Ultrastructural study of upper surface layer in rat articular cartilage by "in vivo cryotechnique" combined with various treatments

Histochemistry and Cell Biology

et al. 2004

A quick-freezing and deep-etching method in combination with replica immunoelectron microscopy was applied for examining localization of hyaluronic acid and fibronectin on the upper surface layer of rat mandibular condylar cartilage. Rat temporomandibular joints were dissected with articular disks in order to leave the articular cartilage surface intact. The disks were slightly cut with razor blades for exposing the condylar articular cartilage surface. They were quickly frozen with the isopentane-propane cryogen (-193 degrees C) and prepared for freeze-fracturing and deep-etching replica membranes. They were additionally treated with 5% SDS and 0.5% collagenase to keep some antigens attached on the replica membranes. After such a treatment, a routine immunogold method was applied for clarifying the localization of hyaluronic acid and fibronectin in the upper surface layer. Small immunogold particles for hyaluronic acid were mainly localized around upper filamentous networks covered with amorphous materials, but large immunogold ones for fibronectin were localized on deep thicker fibrils. We have revealed the native architecture of the upper surface layer of mandibular condylar cartilage on the replica membranes and also three-dimensional localization of hyaluronic acid and fibronectin by the immunogold method.

Section: Discussionsupporting

confidence: 92%

Section: Methodsmentioning

confidence: 95%

Section: Quick-freezing and Deep-etching Methodsmentioning

confidence: 99%

Section: Quick-freezing and Deep-etching Methodsmentioning

confidence: 99%

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Replica immunoelectron microscopic study of the upper surface layer in rat mandibular condylar cartilage by a quick-freezing method

Zea-Aragón

Terada

Histochemistry and Cell Biology

et al. 2004

“…The lack of blood supply into some organs can easily modify their ultrastructure and molecular distributions, presumably induced by anoxia and rapid loss of blood volume and pressure [17,18,26,27,[30][31][32]35]. In addition, such loss of blood supply, inevitable in experimental studies involving conventional chemical fixation or common QF of fresh tissue specimens, sometimes modifies the immunoreactivity of various functional molecules, due to the rapid ischemia, which induces diverse responses in living animal organs [8,29].…”

Section: Significance Of Cryotechniques For Immunohistochemistrymentioning

confidence: 99%

Advanced Application of the In Vivo Cryotechnique to Immunohistochemistry for Animal Organs

Terada

Acta Histochem. Cytochem.

2004

The quick-freezing method often used for physical fixation also contributed enormously to the advancement of morphology, but it could not provide enough information about the dynamic morphological changes in vivo in living animal organs. Therefore, we developed the in vivo cryotechnique in 1995, which could directly cryofix organs in vivo under anesthetized conditions without stopping blood circulation or producing effects of anoxia. We have already reported new findings about the in vivo ultrastructures of living animal organs with the cryotechnique followed by freeze-substitution or replica preparation. Recently, it has also been applied to other morphological analyses in vivo, including immunohistochemistry and FISH, for obtaining dynamically functioning structures of cells and tissues at a light microscopic level. In such experimental processes, the in vivo cryotechnique has been shown to have the added benefit of direct antigen-retrieval effects since it reduces several steps of retrieval treatments which are required in common paraffin-embedded samples prepared by the conventional fixation and dehydration. In conclusion, the in vivo cryotechnique allows us to investigate the functioning real morphology of living animals, which was technically difficult to be observed before, and perform dynamic immunohistochemistry of cells and tissues in various animal organs in vivo at ultimate time-resolution.

Shear‐Induced Aggregation of Mammalian Synovial Fluid Components under Boundary Lubrication Conditions

Banquy

Lee

Das

et al. 2014

Adv Funct Materials

The lubricating and structural properties of different mammalian synovial fluids in thin films undergoing shear between two mica surfaces are studied in detail using a surface force apparatus (SFA). A 10–13 nm thick film of synovial components (proteins, lipids, and polymers) adsorbs on the mica surfaces in less than an hour of incubation time, and induces a strong repulsion between the surfaces that prevents them from coming into contact. Upon shearing, the structure of the confined synovial fluid changes dramatically when sheared above a “critical” shear rate of about 2 s−1 (corresponding to approximately 40 nm s−1). Above this critical shear rate and up to at least 70 μm s−1, the proteins and biopolymers in the fluid gradually aggregate to form a homogenous gel layer on each mica surface. As shearing continues, the gel layer gradually breaks up into discrete/individual gel particles that can roll in the contact keeping the sheared surfaces far apart even under high compressive loads (pressure P ≈ 20 MPa). These particles eventually become elongated and finally behave as roller bearings. This mechanism is consistently observed for three mammalian synovial fluids and two types of surfaces suggesting that it actually occurs in articular joints and prostetic implants in vivo. The implications of these findings for joints and prosthetic implants structure and lubrication are discussed; in particular the formation and function of the lamina splendens.