Quantitative MR Analysis of Changes in the Radius Bone Marrow in Osteoporosis.

Purpose: This pilot study aimed to explore the feasibility of scanning the human distal radius bone marrow in vivo to detect osteoporosis-related changes using magnetic resonance and evaluate whether the radius may serve as an accessible probing site for osteoporosis. This may lead in the future to the use of affordable means such as low-field MRI scanners for the monitoring of disease progression. Methods: A clinical trial was performed using a 3T MR scanner, including 26 women assigned into three study groups: healthy-premenopausal (n = 7; mean age 48.6 ± 3.5 years), healthy-postmenopausal (n = 10; mean age 54.5 ± 5.6 years), and osteoporotic-postmenopausal (n = 9; mean age 61.3 ± 5.6 years). Marrow fat composition was evaluated using T2 maps, a two-compartment model of T1, and a Dixon pulse sequence. Results: The osteoporotic group exhibited higher fat content than the other two groups and lower T2 values than the healthy-premenopausal group. Conclusions: Osteoporosis-related changes in the composition of the distal radius bone marrow may be detected in vivo using MRI protocols. The scanning protocols chosen here can later be repeated using low-field MRI scanners, thus offering the potential for early detection and treatment monitoring, using an accessible, affordable means that may be applied in small clinics. This trial is registered with MOH_2018-05-23_002247, NCT03742362.

Regulatory Forum Opinion Piece*: Imaging Applications in Toxicologic Pathology-Recommendations for Use in Regulated Nonclinical Toxicity Studies.

Available imaging systems for use in preclinical toxicology studies increasingly show utility as important tools in the toxicologic pathologist's armamentarium, permit longitudinal evaluation of functional and morphological changes in tissues, and provide important information such as organ and lesion volume not obtained by conventional toxicology study parameters. Representative examples of practical imaging applications in toxicology research and preclinical studies are presented for ultrasound, positron emission tomography/single-photon emission computed tomography, optical, magnetic resonance imaging, and matrix-assisted laser desorption ionization-imaging mass spectrometry imaging. Some of the challenges for making imaging systems good laboratory practice-compliant for regulatory submission are presented. Use of imaging data on a case-by-case basis as part of safety evaluation in regulatory submissions is encouraged.

Magnetic Resonance Imaging as a Noninvasive Method for Longitudinal Monitoring of Infusion Site Reactions Following Administration of a Novel Apomorphine Formulation.

Infusion site reactions are common following subcutaneous infusion of drugs. Such reactions can lead to discontinuation of the treatment. Therefore, assessment of such reactions is essential during preclinical safety studies, and magnetic resonance imaging (MRI) can assist in evaluation. Here, in vivo and ex vivo MRI evaluations were used in addition to classical histopathology to assess the infusion site reaction to ND0701, a novel formulation of apomorphine base developed for the treatment of Parkinson's disease, in comparison to the commercial apomorphine hydrochloride (HCl) formulation. Both formulations, each at two concentrations, were continuously administered subcutaneously for 20 hr to each of 3 male and 3 female domestic pigs. Based on MRI evaluations, there was a gradual decrease in the volume of the subcutaneous lesions over 4 weeks, with smaller lesions and quicker resolution with ND0701 at concentrations 2.5- to 5-fold higher when compared to the commercial apomorphine HCl formulation. Histopathological evaluation of ND0701 revealed only minimal inflammation at the sites of infusion, whereas the commercial apomorphine HCl caused persistent inflammatory reactions and necrosis. This study provides support to the use of MRI in preclinical testing of subcutaneous drugs when evaluating local site reactions.

Compact Magnetic Resonance Imaging Systems-Novel Cost-Effective Tools for Preclinical Drug Safety and Efficacy Evaluation.

Practical magnetic resonance imaging for use in investigative and preclinical toxicology studies is now feasible. Newly developed, self-containing imaging systems provide an efficient and cost-effective means to rapidly obtain in vivo and ex vivo magnetic resonance imaging images to improve how we perform toxicology and toxicologic pathology.

Compact MRI for the detection of teratoma development following intrathecal human embryonic stem cell injection in NOD-SCID mice.

Stem cells are emerging as a promising new treatment modality for a variety of central nervous system disorders. However, their use is hampered by the potential for the development of teratomas and other tumors. Therefore, there is a crucial need for the development of methods for detecting teratomas in preclinical safety studies. The aim of the current study is to assess the ability of a compact Magnetic Resonance Imaging (MRI) system to detect teratoma formation in mice. Five NOD-SCID mice were injected intrathecally with human embryonic stem cells (hESCs), with two mice serving as controls. In vivo MRI was performed on days 25 and 48, and ex vivo MRI was performed after scheduled euthanization (day 55). MRI results were compared to histopathology findings. Two animals injected with hESCs developed hind-limb paresis and paralysis, necessitating premature euthanization. MRI examination revealed abnormal pale areas in the spinal cord and brain, which correlated histopathologically with teratomas. This preliminary study shows the efficacy of compact MRI systems in the detection of small teratomas following intrathecal injection of hESCs in a highly sensitive manner. Although these results should be validated in larger studies, they provide further evidence that the use of MRI in longitudinal studies offers a new monitoring strategy for preclinical testing of stem cell applications.

Practical Applications of in Vivo and ex Vivo MRI in Toxicologic Pathology Using a Novel High-performance Compact MRI System.

Magnetic resonance imaging (MRI) is widely used in preclinical research and drug development and is a powerful noninvasive method for assessment of phenotypes and therapeutic efficacy in murine models of disease. In vivo MRI provides an opportunity for longitudinal evaluation of tissue changes and phenotypic expression in experimental animal models. Ex vivo MRI of fixed samples permits a thorough examination of multiple digital slices while leaving the specimen intact for subsequent conventional hematoxylin and eosin (H&E) histology. With the advent of new compact MRI systems that are designed to operate in most conventional labs without the cost, complexity, and infrastructure needs of conventional MRI systems, the possibility of MRI becoming a practical modality is now viable. The purpose of this study was to investigate the capabilities of a new compact, high-performance MRI platform (M2™; Aspect Imaging, Israel) as it relates to preclinical toxicology studies. This overview will provide examples of major organ system pathologies with an emphasis on how compact MRI can serve as an important adjunct to conventional pathology by nondestructively providing 3-dimensional (3-D) digital data sets, detailed morphological insights, and quantitative information. Comparative data using compact MRI for both in vivo and ex vivo are provided as well as validation using conventional H&E.

Cytotoxic T lymphocyte perforin and Fas ligand working in concert even when Fas ligand lytic action is still not detectable.

The reason(s) why individual cytotoxic T lymphocytes (CTL) possess a fast-acting, perforin/granzyme-mediated, as well as a much slower, Fas ligand (FasL) -driven killing mechanism is not clear, nor is the basis for wide variations in killing activity exhibited by individual CTL, ranging from minutes to hours. We show that perforin expression among individual, conjugated CTL varies widely, which can account for the heterogeneity in killing speeds exhibited by individual CTL. Despite a 2-hr lag in FasL-based killing, CTL lytic action is enhanced when the two mechanisms operate in concert. This is explained by finding that the two pathways in fact are jump-started simultaneously with the lag in FasL lytic action reflecting pre-lytic caspase-8 activation and BH3-interacting domain (BID) cleavage. The complementary action of the two lytic pathways, co-expressed at varying levels among individual CTL, facilitates the lytic action of late-stage poor perforin-expressing CTL, ensuring optimal cytocidal action throughout the CTL response.

Clinical application of static fluorescence-based cytometry, Cellscan, in cutaneous adverse drug reaction.

The aim of the present study was to evaluate the effectiveness of Cellscan in identifying culprit drugs causing cutaneous adverse drug reaction. It was a prospective study with 3 months follow up conducted at the Departments of Dermatology, Internal Medicine and Dermatology Outpatient Clinic, Chaim Sheba Medical Center, Tel Hashomer, Israel. The study included 36 patients with cutaneous reaction suspected to be secondary to drugs, treated with a total number of 148 drugs. All patients and drugs were classified to three probability groups according to accepted clinical criteria. The effectiveness of the Cellscan test in identifying the culprit drug was addressed according to the clinical probability for cutaneous drug reaction, the drug class and the type of rash. Data analysis according to the clinical probability for cutaneous drug reaction revealed that patients in the moderate and high probability groups had a high test sensitivity of 77.7% and 83.3% with specificity of 71% and 63%, respectively, in identifying the culprit drug. Classifying the data according to drug classes, revealed that for the antibiotic and cardiovascular drug classes the sensitivity of the test was 100% and 92% with specificity of 83.3% and 55.5%, respectively, in identifying the culprit drug. Finally, the classification of patients according to the type of rash revealed a high evaluating accuracy for culprit drugs in maculopapular rashes with sensitivity and specificity of 90% and 60.4%, respectively. The results of this study imply that the Cellscan test is it a good practical tool for identifying the culprit drug in cutaneous adverse drug reaction.

A method for fat suppression in MRI based on diffusion-weighted imaging.

The diffusion coefficient of lipid molecules is usually much smaller than that of water, and it is demonstrated here how this difference can be exploited for robust fat suppression in magnetic resonance imaging (MRI). In contrast to the prevailing methods, diffusion-based fat suppression does not rely on chemical shift differences between water and lipids and can therefore be applied easily in low or inhomogeneous magnetic fields. It is also independent of relaxation times and can therefore be incorporated in experiments requiring conventional T(1)-weighted contrast. Diffusion-based fat suppression (DIFFSUP) consists of subtracting the signals acquired at low and high b-values, where the high b-value is ideally designed to achieve full suppression of the water and negligible attenuation of the lipid signal. Since high b-value images may be particularly affected by motion artifacts, a version of DIFFSUP incorporating first-order velocity compensation is also proposed and demonstrated. Results from phantoms and live mice at field strengths of 4.7 T and 1.0 T are presented.

A cell chip for sequential imaging of individual non-adherent live cells reveals transients and oscillations.

Advances in molecular cell biology, medical research, and drug development are driving a growing need for technologies that enable imaging the dynamics of molecular and physiological processes simultaneously in numerous non-adherent living cells. Here we describe a platform technology and software--the CKChip system--that enables continuous, fluorescence-based imaging of thousands of individual living cells, each held at a given position ("address") on the chip. The system allows for sequential monitoring, manipulation and kinetic analyses of the effects of drugs, biological response modifiers and gene expression in both adherent and non-adherent cells held on the chip. Here we present four specific applications that demonstrate the utility of the system including monitoring kinetics of reactive oxygen species generation, assessing the intracellular enzymatic activity, measuring calcium flux and the dynamics of target cell killing induced by conjugated cytotoxic T-lymphocytes. We found large variations among individual cells in the overall amplitude of their response to stimuli, as well as in kinetic parameters such as time of onset, initial rate and decay of the response, and frequency and amplitude of oscillations. These variations probably reflect the heterogeneity of even cloned cell populations that would have gone undetected in bulk cell measurements. We demonstrate the utility of the system in providing kinetic parameters of complex cellular processes such as Ca++ influx, transients and oscillations in numerous individual cells. The CKChip opens up new opportunities in cell-based research, in particular for acquiring fluorescence-based, kinetic data from multiple, individual non-adherent cells.

Application of a static fluorescence-based cytometer (the CellScan) in basic cytometric studies, clinical pharmacology, oncology and clinical immunology.

The CellScan apparatus is a laser scanning cytometer enabling repetitive fluorescence intensity (FI) and polarization (FP) measurements in living cells, as a means of monitoring lymphocyte activation. The CellScan may serve as a tool for diagnosis of rheumatoid arthritis (RA) and systemic lupus erythematosus (SLE) as well as other autoimmune diseases by monitoring FP changes in peripheral blood lymphocytes (PBLs) following exposure to autoantigenic stimuli. Changes in FI and FP in atherosclerotic patients' PBLs following exposure to various stimuli have established the role of the immune system in atherosclerotic disease. The CellScan has been evaluated as a diagnostic tool for drug-allergy, based on FP reduction in PBLs following incubation with allergenic drugs. FI and FP changes in cancer cells have been found to be well correlated with the cytotoxic effect of anti-neoplastic drugs. In conclusion, the CellScan has a variety of applications in cell biology, immunology, cancer research and clinical pharmacology.

Hypersensitivity to mycophenolate mofetil in systemic lupus erythematosus: diagnostic measures and successful desensitization.

Despite therapeutic advances in the treatment of systemic lupus erythematosus (SLE), several patients are still afflicted with severe and uncontrolled symptoms. Recently, mycophenolate mofetil (MMF) has been introduced in the treatment of SLE, with a significant therapeutic benefit, and minor side effects have been reported. Data on the adverse effects of MMF in SLE are lacking. We present an SLE patient who developed urticaria during MMF treatment. Rechallenge with MMF established the diagnosis of MMF-induced urticaria. As MMF was considered a necessary therapy, a desensitization protocol was devised, which successfully induced tolerance to MMF. This is the first published protocol for MMF desensitization, which induced tolerance in an SLE patient previously reacting with generalized urticaria.

A novel system to diagnose cutaneous adverse drug reactions employing the cellscan--comparison with histamine releasing test and Inf-gamma Releasing Test.

BACKGROUND: There are several mechanisms to describe allergic drug reactions yet the methods to diagnose them are limited. OBJECTIVE: To compare several conventional clinical and laboratory methods to diagnose skin reactions to drugs to a new method of diagnosing drug reactions by the CellScan system. METHODS: The study entailed 21 patients who were diagnosed as suffering from drug eruptions, and 105 healthy controls with no history of drug allergy. The drugs were classified into two groups according to suspicion of causing drug allergy: high and low. Most of the patients were on more than one drug, leading to 41 patient-drug interactions (assays). Histamine releasing test (HRT), interferon (INF)-gamma releasing test and CellScan examination were performed on lymphocytes of the patients and controls. RESULTS: The HRTwas interpreted as positive in 9 out of 18 (50%) patients and in 13 out of 35 (37%) assays. Based on the INF-gamma releasing test, positive results were observed in 16 out of 21 (76%) patients and in 24 out of 41 (59%) assays. In the CellScan test (CST), positive results were observed in 17 out of 21 (81%) patients and in 29 out of 41 (71%) assays. The rate of identifying the drug for eruption in the high suspicion level drugs was 9 out of 22 (41%) assays in the HRT, 20 out of 24 (83%) assays in the INF-gamma releasing test, and 21 out of 24 (87%) studies with the CellScan method. The rate of determining of the drug that caused the eruption in the low suspicion level drugs was 4 out of 13 (31 %) in the HRT, 4 out of 17 (24%) assays in the INF-gamma releasing test, and 8 out of 17 (47%) analyses in the CST. When examined in the CellScan, 99 out of 105 (94%) controls were interpreted as negative. CONCLUSION: This preliminary study indicates that the CellScan seems to be an easy and promising method for the detection of drugs responsible for adverse skin reactions. In contrast to the HRT and to the Interferon-gamma secretion test, the CellScan method is characterized by its ability to track and monitor the reaction of individual cells. By measuring the kinetic parameters of selected cells before and after adding the suspected drug, we were able to identify the culprit drug. The CellScan method had the highest sensitivity, and the interferon-gamma secretion test had the highest specificity for detection of the culprit drug. In contrast, the analysis of 105 normal control sera disclosed a high specificity of 94% for the CellScan method.

Simultaneous monitoring of binding to and activation of tumor-specific T lymphocytes by peptide-MHC.

The recent advent of peptide-MHC tetramers has provided a new and effective tool for studying antigen-specific T cell populations through monitoring tetramer binding to T cells by flow cytometry. Yet information regarding T cell activation induced by the bound tetramers cannot be deduced from binding studies alone; complementary methods are needed to bridge this gap. To this end, we have developed a new approach that now enables monitoring both binding to and activation of T cells by peptide-MHC tetramers at the single-cell level. For this purpose, we have employed the CellScan, a non-flow cytometer designed for repetitive measurements of optical parameters (e.g., fluorescence intensity and polarization) of individual living cells. A melanoma-specific MART1 CTL line and a gp100-specific CTL clone were incubated with specific and control single-chain peptide-MHC tetramers for 45 min. Subsequently, the fluorescence intensity and polarization were measured by the CellScan. Specific binding of fluorescently labeled peptide-MHC tetramers to CTLs, recorded by the CellScan, was comparable to that measured by flow cytometry. CellScan monitoring of the degree of fluorescence polarization of fluorescein diacetate-labeled CTLs that were reacted with tetramers revealed specific activation of the CTLs, which was confirmed by cytokine (INF gamma) production. These results provide a new means of monitoring both the binding to and activation of T lymphocytes by cognate peptide-MHC complexes at the single-cell level, which can now be applied to distinguish between cognate responding and anergic T cells.

Gonadotropin stimulation of MLS human epithelial ovarian carcinoma cells augments cell adhesion mediated by CD44 and by alpha(v)-integrin.

OBJECTIVE: The goal of this work was to evaluate the involvement of gonadotropins in the regulation of adhesion of human epithelial ovarian carcinoma. We studied two pathways that were previously implicated in the metastatic implantation of ovarian carcinoma to the peritoneum, namely hyaluronan-CD44 and RGD-integrin mediated adhesion. METHODS: Two cell lines derived from human epithelial ovarian carcinoma (MLS and OC238) were stimulated with luteinizing hormone (LH) and/or follicle stimulating hormone (FSH). Expression of CD44 was evaluated by Western blotting. Expression of alpha(v)-integrins was studied by RT-PCR and Northern blot. Integrin and CD44 mediated adhesion of the cells was analyzed using culture plates coated either with a thrombin derived RGD containing peptide or fibronectin for integrin mediated adhesion or with hyaluronan for CD44 mediated adhesion. RESULTS: MLS cells stimulated with either LH or FSH showed increased adhesion to culture plates coated with hyaluronan, as well as to culture plates coated with fibronectin or with a thrombin derived RGD containing peptide. In these cells, gonadotropin stimulation led to induced expression of the integrin subunit alpha(v) and CD44, the cell surface hyaluronan receptor. On the other hand, OC238 cells showed no expression of the integrin subunit alpha(v) and no hormonal effect on the expression of CD44. Accordingly, adhesion of OC238 cells on either RGD or CD44 was not affected by hormonal stimulation. CONCLUSION: Elevated levels of gonadotropins may in some cases facilitate peritoneal metastatic dissemination of ovarian cancer by increasing cell adhesion, the first essential step in the invasion process.

Tumor sensitivity to anti-cancer drugs predicted by changes in fluorescence intensity and polarization in vitro.

BACKGROUND: We used the CellScan, a novel static cytometer, to monitor changes induced by anti-neoplastic drugs in the fluorescence intensity and polarization of fluorescently-labeled tumor cells. MATERIALS AND METHODS: T47D and T80 human breast cancer cell lines were exposed to navelbine and to 5-fluorouracil and the fluorescence properties of the treated cells, stained with fluorescein diacetate and rhodamine 123, were measured by the CellScan. RESULTS: A strong correlation was found between the inhibition of cell growth induced by the two drugs, as estimated from cell counts, and the resulting changes in fluorescence intensity and polarization, as monitored by the CellScan. Fluorescence hyperpolarization of the labeled cells occurred in conjunction with AnnexinV binding and propidium iodide exclusion, indicating that such hyperpolarization, resulting from drug action, reflects an early stage of apoptosis, as previously proposed. CONCLUSION: The system presented here could serve as the basis for assessing drug sensitivity or resistance of cancer cells derived from small biopsies of solid human tumors, thus eliminating prior tumor culturing and time-consuming assays.