Human Colors—The Rainbow Garden of Pathology: What Gives Normal and Pathologic Tissues Their Color?

Piña‐Oviedo, Sergio; Ortíz-Hidalgo, Carlos; Ayala, Alberto G.

doi:10.5858/arpa.2016-0274-sa

Cited by 22 publications

(21 citation statements)

References 44 publications

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“…Gray matter derives its name from the gray color taken by the oxidation of vascularized tissue after formalin fixation (272) and largely constitutes the cell bodies of neurons as well as surrounding glial cells. White matter, called so because of the white lipids comprising a major component thereof, represents the myelinated or oligodendrocyte-sheathed axons projecting from them.…”

Section: Metabolite Quantificationmentioning

confidence: 99%

Quantifying the Metabolic Signature of Multiple Sclerosis by in vivo Proton Magnetic Resonance Spectroscopy: Current Challenges and Future Outlook in the Translation From Proton Signal to Diagnostic Biomarker

et al. 2019

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Proton magnetic resonance spectroscopy (1H-MRS) offers a growing variety of methods for querying potential diagnostic biomarkers of multiple sclerosis in living central nervous system tissue. For the past three decades, 1H-MRS has enabled the acquisition of a rich dataset suggestive of numerous metabolic alterations in lesions, normal-appearing white matter, gray matter, and spinal cord of individuals with multiple sclerosis, but this body of information is not free of seeming internal contradiction. The use of 1H-MRS signals as diagnostic biomarkers depends on reproducible and generalizable sensitivity and specificity to disease state that can be confounded by a multitude of influences, including experiment group classification and demographics; acquisition sequence; spectral quality and quantifiability; the contribution of macromolecules and lipids to the spectroscopic baseline; spectral quantification pipeline; voxel tissue and lesion composition; T1 and T2 relaxation; B1 field characteristics; and other features of study design, spectral acquisition and processing, and metabolite quantification about which the experimenter may possess imperfect or incomplete information. The direct comparison of 1H-MRS data from individuals with and without multiple sclerosis poses a special challenge in this regard, as several lines of evidence suggest that experimental cohorts may differ significantly in some of these parameters. We review the existing findings of in vivo 1H-MRS on central nervous system metabolic abnormalities in multiple sclerosis and its subtypes within the context of study design, spectral acquisition and processing, and metabolite quantification and offer an outlook on technical considerations, including the growing use of machine learning, by future investigations into diagnostic biomarkers of multiple sclerosis measurable by 1H-MRS.

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Section: Metabolite Quantificationmentioning

confidence: 99%

Quantifying the Metabolic Signature of Multiple Sclerosis by in vivo Proton Magnetic Resonance Spectroscopy: Current Challenges and Future Outlook in the Translation From Proton Signal to Diagnostic Biomarker

et al. 2019

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“…OP has been found after damage to various other human tissues like heart, liver, colon, and testis and is considered to be a nonspecific sign of cell death. 37 In this study, we have noticed that OP gradually increased over the first 3 years after radiation. The clumps of gross OP consolidated and became more prominent, as if the OP revealed itself or more likely increased after treatment.…”

Section: Discussionmentioning

confidence: 57%

Regression patterns of choroidal melanoma: After palladium-103 (¹⁰³Pd) plaque brachytherapy

Maheshwari

Finger

2018

European Journal of Ophthalmology

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Purpose:To describe the patterns of regression of choroidal melanoma after treatment with plaque brachytherapy.Methods:Retrospective interventional case series including 170 consecutive patients treated with 103Pd eye plaque radiation for choroidal melanoma. Outcome measures were changes in tumor thickness, surface characteristics, tumor vascularity, ultrasonography, fluorescein angiography, optical coherence tomography, and histopathology.Results:The mean initial tumor thickness was 3.9 mm (median 2.8 mm; range 2–11.3 mm) that decreased to 1.7 mm (median 1.2 mm; range 0–7.1 mm) after plaque brachytherapy. On imaging, tumors were pigmented in 51% (n = 86/170), amelanotic in 10% (n = 17/170), and variably pigmented in 39% (n = 67/170). Tumor pigmentation increased in 64% (n = 106/166), decreased in 18% (n = 30/166), and was unchanged in 18% (n = 30/166). Of the 120 that demonstrated intrinsic vascularity, 10% (n = 12/120) had decreased tumor-related vascularity and 90% (n = 108/120) showed complete resolution. Subretinal fluid was present in 34% (n = 58/170) of eyes at presentation. Of them, 15% (9; n = 9/58) had persistent SRF at last follow-up. On ultrasound imaging, 88% (n = 149/170) tumors presented with low to moderate internal reflectivity of which 61% (n = 91/149) showed increased reflectivity on regression. We noted a crescendo–decrescendo fluctuation in the presence of orange pigment lipofuscin along with complete resolution of drusenoid retinal pigment epithelial detachments. In the entire series of 170 patients, there was 0.5% (1) failure of local control, 2% (4) secondary enucleations, and 6% (10) patients developing metastasis.Conclusion:Findings related to choroidal melanoma regression after 103Pd plaque brachytherapy included decreased intrinsic tumor vascularity, decreased tumor-related subretinal fluid, increased pigmentation, specific changes in orange pigment lipofuscin and resolution of drusenoid retinal pigment epithelial detachments, as well as decreased tumor thickness with an increase in internal reflectivity on ultrasound.

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“…20 Hematein should not be confused with hematin, the blue to black-brown compound formed after oxidation of hemoglobin. 22 The ripening process may also be accomplished by different methods. For example, Delafield's (Francis Delafield, 1841-1915), and Ehrlich's (Paul Ehrlich, 1854-1915) methods rely on atmospheric oxygen for oxidation.…”

Section: Hematoxylin the Dye Extract From Palo De Campechementioning

confidence: 99%

“…20 Hematein should not be confused with hematin, the blue to black-brown compound formed after oxidation of hemoglobin. 22…”

Section: Hematoxylin the Dye Extract From Palo De Campechementioning

confidence: 99%

Hematoxylin: Mesoamerica’s Gift to Histopathology. Palo de Campeche (Logwood Tree), Pirates’ Most Desired Treasure, and Irreplaceable Tissue Stain

Ortíz-Hidalgo

Piña‐Oviedo

2018

Int J Surg Pathol

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Hematoxylin is a basic dye derived from the heartwood of Palo de Campeche ( Haematoxylum campechianum), the logwood tree native to Mexico and Central America. Haematoxylum means "bloodwood" in reference to its dark-red heartwood and campechianum refers to its site of origin, the coastal city of Campeche on the Yucatan Peninsula, Mexico. Hematoxylin is colorless but it turns into the color dye hematein after oxidation (ripening). The dyeing property of logwood was well-known to the natives of the Yucatan Peninsula before the arrival of the Spaniards who brought it to Europe shortly after the discovery of the Americas. An important trade soon developed related to growing and preparing hematoxylin for dyeing fabrics. Pirates discovered that one shipload of logwood was equivalent to a year's value from any other cargo, and by 1563, more than 400 pirate vessels wandered the Atlantic Ocean and attacked Spanish galleons transporting gold, silver, and logwood from the Americas to Europe. Hematoxylin and eosin is a staining method that dates back to the late 19th century. In 1865 and 1891, Böhmer and Meyer, respectively, first used hematoxylin in combination with a mordant (alum). Later, with the use of anilines by Ehrlich, the repertoire of stains expanded rapidly resulting in the microscopic descriptions of multiple diseases that were defined by their stainable features. Today hematoxylin, along with eosin, remains the most popular stain in histology.

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Human Colors—The Rainbow Garden of Pathology: What Gives Normal and Pathologic Tissues Their Color?

Cited by 22 publications

References 44 publications

Quantifying the Metabolic Signature of Multiple Sclerosis by in vivo Proton Magnetic Resonance Spectroscopy: Current Challenges and Future Outlook in the Translation From Proton Signal to Diagnostic Biomarker

Quantifying the Metabolic Signature of Multiple Sclerosis by in vivo Proton Magnetic Resonance Spectroscopy: Current Challenges and Future Outlook in the Translation From Proton Signal to Diagnostic Biomarker

Regression patterns of choroidal melanoma: After palladium-103 (¹⁰³Pd) plaque brachytherapy

Hematoxylin: Mesoamerica’s Gift to Histopathology. Palo de Campeche (Logwood Tree), Pirates’ Most Desired Treasure, and Irreplaceable Tissue Stain

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Human Colors—The Rainbow Garden of Pathology: What Gives Normal and Pathologic Tissues Their Color?

Cited by 22 publications

References 44 publications

Quantifying the Metabolic Signature of Multiple Sclerosis by in vivo Proton Magnetic Resonance Spectroscopy: Current Challenges and Future Outlook in the Translation From Proton Signal to Diagnostic Biomarker

Quantifying the Metabolic Signature of Multiple Sclerosis by in vivo Proton Magnetic Resonance Spectroscopy: Current Challenges and Future Outlook in the Translation From Proton Signal to Diagnostic Biomarker

Regression patterns of choroidal melanoma: After palladium-103 (103Pd) plaque brachytherapy

Hematoxylin: Mesoamerica’s Gift to Histopathology. Palo de Campeche (Logwood Tree), Pirates’ Most Desired Treasure, and Irreplaceable Tissue Stain

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Regression patterns of choroidal melanoma: After palladium-103 (¹⁰³Pd) plaque brachytherapy