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The VP series of Isothermal Titration (ITC) and differential Scanning (DSC) Calorimetry systems represent major advances in sensitivity, reproducibility, stability and ease of use as compared to any other commercially available ITC or DSC system. This translates into smaller sample requirements, greater precision, minimal use of bench space and the ability to quickly generate high quality data with less time and effort. Calorimetry is a universal detection system as heat is either generated or absorbed in any chemical process. This permits the study of molecular interactions and conformational energetic using native materials. There is no need to chemically modify your materials, which can lead to erroneous results. Calorimetry is widely used to study biomolecular binding, kinetics, stability in the life science. - �����`���� - ��(sh��)�(y��n)�ĕr(sh��)�� - ��Ʒ������ - ܛ�����ƺ͔�(sh��)��(j��)̎�� - ȫ�ן��(d��ng)���W(xu��)��(sh��)��(j��), �� ��H, ��Cp, ��S, ��G, Ka , n ��.

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The VP series of Isothermal Titration (ITC) and differential Scanning (DSC) Calorimetry systems represent major advances in sensitivity, reproducibility, stability and ease of use as compared to any other commercially available ITC or DSC system. This translates into smaller sample requirements, greater precision, minimal use of bench space and the ability to quickly generate high quality data with less time and effort. Calorimetry is a universal detection system as heat is either generated or absorbed in any chemical process. This permits the study of molecular interactions and conformational energetic using native materials. There is no need to chemically modify your materials, which can lead to erroneous results. Calorimetry is widely used to study biomolecular binding, kinetics, stability in the life science. - �����`���� - ��(sh��)�(y��n)�ĕr(sh��)�� - ��Ʒ������ - ܛ�����ƺ͔�(sh��)��(j��)̎�� - ȫ�ן��(d��ng)���W(xu��)��(sh��)��(j��), �� ��H, ��Cp, ��S, ��G, Ka , n ��.

VP-ITC�Ȝصζ�΢������x ��icroCal

The VP series of Isothermal Titration (ITC) and differential Scanning (DSC) Calorimetry systems represent major advances in sensitivity, reproducibility, stability and ease of use as compared to any other commercially available ITC or DSC system. This translates into smaller sample requirements, greater precision, minimal use of bench space and the ability to quickly generate high quality data with less time and effort. Calorimetry is a universal detection system as heat is either generated or absorbed in any chemical process. This permits the study of molecular interactions and conformational energetic using native materials. There is no need to chemically modify your materials, which can lead to erroneous results. Calorimetry is widely used to study biomolecular binding, kinetics, stability in the life science. - �����`���� - ��(sh��)�(y��n)�ĕr(sh��)�� - ��Ʒ������ - ܛ�����ƺ͔�(sh��)��(j��)̎�� - ȫ�ן��(d��ng)���W(xu��)��(sh��)��(j��), �� ��H, ��Cp, ��S, ��G, Ka , n ��.

VP-DSC��ʾ����΢������xMicroCal , USA

The VP series of Isothermal Titration (ITC) and differential Scanning (DSC) Calorimetry systems represent major advances in sensitivity, reproducibility, stability and ease of use as compared to any other commercially available ITC or DSC system. This translates into smaller sample requirements, greater precision, minimal use of bench space and the ability to quickly generate high quality data with less time and effort. Calorimetry is a universal detection system as heat is either generated or absorbed in any chemical process. This permits the study of molecular interactions and conformational energetic using native materials. There is no need to chemically modify your materials, which can lead to erroneous results. Calorimetry is widely used to study biomolecular binding, kinetics, stability in the life science. - �����`���� - ��(sh��)�(y��n)�ĕr(sh��)�� - ��Ʒ������ - ܛ�����ƺ͔�(sh��)��(j��)̎�� - ȫ�ן��(d��ng)���W(xu��)��(sh��)��(j��), �� ��H, ��Cp, ��S, ��G, Ka , n ��.

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