Estudo da reprodutibilidade do exame de microscopia especular de córnea em amostras com diferentes números de células / Reproducibility study of the corneal specular microscope in samples with different number of cells

Holzchuh, Ricardo

19 August 2011

INTRODUÇÃO: O endotélio corneal exerce papel primordial para a fisiologia da córnea. Seus dados morfológicos gerados pelo microscópio especular (MEC) como densidade endotelial (DE), área celular média (ACM), coeficiente de variação (CV) e porcentagem de células hexagonais (HEX) são importantes para avaliar sua vitalidade. Para interpretar estes dados de forma padronizada e reprodutível, foi utilizado um programa estatístico de análise amostral, Cells Analyzer PAT. REQ.(CA). OBJETIVO: Demonstrar valores de referência para DE, ACM, CV e HEX. Demonstrar o percentual de células endoteliais marcadas e desconsideradas no exame ao marcar-se 40, 100 e 150 células em uma única imagem do mosaico endotelial e o perfil do intervalo de confiança (IC) das variáveis estudadas ao se considerar 40, 100, 150 e tantas células quantas indicadas pelo CA. Demonstrar o erro amostral de cada grupo estudado. MÉTODOS: Estudo transversal. Os exames de MEC foram realizados com o aparelho Konan NONCON ROBO® SP-8000, nos 122 olhos de 61 portadores de catarata (63,97 ± 8,15 anos de idade). As imagens endoteliais caracterizaram se pelo número de células marcadas e consideradas para cálculo dos seguintes dados: DE, ACM, CV e HEX. Os grupos foram formados de 40, 100, 150 células marcadas numa única imagem endotelial e Grupo CA em que foram marcadas tantas células quanto necessárias em diferentes imagens, para obter o erro relativo calculado inferior ao planejado (0,05), conforme orientação do programa CA. Estudou-se o efeito do número de células sobre IC para as variáveis endoteliais utilizadas. RESULTADOS: A média dos valores de referência encontrados para DE foi 2395,37 ± 294,34 cel/mm2; ACM 423,64 ± 51,09 m2; CV 0,40 ± 0,04 e HEX 54,77 ± 4,19%. O percentual de células endoteliais desconsideradas no Grupo 40 foi 51,20%; no Grupo 100, 35,07% e no Grupo 150, 29,83%. O número médio de células calculado inicialmente pelo CA foi 247,48 ± 51,61 e o número médio de células efetivamente incluídas no final do processo amostral foi 425,25 ± 102,24. O erro amostral dos exames no Grupo 40 foi 0,157 ± 0,031; Grupo 100, 0,093 ± 0,024; Grupo 150, 0,075 ± 0,010 e Grupo CA, 0,037 ± 0,005. O aumento do número de células diminuiu a amplitude do IC nos olhos direito e esquerdo para a DE em 75,79% e 77,39%; ACM em 75,95% e 77,37%; CV em 72,72% e 76,92%; HEX em 75,93% e 76,71%. CONCLUSÃO: Os valores de referência da DE foi 2395,37 ± 294,34 cel/mm2; ACM foi 423,64 ± 51,09 m2; CV foi 0,40 ± 0,04 e HEX foi 54,77 ± 4,19%. O percentual de células endoteliais desconsideradas no Grupo 40 foi 51,20%; no Grupo 100 foi 35,07% e no Grupo 150 foi 29,83%. O programa CA considerou correto os exames nos quais 425,25 ± 102,24 células foram marcadas entre duas e cinco imagens (erro relativo calculado de 0,037 ± 0,005). O aumento do número de células diminuiu a amplitude do IC para todas as variáveis endoteliais avaliadas pela MEC / INTRODUCTION: Corneal endothelium plays an important role in physiology of the cornea. Morphological data generated from specular microscope such as endothelial cell density (CD), average cell area (ACA), coefficient of variance (CV) and percentage of hexagonal cells (HEX) are important to analyze corneal status. For a standard and reproducible analysis of the morphological data, a sampling statistical software called Cells Analyzer PAT. REC (CA) was used. PURPOSE: To determine normal reference values of CD, ACA, CV and HEX. To analyze the percentage of marked and excluded cells when the examiner counted 40, 100, 150 cells in one endothelial image. To analyze the percentage of marked and excluded cells according to the statistical software. To determine the confidence interval of these morphological data. METHODS: Transversal study of 122 endothelial specular microscope image (Konan, non-contact NONCON ROBO® SP- 8000 Specular Microscope) of 61 human individuals with cataract (63.97 ± 8.15 years old) was analyzed statistically using CA. Each image was submitted to standard cell counting. 40 cells were counted in study Group 40; 100 cells were counted in study Group 100; and 150 cells were counted in study Group 150. In study group CA, the number of counted cells was determined by the statistical analysis software in order to achieve the most reliable clinical information (relative error < 0,05). Relative error of the morphological data generated by the specular microscope were then analyzed by statistical analysis using CA software. For Group CA, relative planned error was set as 0.05. RESULTS: The average normal reference value of CD was 2395.37 ± 294.34 cells/mm2, ACA was 423.64 ± 51.09 m2, CV was 0.40 ± 0.04 and HEX was 54.77 ± 4.19%. The percentage of cells excluded for analysis was 51.20% in Group 40; 35.07% in Group 100; and 29.83% in Group 150. The average number of cells calculated initially by the statistical software was 247.48 ± 51.61 cells and the average number of cells included in the final sampling process was 425.25 ± 102.24 cells. The average relative error was 0.157 ± 0.031 for Group 40; 0.093 ± 0.024 for Group 100; 0.075 ± 0.010 for Group 150 and 0.037 ± 0.005 for Group CA. The increase of the marked cells decreases the amplitude of confidence interval (right and left eyes respectively) in 75.79% and 77.39% for CD; 75.95% and 77.37% for ACA; 72.72% and 76.92% for CV; 75.93% and 76.71% for HEX. CONCLUSION: The average normal reference value of CD was 2395.37 ± 294.34 cells/mm2, ACA was 423.64 ± 51.09 m2, CV was 0.40 ± 0.04 and HEX was 54.77 ± 4.19%. The percentage of excluded cells for analysis was 51.20% in Group 40; 35.07% in Group 100 and 29.83% in Group 150. CA software has considered reliable data when 425.25 ± 102.24 cells were marked by the examiner in two to five specular images (calculated relative error of 0.037 ± 0.005). The increase of the marked cells decreases the amplitude of confidence interval for all morphological data generated by the specular microscope

Análise de estatística

Cell count

Contagem de células

Corneal endothelium

Endotélio da córnea

Microscopia/métodos

Microscopy/methods

Sample size

Statistical analysis

Tamanho da amostra

Estudo da reprodutibilidade do exame de microscopia especular de córnea em amostras com diferentes números de células / Reproducibility study of the corneal specular microscope in samples with different number of cells

Ricardo Holzchuh

19 August 2011

INTRODUÇÃO: O endotélio corneal exerce papel primordial para a fisiologia da córnea. Seus dados morfológicos gerados pelo microscópio especular (MEC) como densidade endotelial (DE), área celular média (ACM), coeficiente de variação (CV) e porcentagem de células hexagonais (HEX) são importantes para avaliar sua vitalidade. Para interpretar estes dados de forma padronizada e reprodutível, foi utilizado um programa estatístico de análise amostral, Cells Analyzer PAT. REQ.(CA). OBJETIVO: Demonstrar valores de referência para DE, ACM, CV e HEX. Demonstrar o percentual de células endoteliais marcadas e desconsideradas no exame ao marcar-se 40, 100 e 150 células em uma única imagem do mosaico endotelial e o perfil do intervalo de confiança (IC) das variáveis estudadas ao se considerar 40, 100, 150 e tantas células quantas indicadas pelo CA. Demonstrar o erro amostral de cada grupo estudado. MÉTODOS: Estudo transversal. Os exames de MEC foram realizados com o aparelho Konan NONCON ROBO® SP-8000, nos 122 olhos de 61 portadores de catarata (63,97 ± 8,15 anos de idade). As imagens endoteliais caracterizaram se pelo número de células marcadas e consideradas para cálculo dos seguintes dados: DE, ACM, CV e HEX. Os grupos foram formados de 40, 100, 150 células marcadas numa única imagem endotelial e Grupo CA em que foram marcadas tantas células quanto necessárias em diferentes imagens, para obter o erro relativo calculado inferior ao planejado (0,05), conforme orientação do programa CA. Estudou-se o efeito do número de células sobre IC para as variáveis endoteliais utilizadas. RESULTADOS: A média dos valores de referência encontrados para DE foi 2395,37 ± 294,34 cel/mm2; ACM 423,64 ± 51,09 m2; CV 0,40 ± 0,04 e HEX 54,77 ± 4,19%. O percentual de células endoteliais desconsideradas no Grupo 40 foi 51,20%; no Grupo 100, 35,07% e no Grupo 150, 29,83%. O número médio de células calculado inicialmente pelo CA foi 247,48 ± 51,61 e o número médio de células efetivamente incluídas no final do processo amostral foi 425,25 ± 102,24. O erro amostral dos exames no Grupo 40 foi 0,157 ± 0,031; Grupo 100, 0,093 ± 0,024; Grupo 150, 0,075 ± 0,010 e Grupo CA, 0,037 ± 0,005. O aumento do número de células diminuiu a amplitude do IC nos olhos direito e esquerdo para a DE em 75,79% e 77,39%; ACM em 75,95% e 77,37%; CV em 72,72% e 76,92%; HEX em 75,93% e 76,71%. CONCLUSÃO: Os valores de referência da DE foi 2395,37 ± 294,34 cel/mm2; ACM foi 423,64 ± 51,09 m2; CV foi 0,40 ± 0,04 e HEX foi 54,77 ± 4,19%. O percentual de células endoteliais desconsideradas no Grupo 40 foi 51,20%; no Grupo 100 foi 35,07% e no Grupo 150 foi 29,83%. O programa CA considerou correto os exames nos quais 425,25 ± 102,24 células foram marcadas entre duas e cinco imagens (erro relativo calculado de 0,037 ± 0,005). O aumento do número de células diminuiu a amplitude do IC para todas as variáveis endoteliais avaliadas pela MEC / INTRODUCTION: Corneal endothelium plays an important role in physiology of the cornea. Morphological data generated from specular microscope such as endothelial cell density (CD), average cell area (ACA), coefficient of variance (CV) and percentage of hexagonal cells (HEX) are important to analyze corneal status. For a standard and reproducible analysis of the morphological data, a sampling statistical software called Cells Analyzer PAT. REC (CA) was used. PURPOSE: To determine normal reference values of CD, ACA, CV and HEX. To analyze the percentage of marked and excluded cells when the examiner counted 40, 100, 150 cells in one endothelial image. To analyze the percentage of marked and excluded cells according to the statistical software. To determine the confidence interval of these morphological data. METHODS: Transversal study of 122 endothelial specular microscope image (Konan, non-contact NONCON ROBO® SP- 8000 Specular Microscope) of 61 human individuals with cataract (63.97 ± 8.15 years old) was analyzed statistically using CA. Each image was submitted to standard cell counting. 40 cells were counted in study Group 40; 100 cells were counted in study Group 100; and 150 cells were counted in study Group 150. In study group CA, the number of counted cells was determined by the statistical analysis software in order to achieve the most reliable clinical information (relative error < 0,05). Relative error of the morphological data generated by the specular microscope were then analyzed by statistical analysis using CA software. For Group CA, relative planned error was set as 0.05. RESULTS: The average normal reference value of CD was 2395.37 ± 294.34 cells/mm2, ACA was 423.64 ± 51.09 m2, CV was 0.40 ± 0.04 and HEX was 54.77 ± 4.19%. The percentage of cells excluded for analysis was 51.20% in Group 40; 35.07% in Group 100; and 29.83% in Group 150. The average number of cells calculated initially by the statistical software was 247.48 ± 51.61 cells and the average number of cells included in the final sampling process was 425.25 ± 102.24 cells. The average relative error was 0.157 ± 0.031 for Group 40; 0.093 ± 0.024 for Group 100; 0.075 ± 0.010 for Group 150 and 0.037 ± 0.005 for Group CA. The increase of the marked cells decreases the amplitude of confidence interval (right and left eyes respectively) in 75.79% and 77.39% for CD; 75.95% and 77.37% for ACA; 72.72% and 76.92% for CV; 75.93% and 76.71% for HEX. CONCLUSION: The average normal reference value of CD was 2395.37 ± 294.34 cells/mm2, ACA was 423.64 ± 51.09 m2, CV was 0.40 ± 0.04 and HEX was 54.77 ± 4.19%. The percentage of excluded cells for analysis was 51.20% in Group 40; 35.07% in Group 100 and 29.83% in Group 150. CA software has considered reliable data when 425.25 ± 102.24 cells were marked by the examiner in two to five specular images (calculated relative error of 0.037 ± 0.005). The increase of the marked cells decreases the amplitude of confidence interval for all morphological data generated by the specular microscope

Análise de estatística

Contagem de células

Endotélio da córnea

Microscopia/métodos

Tamanho da amostra

Cell count

Corneal endothelium

Microscopy/methods

Sample size

Statistical analysis

Mechanical property and biocompatibility of PLLA coated DCPD composite scaffolds

Tanataweethum, Nida

21 May 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Dicalcium phosphate dihydrate (DCPD) cements have been used for bone repair due to its excellent biocompatibility and resorbability. However, DCPD cements are typically weak and brittle. To overcome these limitations, the sodium citrate used as a setting regulator and the coating of poly-L-lactide acid (PLLA) technique have been proposed in this study. The first purpose of this thesis is to develop composite PLLA/DCPD scaffolds with enhanced toughness by PLLA coating. The second purpose is to examine the biocompatibility of the scaffolds. The final purpose is to investigate the degradation behaviors of DCPD and PLLA/DCPD scaffolds. In this experiment, DCPD cements were synthesized from monocalcium phosphate monohydrate (MCPM) and 𝛽-tricalcium phosphate (𝛽 –TCP) by using deionized water and sodium citrate as liquid components. The samples were prepared with powder to liquid ratio (P/L) at 1.00, 1.25 and 1.50. To fabricate the PLLA/DCPD composite samples, DCPD samples were coated with 5 % PLLA. The samples were characterized mechanical properties, such as porosity, diametral tensile strength, and fracture energy. The mechanical properties of DCPD scaffolds with and without PLLA coating after the in vitro static degradation (day 1, week1, 4, and 6) and in vitro dynamic degradation (day 1, week 1, 2, 4, 6, and 8) were investigated by measuring their weight loss, fracture energy, and pH of phosphate buffer solution. In addition, the dog bone marrow stromal stem cells (dBMSCs) adhesion on DCPD and PLLA/DCPD composite samples were examined by scanning electron microscopy. The cell proliferation and differentiation in the medium conditioned with DCPD and PLLA/DCPD composite samples were studied by XTT (2,3-Bis(2-methoxy-4- nitro-5-sulfophenyl)-2H-tetrazolium-5-carboxanilide inner salt), and alkaline phosphatase (ALP) assay, respectively. The addition of sodium citrate and PLLA coating played a crucial role in improving the mechanical properties of the samples by increasing the diametral tensile strength from 0.50 ± 0.15 MPa to 2.70 ± 0.54 MPa and increasing the fracture energy from 0.76 ± 0.18 N-mm to 12.67 ± 4.97 N-mm. The DCPD and PLLA/DCPD composite samples were compatible with dBMSCs and the cells were able to proliferate and differentiate in the conditioned medium. The degradation rate of DCPD and PLLA/DCPD samples were not significant different (p > 0.05). However, the DCPD and PLLA/DCPD composite samples those used sodium citrate as a liquid component was found to degrade faster than the groups that use deionized water as liquid component

Porosity

Analysis of variance -- Statistics

Materials -- Mechanical properties

Scanning electron microscopy -- Methods

Bone remodeling