Carboxyterminal degradation products of type I collagen

Sassi, M.-L. (Mirja-Liisa)

03 August 2001

Abstract The assay for the carboxyterminal telopeptide of type I collagen, ICTP, has been shown to be a reliable marker in many pathological conditions but insensitive to changes in physiological bone turnover. This has induced uncertainty and confusion regarding the role of ICTP assay in the study of collagen metabolism in bones. Especially, since another assay for the carboxyterminal telopeptide of type I collagen, serum CrossLaps ELISA, sensitively follows the changes in physiological bone turnover. To find out the reasons for the discrepancy we characterized the antigenic determinant of the ICTP assay by comparing human and bovine antigens after trypsin and chymotrypsin treatments. An assay for bovine ICTP was developed contemporarily with the present study. The epitope lies on the phenylalanine rich region of two telopeptide chains. We were able to show that the region is destroyed by cathepsin K, an osteoclastic enzyme responsible for physiological bone turnover, but not by several matrix metalloproteinases (MMPs), which are important collagen degrading enzymes in pathological conditions. Cathepsin K treatment had no effect on the CrossLaps assay. The CrossLaps assay is also able to measure the MMP-derived fragments, but usually their amount is so low in serum that it is masked by the cathepsin K-derived collagen degradation. The results explain the apparent discrepancy regarding the different behaviour of ICTP and CrossLaps assays in various conditions as also verified in our study with rheumatoid arthritis patients. The ICTP assay was also found to measure only trivalently cross-linked forms of the carboxyterminal telopeptide which contains two telopeptide chains, and is therefore unable to react with divalently or histidinohydroxylysinonorleucine (HHL)-cross-linked forms of the carboxyterminal telopeptide. These forms can be measured with the SP4 (synthetic peptide 4) assay. We utilized this property in analyzing the skin samples of 18 breast cancer patients on both the irradiated and unirradiated side. The content of HHL was increased on the irradiated side, as were type I collagen synthesis and degradation. In conclusion, there are two assays for two different degradation products of the trivalently cross-linked carboxyterminal telopeptide of type I collagen, ICTP and CrossLaps, the former measuring the MMP-derived and the latter the cathepsin K-derived collagen degradation.

Cathepsin K

CrossLaps

ICTP

MMPs

Integrated CFD Model for Nanoparticle Production in Inductively Coupled Plasma Reactor: Implementation and Application

Benros Santos Lopes, Silvania

24 May 2016

Nanoparticles represent a very exciting new area of research. Their small size, ranging from several nanometers to tens of nanometers, is responsible for many changes in the structural, thermal, electromagnetic, optical and mechanical properties in comparison with the bulk solid of the same materials. However, promoting the use of such material requires well-controlled synthesis techniques to be developed. Inductively coupled thermal plasma (ICTP) reactors have been shown to offer unique advantages over other synthesis methods. The purpose of this thesis is to develop a numerical model to assist the design of an ICTP reactor for the efficient and controlled production of nanoparticles at industrial scale. The complete model describes the evaporation of the micron-sized precursor particles in the plasma flow and the subsequent formation of the nanoparticles in the quenching reactor. The plasma flow is described by a coupled system of the fluid mechanics equations of continuity, momentum, and energy with the vector potential formulation of Maxwell's equations. The solid particles precursors are treated following a Lagrangian approach, taking into account the vapor production field in the plasma flow. An Eulerian model based on the method of moments with interpolative closure is used to describe the formation of nanoparticles by simultaneous nucleation and growth by condensation and coagulation. The coupled plasma torch, particle evaporation and nanoparticle formation models are implemented in 2D and 3D configurations, using the OpenFoam source code. The results show that the effects of the particle evaporation on the temperature field are substantial, even for low particle mass loading. The associated vapor concentration which enters in the reactor has then a direct influence on the formation of nanoparticles. The effects of the plasma torch parameters and the quenching configuration (quench type, position, injection angle and cooling rate) on the contribution of the different formation mechanisms and on the generated particle's size and distribution are studied in both 2D axi-symmetric and 3D geometries. The quench mechanism strongly affects the temperature and the vapor concentration in the reactor, and consequently has an impact on the final particle size distribution. It is shown that the size of the nanoparticles obtained for different quenching conditions is not only a consequence of the cooling rate but also of the trajectories of the vapor and the generated particles imposed by quenching gas. The results have also demonstrated that the predicted particle are smaller and more sensitive to the modifications of the quenching condition when quenching at high temperature. The sensitivity of the complete model to the physical properties of the vapor (vapor pressure and surface tension) is also investigated, in order to identify their effect on the final particle size. The results obtained provide an insight into the phenomena involved during the production of nanoparticles and enable the improvement of ICTP rectors design and nanoparticles synthesis process. / Doctorat en Sciences de l'ingénieur et technologie / info:eu-repo/semantics/nonPublished

Sciences de l'ingénieur

Inductively coupled thermal plasma

ICTP

ICP

Plasma flow simulation

Nanoparticle formation simulation

Nucleation

Condensation

Coagulation

Method of moment

Quenching

OpenFoam