Use Of Quantitative Image Analysis Research Articles

Delta radiomics analysis of Magnetic Resonance guided radiotherapy imaging data can enable treatment response prediction in pancreatic cancer

BackgroundMagnetic Resonance Image guided Stereotactic body radiotherapy (MRgRT) is an emerging technology that is increasingly used in treatment of visceral cancers, such as pancreatic adenocarcinoma (PDAC). Given the variable response rates and short progression times of PDAC, there is an unmet clinical need for a method to assess early RT response that may allow better prescription personalization. We hypothesize that quantitative image feature analysis (radiomics) of the longitudinal MR scans acquired before and during MRgRT may be used to extract information related to early treatment response.MethodsHistogram and texture radiomic features (n = 73) were extracted from the Gross Tumor Volume (GTV) in 0.35T MRgRT scans of 26 locally advanced and borderline resectable PDAC patients treated with 50 Gy RT in 5 fractions. Feature ratios between first (F1) and last (F5) fraction scan were correlated with progression free survival (PFS). Feature stability was assessed through region of interest (ROI) perturbation.ResultsLinear normalization of image intensity to median kidney value showed improved reproducibility of feature quantification. Histogram skewness change during treatment showed significant association with PFS (p = 0.005, HR = 2.75), offering a potential predictive biomarker of RT response. Stability analyses revealed a wide distribution of feature sensitivities to ROI delineation and was able to identify features that were robust to variability in contouring.ConclusionsThis study presents a proof-of-concept for the use of quantitative image analysis in MRgRT for treatment response prediction and providing an analysis pipeline that can be utilized in future MRgRT radiomic studies.

Quantitative Morphological Analysis of Filamentous Microorganisms in Cocultures and Monocultures: Aspergillus terreus and Streptomyces rimosus Warfare in Bioreactors

The aim of this study was to quantitatively characterize the morphology of the filamentous microorganisms Aspergillus terreus ATCC 20542 and Streptomyces rimosus ATCC 10970, cocultivated in stirred tank bioreactors, and to characterize their mutual influence with the use of quantitative image analysis. Three distinct coculture initiation strategies were applied: preculture versus preculture, spores versus spores and preculture versus preculture with time delay for one of the species. Bioreactor cocultures were accompanied by parallel monoculture controls. The results recorded for the mono- and cocultures were compared in order to investigate the effect of cocultivation on the morphological evolution of A. terreus and S. rimosus. Morphology-related observations were also confronted with the analysis of secondary metabolism. The morphology of the two studied filamentous species strictly depended on the applied coculture initiation strategy. In the cocultures initiated by the simultaneous inoculation, S. rimosus gained domination or advance over A. terreus. The latter microorganism dominated only in these experiments in which S. rimosus was introduced with a delay.

Quantitative image analysis as a robust tool to assess effluent quality from an aerobic granular sludge system treating industrial wastewater

Quantitative image analysis (QIA) is a simple and automated method for process monitoring, complementary to chemical analysis, that when coupled to mathematical modelling allows associating changes in the biomass to several operational parameters. The majority of the research regarding the use of QIA has been carried out using synthetic wastewater and applied to activated sludge systems, while there is still a lack of knowledge regarding the application of QIA in the monitoring of aerobic granular sludge (AGS) systems. In this work, chemical oxygen demand (COD), ammonium (N–NH4+), nitrite (N–NO2-), nitrate (N–NO3-), salinity (Cl−), and total suspended solids (TSS) levels present in the effluent of an AGS system treating fish canning wastewater were successfully associated to QIA data, from both suspended and granular biomass fractions by partial least squares models. The correlation between physical-chemical parameters and QIA data allowed obtaining good assessment results for COD (R2 of 0.94), N–NH4+ (R2 of 0.98), N–NO2- (R2 of 0.96), N–NO3- (R2 of 0.95), Cl− (R2 of 0.98), and TSS (R2 of 0.94). While the COD and N–NO2- assessment models were mostly correlated to the granular fraction QIA data, the suspended fraction was highly relevant for N–NH4+ assessment. The N–NO3-, Cl− and TSS assessment benefited from the use of both biomass fractions (suspended and granular) QIA data, indicating the importance of the balance between the suspended and granular fractions in AGS systems and its analysis. This study provides a complementary approach to assess effluent quality parameters which can improve wastewater treatment plants monitoring and control, with a more cost-effective and environmentally friendly procedure, while avoiding daily physical-chemical analysis.

Morpholiogical, quantitative image analysis and molecular biology of oesophageal squamous cell carcinoma (ESCC), with special reference to tumour progression and human papillomavirus (HPV) involvement

It is an urgent need to improve early diagnosis of ESCC, because is one of the most aggressive cancer. The quantitative image analysis can aid in the identification of ESCC. Despite much research effort, the major prognostic factor of ESCC remains the pathological stage of the disease as defined by the TNM classification, whereas tumour grading is of limited value in this respect, mainly due to its low reproducibility. A better means for disease prognostication based on improved understanding of the pathogenetic mechanisms is urgently required. Materials and methods: The material of the present study was derived from a series of 1876 oesophageal surgical specimens taken from a total of 700 patients, who underwent oesophageal resection for an invasive ESCC in Anyang Tumour Hospital, Henan Province of China. Among. The cases of ESCC, previously subjected to extensive testing for Human Papillomavirus (HPV) involvement and expression of p53 gene. All cases are analysed by histopathology and by in situ hybridisation (ISH) and PCR, and a group of 272 patients was randomly selected for analysis of the primary tumour, adjacent mucosa and regional lymph nodes, in the quantitative image analysis. All cases and HPV data were subjected to extensive univariate and multivariate analysis to disclose independent predictors of progressive disease. Results: For the analyses, the ESCCs were graded into two categories: well – moderately and poorly-differentiated. HPV DNA was detected in 116 (18.9 %) of the carcinomas by ISH and in 15.2 % by PCR. In univariate analysis, lymph node status was significantly (p < 0.01) predicted by the following nuclear parameters: nuclear area, G0/G1 ratio, HPV DNA status, integrated optical density (IOD), mean optical density (MOD) and S-Phase. In multivariate analysis, 6 variables remained as independent predictors of disease progression (p < 0.05 level), the three most significant ones being nuclear perimeter, nuclear roundness and equivalent diameter (p < 0.01). Conclusions: A series of quantitatively measured nuclear parameters seem to be a close correlation with ESCC differentiation and progression in univariate analysis and some of these variables proved to be significant independent predictors of disease progression in multivariate modelling as well. These data clearly advocate the use of quantitative image analysis in searching for additional prognostic factors of ESCC.

The cell resealing technique for manipulating, visualizing, and elucidating molecular functions in living cells

BackgroundCell-based assays are essential for analyzing molecular functions and spatiotemporal information. The cell resealing technique, in which pore-forming toxins are used to permeabilize cell membranes, enables the delivery of various membrane-impermeable molecules inside cells. Scope of reviewWe review the basics of the resealed cell system, including optimized protocols, assessment of cellular damage, and recovery following permeabilization of the membrane. Additionally, we introduce the streptolysin O (SLO)-type and listeriolysin O (LLO)-type resealing techniques. In SLO, the formation of larger pores (~30 nm) enables the passage of a wider range of molecules. Then, we discuss the advantages and applications of the semi-intact cell system, in which ongoing permeabilization is selected to maintain and analyze a specific cellular environment. Major conclusionsAs confirmed by the effective use of quantitative image analysis, the SLO-type resealing system is successful for establishing and phenotyping diabetic model cells by introducing cytosol from diabetic mice. The LLO-type resealing technique enables the delivery of mid-sized molecules with high efficiency and low damage. As each technique has specific advantages, understanding the characteristics of LLO and SLO is necessary for choosing the appropriate technique. General significanceSLO-type resealing is optimal for creating disease model cells and drug screening, especially lifestyle-related diseases. LLO-type resealing is expected to be suitable for screening mid-sized biological drugs. Semi-intact cells can contribute to elucidating various cellular phenomena that have remained intractable due to their complexity.

The use of Quantitative Image Analysis to Evaluate the Effectiveness of Microwave-assisted Formaldehyde Fixation in Breast Cancer Diagnostics

Extended abstract of a paper presented at Microscopy and Microanalysis 2012 in Phoenix, Arizona, USA, July 29 – August 2, 2012.

The Use of Quantitative Image Analysis to Evaluate the Effectiveness of Microwave-Assisted Formaldehyde Fixation

Extended abstract of a paper presented at Microscopy and Microanalysis 2011 in Nashville, Tennessee, USA, August 7–August 11, 2011.

Low Proliferation Index May Be Associated with Longer Time to First Therapy In Low Grade Follicular Lymphoma

AbstractAbstract 4149 BackgroundFollicular lymphoma (FL) is the second most common type of lymphoma in Europe and North America. Traditionally, FL has been graded according to the number of centroblasts in the follicles per high power field, to grades 1–3. This grading system, however, does not capture the clinical variability observed in low grade (1-2) FL. The recent WHO classification made it clear that clinically, FL grade 1 and 2 cannot be distinguished, with generally long median survival and recurrent relapses, while grade 3 FL generally has a more aggressive course. Though the clinical prognostic indices such as the FLIPI and the IPI can provide information regarding outcome, they fail to define the biology of the disease. Proliferation index (PI) as determined by Ki-67 immunohistochemistry (MIB-1) has been shown by some to have prognostic value in FL, while others did not find any significance. The PI value in FL is usually determined either by counting cells or by visual estimation. We previously validated the use of quantitative image analysis (QIA) in mantle cell lymphoma, and showed that it is a robust tool for determination of the PI. It is objective and highly reproducible. In this study we aim to evaluate the prognostic significance of PI in a retrospective cohort of pts with FL, grade 1–2. MethodsSpecimens from 73 FL pts (33 man, 40 women) diagnosed between the years 2001–2008 were identified. Clinical data was obtained by thorough chart review. All specimens were reviewed by an experienced hematopathologist and the grade confirmed. There were 59 grade 1–2 and 14 grade 3 cases. Slides were scanned with the ScanScopeXT (Aperio, Vista, CA) using brightfield imaging at 200x magnification. Follicles were annotated using ImageScope (Aperio) and analyzed using Aperio image analysis software. Inter-follicular areas were not analyzed. Survival analysis was done by the Kaplan-Meier method. Differences between groups were analyzed using chi-square test and Fisher's exact test. ResultsMedian age at diagnosis was 61.8 years. Median follow-up time for all 73 pts was 38.8 m (range 0.95 to 102.3). The median PI for the entire group was 33%. When analyzing grade 1 and 2 separately (no=59), the median was almost the same (32%) (Fig 1). We found no significant correlation between grade and PI in this cohort. Outcome for pts with grade 1–2 disease was analyzed by dividing the pts based on PI: low PI (PI<30%); and high PI group (PI>=30%). These two groups did not differ in clinical characteristics including: age, clinical stage, FLIPI score, or the indication for first treatment. Overall survival (OS) (median not reached) and event-free survival (EFS) (median 54.2 m) were not statistically different between the groups. However, time to first therapy (TTFT), was significantly shorter for the high PI group (p=0.01) (Fig 2). The median time to first therapy for FL, grade 1–2, was 3.4 m. Within this group, the time to first treatment was 2.1 m v 31.6 m, for the high and low PI groups, respectively. As the curves indicate, the difference between the groups starts approximately 3–6 months after diagnosis. A similar analysis of FLIPI risk group (low and intermediate v high) failed to demonstrated differences in OS, EFS and TTFT. [Display omitted] [Display omitted] ConclusionsWe conclude that PI varies significantly among low grade FL pts. This variability may relate to the clinical course of these pts. We have shown significantly different time to first therapy between the low and high PI groups. We plan to further explore differences in OS and EFS in a larger series of FL pts and confirm the predictive value of PI for TTFT.PI distribution as determined by QIA among all cases of FL.Time to first therapy for low grade FL pts separated to low and high PI. Disclosures:No relevant conflicts of interest to declare.

Detection and Localization of Intraepithelial Neoplasia and Invasive Carcinoma Using Fluorescence-Reflectance Bronchoscopy: An International, Multicenter Clinical Trial

The primary objective of this study was to evaluate the benefit of using a new fluorescence-reflectance imaging system, Onco-LIFE, for the detection and localization of intraepitheal neoplasia and early invasive squamous cell carcinoma. A secondary objective was to evaluate the potential use of quantitative image analysis with this device for objective classification of abnormal sites. This study was a prospective, multicenter, comparative, single arm trial. Subjects for this study were aged 45 to 75 years and either current or past smokers of more than 20 pack-years with airflow obstruction, forced expiratory volume in 1 second/forced vital capacity less than 75%, suspected to have lung cancer based on either sputum atypia, abnormal chest roentgenogram/chest computed tomography, or patients with previous curatively treated lung or head and neck cancer within 2 years. The primary endpoint of the study was to determine the relative sensitivity of white light bronchoscopy (WLB) plus autofluorescence-reflectance bronchoscopy compared with WLB alone. Bronchoscopy with Onco-LIFE was carried out in two stages. The first stage was performed under white light and mucosal lesions were visually classified. Mucosal lesions were classified using the same scheme in the second stage when viewed with Onco-LIFE in the fluorescence-reflectance mode. All regions classified as suspicious for moderate dysplasia or worse were biopsied, plus at least one nonsuspicious region for control. Specimens were evaluated by the site pathologist and then sent to a reference pathologist, each blinded to the endoscopic findings. Positive lesions were defined as those with moderate/severe dysplasia, carcinoma in situ (CIS), or invasive carcinoma. A positive patient was defined as having at least one lesion of moderate/severe dysplasia, CIS, or invasive carcinoma. Onco-LIFE was also used to quantify the fluorescence-reflectance response (based on the proportion of reflected red light to green fluorescence) for each suspected lesion before biopsy. There were 115 men and 55 women with median age of 62 years. Seven hundred seventy-six biopsy specimens were included. Seventy-six were classified as positive (moderate dysplasia or worse) by pathology. The relative sensitivity on a per-lesion basis of WLB + FLB versus WLB was 1.50 (95% confidence interval [CI], 1.26-1.89). The relative sensitivity on a per-patient basis was 1.33 (95% CI, 1.13-1.70). The relative sensitivity to detect intraepithelial neoplasia (moderate/severe dysplasia or CIS) was 4.29 (95% CI, 2.00-16.00) and 3.50 (95% CI, 1.63-12.00) on a per-lesion and per-patient basis, respectively. For a quantified fluorescence reflectance response value of more than or equal to 0.40, a sensitivity and specificity of 51% and 80%, respectively, could be achieved for detection of moderate/severe dsyplasia, CIS, and microinvasive cancer. Using autofluorescence-reflectance bronchoscopy as an adjunct to WLB with the Onco-LIFE system improves the detection and localization of intraepitheal neoplasia and invasive carcinoma compared with WLB alone. The use of quantitative image analysis to minimize interobserver variation in grading of abnormal sites should be explored further in future prospective clinical trial.

Whipple’s disease: immunospecific and quantitative immunohistochemical study of intestinal biopsy specimens

Whipple’s disease may be diagnosed by periodic acid-Schiff (PAS) staining, electron microscopy, or polymerase chain reaction of intestinal biopsy specimens. The aim of this study was to evaluate the diagnostic value of immunohistochemistry and the quantification of infected cells in intestinal Whipple’s disease. A total of 29 duodenal biopsy specimens from 15 patients with untreated and treated Whipple’s disease were examined and compared with biopsy specimens from control patients with normal intestinal mucosa or various pathologic processes. Percentages of staining surfaces with PAS stain and antibodies directed against CD68, a macrophage marker, or the Whipple bacillus, Tropheryma whipplei, were studied quantitatively using a computerized system of image analysis. Positive detection of T. whipplei was obtained using immunohistochemistry in all 15 patients with Whipple’s disease. No bacteria were detected in any of the negative controls. The use of quantitative image analysis showed a massive intestinal macrophagic infiltration before (20.3%) and after (13.4%) antibiotic therapy completion as compared with controls (2.1%). The 2 detection methods for T. whipplei, PAS stain and immunohistochemistry, were quantitatively similar before therapy (19.9% versus 17.5%), but the immunodetection-based surface area was significantly lower than the PAS staining surface area after therapy (2.8% versus 7.9%). Our findings indicate that immunohistochemistry is highly specific and sensitive and is applicable as a diagnostic method on intestinal tissue specimens to detect T. whipplei during active infection or in retrospective studies.

The use of quantitative image analysis in the assessment of in vitro embryotoxicity endpoints based on a novel embryonic stem cell clone with endoderm-related GFP expression

The capacity of pluripotent embryonic stem cells (ESC) to differentiate in vitro into various tissues provides the opportunity to develop an in vitro assay for investigating mechanisms of developmental toxicity. ESC clones carrying tissue specific reporter gene constructs are currently being developed. The clones should allow the quantification of the effects of chemicals on the development of germ layers and main target tissues. We report the establishment of the alpha-fetoprotein_GFP/D3 reporter gene clone: alpha-fetoprotein (AFP) enhancers and the homologous promoter regulate green fluorescent protein (GFP) expression in cells of the D3-ESC clone. AFP was used as a marker for endodermal cells. Differentiation of this clone via embryoid bodies (EBs, spheroids of cells) leads to green fluorescence on the surfaces of EBs. AFP- related GFP expression was confirmed. An easy and quick image analysis-based endpoint measurement was developed for quantifying low amounts of cells expressing GFP. As demonstrated with the embryotoxic chemical diphenylhydantoin, image analysis can be used to distinguish between a general effect on EB growth and a specific effect on the development of GFP-positive endodermal cells. Endoderm development was inhibited at a different dose than cardiomyocyte development.

Determination of the fracture mechanical parameters of porous ceramics from microstructure parameters measured by quantitative image analysis

The porosity that takes an important part in the failure process of three different ceramic materials (mullite, silicon carbide and silicon nitride) was characterised by means of Quantitative Image Analysis (QIA). Several parameters such as size, shape and orientation of pores have been evaluated. In parallel, the mechanical properties such as fracture toughness and Weibull modulus were directly measured. In order to appreciate the relevance of the use of QIA, the mechanical parameters have also been deduced from the microstructural features, and a comparison between measured and determined values was carried out. The results show a remarkable concordance.

Scanning force microscopy of circular and linear plasmid DNA spread on mica with a quaternary ammonium salt.

Scanning force microscopy (SFM) offers the potential for subnanometer resolution in the investigation of nucleic acids, proteins, and their complexes. SFM is not bound by the requirement of classical transmission electron microscopy (TEM) for contrast enhancement through shadow casting or negative staining. A primary challenge, however, has been the reproducible fixation of samples on an atomically flat surface such as mica. We have developed a method for the routine imaging by SFM of supercoiled, relaxed, and linearized plasmid DNA, immobilized on freshly cleaved mica through the spreading action of benzyldimethylalkylammonium chloride (BAC) at micromolar concentrations. A reproducibly high yield of well-spread, dispersed molecules is obtained and background contamination is minimal. The contour lengths of the relaxed and linearized molecules imaged in air agree well with the helical rise (3.4 A/bp) of B-DNA in solution. We have also introduced the use of quantitative image analysis of SFM images to determine apparent molecular width and height over the entire molecular path.

Image analysis techniques. The problem of the quantitative evaluation of thechromatin ultrastructure

The application of image analysis methods to conventional thin sections for electron microscopy to analyze the chromatin arrangement are quite limited. We developed a method which utilizes freeze-fractured samples; the results indicate that the method is suitable for identifying the changes in the chromatin arrangement which occur in physiological, experimental and pathological conditions. The modern era of image analysis begins in 1964, when pictures of the moon transmitted by Ranger 7 were processed by a computer. This processing improved the original picture by enhancing and restoring the image affected by various types of distorsion. These performances have been allowed by the third-generation of computers having the speed and the storage capabilities required for practical use of image processing algorithms. Each image can be converted into a two-dimensional light intensity function: f (x, y), where x and y are the spatial coordinates and f value is proportional to the gray level of the image at that point. The digital image is therefore a matrix whose elements are the pixels (picture elements). A typical digital image can be obtained with a quality comparable to monochrome TV, with a 512×512 pixel array with 64 gray levels. The magnetic disks of commercial minicomputers are thus capable of storing some tenths of images which can be elaborated by the image processor, converting the signal into digital form. In biological images, obtained by light microscopy, the digitation converts the chromatic differences into gray level intensities, thus allowing to define the contours of the cytoplasm, of the nucleus and of the nucleoli. The use of a quantitative staining method for the DNA, the Feulgen reaction, permits to evaluate the ratio between condensed chromatin (stained) and euchromatin (unstained). The digitized images obtained by transmission electron microscopy are rich in details at high resolution. However, the application of image analysis techniques to these images and especially to those referring to nuclei, is limited by several drawbacks: i) the thin section represents only a small fraction of the nuclear volume entirely visible in optical microscope specimens; ii) the identification of nucleosomes, of the solenoid fibres and of the higher levels of compaction of the heterochromatin is not thinsectioned specimens; iii) the differences between heterochromatin and euchromatin are based only on their grey level but do not reveal possible variations of their structural organization. Therefore, the applications of image analysis to the nuclear content does not utilzes the high resolution power of e.m. images and simply quantify the areas occupied by electron-dense chromatin with respect to the more electron-transparent ones. This result is less significative of those obtainable by optical microscopy, since the electron staining is not quantitative as the Fulgen reaction. On the other hand, the following problems still remain unresolved and should be clarified only by the use of quantitative image analysis: ultrastructural organization of the different types of heterochromatin (1); relationships between gene activation, transcription and chromatin decondensation; chromatin arrangement transformation induced by exogenous agents. In order to face these problems, in the last years we applied image analysis to cell or tissue specimens frozen in liquid nitrogen and then fractured in order to expose the inner content of the nucleus (Fig. 1). The obtained metal replicas represent very suitable specimens for digitalized image elaboration, since the fibers which give rise to the chromatin domains are exposed by the fracturing and evidentiated by the shadowing as black dots with a clear white shadow (Fig. 2). Therefore, their size and shape can be quantitatively evaluated by a digital image processor; in this vay the structural elements of the chromatin fibres are also detectable inside a fractured nucleus and their relative percentage ca be determined in each nuclear area (Fig. 3). This type of analysis has been initially used for characterizing in quantitative terms the organization of the nucleolar, heterochromatin and euchromatin areas in isolated nuclei (2) since the isolation procedure increases the differences among the nuclear domains. By using freeze-fractured isolated nuclei and conventional image analysis procedures, we quantitatively described the changes induced in the chromatin superstructure by the intercalating dye ethidium bromide (3), by the polyanionic phospholipid phosphatidylserine (4) and by the chemical carcinogen diethylnitrosamine (5). In all these cases, the principal affected parameter has been the ratio between the nucleosome and dolenoid percentage in different nuclear domains. The selection of a given class of particles, based on their size and/or shape, allowed to determine the spatial localization of some components such as the nuclear matrix, not easily detectable with conventional staining methods (6).