial mycolic acids can be exploited for designing of anti- TB agents. It was also demonstrated in this study that cholesterol has a negative effect on the activity of INH. Thus cholesterol, which is required for entry and survival of M tuberculosis in the host cells, has yet another protective effect on this pathogen. The possible ability of cholesterol to target the same enzyme(s) as INH is another small piece of knowledge to complete the puzzle to understanding the mode of virulence and pathogenesis of this pathogen and develop of new ways to fight the old enemy. / Dissertation (MSc(Biochemistry))--University of Pretoria, 2006. / Biochemistry / unrestricted

Drugs design

Tuberculosis chemotherapy

Host-parasite relationships

Tuberculosis research

UCTD

Assay development for use in drug discovery against Bovine Trichomoniasis

Schreiber, Kimberly C. M.

01 January 2007

Bovine trichomoniasis is a venereal disease that affects cattle. The causative agent of this disease is Tritrichomonas foetus, a flagellated protozoan. There is no current FDA approved treatment for this disease. The purpose of this study was to develop new compound screening assays that will make the discovery of new compounds faster and more accurate. The CellTiter-Glo Luminescent Cell Viability Assay, a high throughput screening (HTS) assay from Promega, was found to be as affective at measuring cytotoxicity as traditional assaying techniques. For the first time. preen florescent protein. a reporter gene used in cell viability assavs was successfully transformed into T. foetus for use in HTS systems. This study also identified new compounds that can potentially be used as new treatments for this disease.

Trichomoniasis Treatment

Drug development

Drugs Design

Life Sciences

Tricyclic purine analogues as antiparasitic and antiviral agents

Hagos, Asmerom M.

01 December 2003

No description available.

Purines Synthesis

Antiviral agents

Antiparasitic agents

Trypanosoma brucei

Drugs Design

Trypanosoma brucei

Antiparasitic agents

Antiviral agents

Drugs Design

Purines Synthesis

A novel optimization algorithm and other techniques in medicinal chemistry

Unknown Date

In this dissertation we will present a stochastic optimization algorithm and use it and other mathematical techniques to tackle problems arising in medicinal chemistry. In Chapter 1, we present some background about stochastic optimization and the Accelerated Random Search (ARS) algorithm. We then present a novel improvement of the ARS algorithm, DIrected Accelerated Random Search (DARS), motivated by some theoretical results, and demonstrate through numerical results that it improves upon ARS. In Chapter 2, we use DARS and other methods to address issues arising from the use of mixture-based combinatorial libraries in drug discovery. In particular, we look at models associated with the biological activity of these mixtures and use them to answer questions about sensitivity and robustness, and also present a novel method for determining the integrity of the synthesis. Finally, in Chapter 3 we present an in-depth analysis of some statistical and mathematical techniques in combinatorial chemistry, including a novel probabilistic approach to using structural similarity to predict the activity landscape. / by Radleigh G. Santos. / Thesis (Ph.D.)--Florida Atlantic University, 2012. / Includes bibliography. / Electronic reproduction. Boca Raton, Fla., 2012. Mode of access: World Wide Web.

Drugs--Design--Mathematical models

Combinatorial optimization

Combinatorial chemistry

Genetic algorithms

Mathematical optimization

Stochastic processes