Quantitative three-dimensional analysis of chondrocytic kinetic responses to short-term stapling of the rat proximal tibial growth plate.

Although it has been demonstrated clinically that controlled compression across a growth plate will slow the rate of endochondral ossification and thus can be used to correct angular limb deformities, the cellular-based mechanism by which altered growth is achieved is poorly understood. This study used short-term uniaxial stapling of the rat proximal tibial growth plate as an experimental system to study chondrocytic responses in the growth plate that account quantitatively for the decreased rate of growth. Growth plates were labeled with oxytetracycline to measure bone growth, and with bromodeoxyuridine to analyze proliferative cell kinetics. Multiple indicators of chondrocytic activity, measured by stereological parameters, were analyzed using growth rate as the primary dependent variable. The unique feature of this analysis was the creation of three-dimensional reconstructions that allowed analysis of data in all directions with distance from the staple. A significant observation was that for the entire operated limb after both 3 and 6 days, all chondrocytic kinetic parameters were affected, indicating that proliferative and hypertrophic responses both act to decrease growth rate in response to stapling. This contradicted our hypothesis that proliferative and hypertrophic responses could occur independently, and that small changes in rate would be attributed primarily to the former and large changes to the latter. The data from this study also demonstrate that volume regulation during hypertrophy can be affected by a primarily mechanical perturbation. Because changes in hypertrophic cell number and volume throughout the growth plate that occur by day 3 remain similar at day 6, the initial modulation of chondrocytic volume and shape may represent the limit of the response while maintaining a growth plate capable of continued growth.

Differential growth by growth plates as a function of multiple parameters of chondrocytic kinetics.

Differential elongation of growth plates is the process by which growth-plate chondrocytes translate the same sequence of gene regulation into the appropriate timing pattern for a given rate of elongation. While some of the parameters associated with differential growth are known, the purpose of this study was to test the hypothesis that eight independent variables are involved. We tested this hypothesis by considering four different growth plates in 28-day-old Long-Evans rats. Temporal parameters were provided by means of oxytetracycline and bromodeoxyuridine labeling techniques. Stereological parameters were measured with standard techniques. For all four growth plates, the calculated number of new chondrocytes produced per day approximated the number of chondrocytes lost per day at the chondro-osseous junction. This suggests that the proposed equations and associated variables represent a comprehensive set of variables defining differential growth. In absolute numbers, the proximal tibial growth plate produced about four times as many chondrocytes per day as the proximal radial growth plate (16,400 compared with 3,700). In the proximal tibia, 9% of growth is contributed by cellular division; 32%, by matrix synthesis throughout the growth plate; and 59%, by chondrocytic enlargement during hypertrophy. In the more slowly elongating growth plates, the relative contribution to elongation from cellular enlargement decreases from 59 to 44%, with a relative increase in contribution from matrix synthesis ranging from 32% in the proximal tibia 49% in the proximal radius. This study suggests that differential growth is best depicted as a complex interplay among cellular division, matrix synthesis, and cellular enlargement during hypertrophy. Differential growth is best explained by considering a set of eight independent variables, seven of which vary from growth plate to growth plate. Thus, this study confirms the importance of cellular hypertrophy during elongation and adds to our understanding of the importance of locally mediated regulatory systems controlling growth-plate activity.

Cell cycle analysis of proliferative zone chondrocytes in growth plates elongating at different rates.

Regulation of postnatal growth of long bones occurs in multiple levels of chondrocytic activity, including stem cell proliferation, proliferative zone cycling, and regulation of changes in chondrocytic shape during hypertrophy. The differentiation sequence of chondrocytes is the same in all growth plates, but rates of elongation at a single point in time and over a period of time differ widely among individual growth plates, which suggests that the rates of sequential gene activation and suppression in this phenotypic pattern can vary. The purpose of this study was to investigate, directly and in vivo, parameters of the cell cycle of proliferative chondrocytes in growth plates growing at widely different rates at a single point in time in order to analyze the relationship between cell cycle time, including the duration of each phase of the cell cycle (G1, S, G2, and M), and the rate of growth. The experimental design used repeated pulse labeling with bromodeoxyuridine and was analyzed using a regression model of time of pulse label with increasing labeling index. Total cell cycle time was calculated as the inverse of the slope of the relationship of the labeling index and the time between labels. The y intercept was the calculated labeling index at time zero. Multiple comparison contrasts were used to test for individual differences among four growth plates with growth rates ranging from approximately 50 to 400 microns per 24 hours from 28-day-old rats. The estimate of total cell cycle time for the proximal tibial growth plate was 30.9 hours. Cell cycle times for the other three growth plates were 34.0, 48.7, and 76.3 hours for the distal radius, distal tibia and proximal radius, respectively. Although the times for the proximal tibia and distal radius did not differ significantly, all other times were significantly different (p < 0.05). Almost all differences in total cell cycle time were attributable to significant differences in the length of the G1 phase. The S phase was estimated at 3.4-6.1 hours; the G2 phase, at 3.0 hours; and the M phase, at 0.5-0.6 hours. The current study suggests that regulation through cell cycle parameters, specifically in the G1 phase, may be involved in overall regulation of differential postnatal long bone growth. It has previously been established that increase and shape change of cellular volume during hypertrophy may be regulated at the level of individual growth plates and that both are significant in understanding differential growth of long bone at this level. By demonstrating that chondrocytes in the proliferating zone have different cell cycle times that are regulated primarily through differences in the duration of G1, this study suggests that, in addition to systemic controls of chondrocyte proliferation, local controls may modulate rates of proliferation of individual growth plates and thus may be another locally mediated regulator of differential growth.

Stereological and serial section analysis of chondrocytic enlargement in the proximal tibial growth plate of the rat.

BACKGROUND: It has been suggested that within the growth plate, the final volume and shape of hypertrophic chondrocytes are important variables in determining the rate of longitudinal bone growth. To better understand the organization and regulation of chondrocytic hypertrophy as related to longitudinal bone growth, the beginning and end, and the location and magnitude of chondrocytic volume and shape changes during the hypertrophic process were defined in the proximal tibial growth plate of 35-day-old rats. METHODS: In this study we used two different approaches, a stereological analysis of chondrocytes in unbiasedly defined, narrow growth plate strata, and a serial section reconstruction and measurement of individual cells. In both experiments chondrocytes were preserved using optimal chemical fixation. Proliferating chondrocytes were identified using bromodeoxyuridine labelling, and the rate of longitudinal bone growth was determined using oxytetracycline labelling. RESULTS: In both studies, immediately following cell division in the proliferative zone, chondrocytic volume gradually increased toward the mid-point of the growth plate. During this phase of about 30 hours, approximately 20% of the final cell volume was obtained. During the following 20 hours the remaining 80% was acquired. The estimated rate of cell volume increased changed from approximately 50 microns 3/hr during the first 30 hours to about 800 microns 3/hr during the last 20 hours. The increase in cell volume resulted in an increase in both the vertical and the horizontal chondrocytic diameters. Cell parameters did not change during the final five hours of the maturation process. CONCLUSIONS: In this study we demonstrated that chondrocytic enlargement starts immediately following cell division in the proliferative zone, and that chondrocytic enlargement consists of two morphologically distinguishable phases. The transition point between the first and the second phase of chondrocytic enlargement corresponded with the junction between the proliferative zone and the maturation zone.

Hypertrophic chondrocyte volume and growth rates in avian growth plates.

In growing mammals there is a positive linear relationship between the mean hypertrophic chondrocyte volume and the rate of bone elongation. This suggests that the control of chondrocytic volume in the growth plate, is a major determinant in controlling bone elongation in mammals. In the present study the existence of such a relationship was tested for in birds. A scheme of fluorochrome labelling was devised to enable direct measurement of bone elongation per unit time. Four weight-bearing growth plates from two-week-old mallard ducklings and the corresponding four growth plates from two-week-old leghorn chicks were studied. Growth plate cartilage was fixed in the presence of ruthenium hexamine trichloride and embedded in Epon araldite. Estimates of mean cell volume, v(chondr), and mean cubic intercept (l3) were calculated by applying the stereological relationship: v(chondr) = (pi/3) x (l3). Regression analysis revealed a positive linear relationship between the two parameters, rate of bone elongation and mean hypertrophic cell volume in both species (squared correlation statistics: 65 per cent for mallards, 54 per cent for leghorns). There was a wide range in rates of bone elongation among growth plates studied (318 to 1418 microns 24 h-1 for mallards, 77 to 445 microns 24 h-1 for leghorns) and compared to mammals (such as rabbits, rats, swine and dogs), a small range in mean cell volume (2709 to 4786 micron3 for mallards, 3663 to 5719 micron3 for leghorns).(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence of the growth plate and the growth of long bones in juvenile dinosaurs.

Histological and ultrastructural evaluation of the ends of long bones of juvenile dinosaurs from the Upper Cretaceous Two Medicine Formation of Montana revealed the preservation of growth plates. Growth plates are discs of cartilage present near the ends of growing long bones that generate bone elongation. Comparison of the fossils with modern taxa demonstrated homology of the growth plate in birds and dinosaurs. The presence of an avian-type growth plate in dinosaurs adds a shared derived anatomical character corroborating inclusion of birds within the Dinosauria. Additionally, possession of a growth plate, which in birds is capable of producing rapid determinate long bone growth, implies that an avian developmental pattern may have been present in these dinosaurs.

Determination of proliferative characteristics of growth plate chondrocytes by labeling with bromodeoxyuridine.

Postnatal bone growth occurs by the process of endochondral ossification in cartilaginous growth plates at the ends of long bones. The rate and extent of long bone growth is determined by a combination of chondrocytic proliferation, matrix production, and increase in chondrocytic height in the direction of growth during cellular enlargement. In this study, single pulse and/or repeated pulse labeling with the thymidine analog bromodeoxyuridine (BrdU) was used to study the role of cellular proliferation in controlling long bone growth. Variables studied included progression of the label over time following a pulse, and patterns and progression of the label over time following repeated pulse labeling for 24 and 48 hours. Examination was made of the proliferative characteristics of chondrocytes, the spatial pattern of cellular proliferation, and cell cycle kinetics. With respect to the spatial pattern of proliferative chondrocytes, results suggest that chondrocytes within a column are more synchronized with each other than are chondrocytes in different columns. This is consistent with the concept that each column represents a clonal expansion of a stem cell, which may proceed independently from adjacent columns. Despite this apparent heterogeneity, all chondrocytes in the proliferative zone complete at least one cell cycle in 24-28 hours. This estimate of the cell cycle time is significantly shorter than previous estimates of cell cycle times in similar growth plates. Our results also suggest that chondrocytes entering the cell cycle in the proximal part of the growth plate spend an average of 4 days in the proliferative cell zone, representing approximately four cellular divisions. After leaving the cell cycle, an additional 48 hours is required for the label to reach the terminal chondrocyte, which represents the time required to complete hypertrophy. These data are important when considering hypotheses concerning both the role of controls on proliferation in the determination of overall rate of long bone growth, as well as the interplay between proliferation and hypertrophy in regulating the overall amount of growth achieved by a given growth plate.

Ocular-chondrodysplasia in labrador retriever dogs: a morphometric and electron microscopical analysis.

Ocular-chondrodysplasia in Labrador Retriever dogs is characterized by short-limbed dwarfism and ocular abnormalities. The purposes of the present study were to develop morphological criteria to define the matrix and/or chondrocytic abnormalities associated with this chondrodysplasia, and to test the hypothesis that ineffective matrix-directed cellular swelling was associated with the decreased longitudinal bone growth in these animals. The proximal and distal radial growth plates were collected from four affected animals of the same litter. Stereological techniques were used to analyze both cellular shapes and cellular volume changes in the hypertrophic zone. The pathological changes seen in these growth plates varied between animals and included disorganization of cellular columns with abnormal extent of calcification. Chondrocytes of all zones contained two types of abnormal cellular inclusions classified as light and dark, based on the intensity of eosinophilic staining. Both types of inclusions contained material that resembled the surrounding extracellular matrix, varying only in the apparent hydration of the contents. It could be demonstrated that light inclusions were located in the peripheral cytoplasm and connected to the extracellular matrix through narrow channels. By contrast, dark inclusions were membrane bound and perinuclear. Chondrocytes with multiple, large inclusions appeared to be undergoing degenerative changes. Although the final volume achieved by hypertrophic chondrocytes was consistent with that of normal growth plates, there was a high level of variability of chondrocytic shape and evidence of premature cellular condensation in the maturation zone. The severity of the dwarfism correlated both with the extent of chondrocytic changes and the severity of the ocular lesions.(ABSTRACT TRUNCATED AT 250 WORDS)

Cellular basis of decreased rate of longitudinal growth of bone in pseudoachondroplastic dogs.

Regulation of growth of long bones occurs in cartilage growth plates, where proliferation of chondrocytes, matrix synthesis, and an increase in vertical height in the direction of growth all contribute to the final length of a bone. In this study, we tested the hypothesis that an increase in chondrocytic vertical height is a major variable that accounts for the decreased rate of growth of long bones in Scottish deerhound dogs that had pseudoachondroplasia. The diagnosis of pseudoachondroplasia is based, primarily, on the demonstration of alternating electron-dense and electron-lucent lamellae with a periodicity of 100 to 150 nanometers in dilated rough endoplasmic reticulum. These ultrastructural changes are similar to those seen in humans who have pseudoachondroplasia. In Scottish deerhounds that have the disease, growth of bone is approximately 65 per cent of that in normal animals. There were striking differences in the diameters of proliferating and hypertrophic chondrocytes in pseudoachondroplastic animals compared with normal animals. Specifically, the horizontal diameter of proliferating chondrocytes was 22.7 micrometers in normal animals and 11.3 micrometers in pseudoachondroplastic animals. The vertical diameter of proliferating chondrocytes was 4.8 and 7.6 micrometers in normal and pseudoachondroplastic animals. In the distal 100 micrometers of the hypertrophic zone, the mean horizontal diameter of hypertrophic chondrocytes was 29.6 and 19.1 micrometers and the mean vertical diameter was 22.8 and 18.6 micrometers in normal and pseudoachondroplastic animals. All these differences were statistically significant. The changes in vertical height resulted in a significant difference in the incremental difference in vertical height between chondrocytes from the proliferative and hypertrophic zones in normal animals (18.0 micrometers per chondrocyte) and pseudoachondroplastic animals (11.0 micrometers per chondrocyte). Each chondrocyte in the abnormal plates achieved only 61 per cent of the incremental difference of chondrocytes in normal plates. The mean cellular volume of chondrocytes in the hypertrophic zone was 13,050 cubic micrometers in the normal animals and 10,740 cubic micrometers in the pseudoachondroplastic animals. This difference was not statistically significant. These results are discussed in relation to current theories of the role of the shape and change in volume of chondrocytes in the regulation of longitudinal growth of bone.(ABSTRACT TRUNCATED AT 400 WORDS)

Linear relationship between the volume of hypertrophic chondrocytes and the rate of longitudinal bone growth in growth plates.

In this study, we tested the hypothesis that hypertrophic cell volume varies directly with the rate of longitudinal bone growth. The volume of hypertrophic chondrocytes (using stereological techniques) and longitudinal bone growth per 24 h (using oxytetracycline labeling techniques) were measured in the proximal and distal radial growth plates and the proximal and distal tibial growth plates of 21- and 35-day-old hooded rats and 21- and 35-day-old Yucatan pigs. We demonstrated a high coefficient of correlation (rats 0.98, pigs 0.83) between the final volume of hypertrophic chondrocytes and the rate of longitudinal bone growth over a wide range of growth rates and volumes of hypertrophic chondrocytes. In addition, we demonstrated a positive linear relationship between the rate of longitudinal bone growth and the final volume of hypertrophic chondrocytes. The slope of the regression line was different for rats than for pigs. The relationship was independent of the location of the growth plate in the animal and the age of the animal. The data suggest that mechanisms regulating volume changes in hypertrophic chondrocytes may exist and that chondrocytic volume increase is a major determinant of the rate of longitudinal bone growth. However, the relative contribution of cellular hypertrophy to longitudinal bone growth may be different in rats than in pigs.

Visualization of living terminal hypertrophic chondrocytes of growth plate cartilage in situ by differential interference contrast microscopy and time-lapse cinematography.

The functional unit within the growth plate consists of a column of chondrocytes that passes through a sequence of phases including proliferation, hypertrophy, and death. It is important to our understanding of the biology of the growth plate to determine if distal hypertrophic cells are viable, highly differentiated cells with the potential of actively controlling terminal events of endochondral ossification prior to their death at the chondro-osseous junction. This study for the first time reports on the visualization of living hypertrophic chondrocytes in situ, including the terminal hypertrophic chondrocyte. Chondrocytes in growth plate explants are visualized using rectified differential interference contrast microscopy. We record and measure, using time-lapse cinematography, the rate of movement of subcellular organelles at the limit of resolution of this light microscopy system. Control experiments to assess viability of hypertrophic chondrocytes include coincubating organ cultures with the intravital dye fluorescein diacetate to assess the integrity of the plasma membrane and cytoplasmic esterases. In this system, all hypertrophic chondrocytes, including the very terminal chondrocyte, exist as rounded, fully hydrated cells. By the criteria of intravital dye staining and organelle movement, distal hypertrophic chondrocytes are identical to chondrocytes in the proliferative and early hypertrophic cell zones.

Condensation of hypertrophic chondrocytes at the chondro-osseous junction of growth plate cartilage in Yucatan swine: relationship to long bone growth.

Chondrocytes of the cartilaginous growth plate are found in a spatial gradient of cellular differentiation beginning with cellular proliferation and ending with cellular hypertrophy. Although it is recognized that both proliferation and hypertrophy contribute significantly to overall bone growth, mechanisms acting on the chondrocyte to control the timing, the rate, and the extent of hypertrophy are poorly understood. Similarly, mechanisms acting on the terminal chondrocyte to cause its death at the chondro-osseous junction have not been investigated. In this study we examine the condensation of terminal hypertrophic chondrocytes in proximal and distal radial growth plates of Yucatan swine at 4 weeks of age. The animals were raised in a controlled environment where activity and feeding patterns were synchronized to a given time in the light/dark cycle. We analyzed cellular condensation both as a function of circadian rhythms in a 24-hr time period, and as a function of overall rate of growth. The data suggest that the magnitude of circadian influences on long bone growth is significantly damped at the level of the hypertrophic chondrocyte compared to that seen by previous investigators studying circadian influences on chondrocytic proliferation. Secondly, the condensation of hypertrophic chondrocytes at the chondro-osseous junction varies inversely with rate of growth in length of the bone. At any time period, a higher percentage of terminal chondrocytes in the condensed form was found in the slower-growing of the two growth plates. We relate these findings to current hypotheses concerning controls of chondrocytic hypertrophy and possible controls over the timing of hypertrophic cell death.

Cellular turnover at the chondro-osseous junction of growth plate cartilage: analysis by serial sections at the light microscopical level.

In the distal hypertrophic cell zone of growth plate cartilage, the penetration of metaphyseal vascular endothelial cells is into the noncalcified territorial and pericellular matrices. Cellular mechanisms that promote metaphyseal vascularization are understood poorly, partly because no study has addressed the question of the time sequence of cellular interactions at the chondro-osseous junction. The purpose of the present study is to make predictions about the relative and the real time duration of cellular events during vascular invasion, including an analysis of the time sequence of death of the terminal hypertrophic chondrocyte. The data from serial section analysis at the light microscopical level of tetracycline-labeled growth plates indicate that death of the terminal hypertrophic chondrocyte occurs in discrete morphological stages characterized by rapid cellular condensation followed, within minutes, by endothelial cell penetration into the vacated lacuna. Cellular condensation lasts approximately 45 min or 18% of the time a cell spends as a terminal chondrocyte. The data also demonstrate that chondrocytic death occurs prior to invasion by vascular endothelial cells and that the chondrocytic lacuna remains empty for as long as 15 min before an endothelial cell or blood vascular cell fills the space.

Lectin-binding histochemistry of intracellular and extracellular glycoconjugates of the reserve cell zone of growth plate cartilage.

The distribution of intracellular and extracellular lectin-binding glycoconjugates of the reserve cell zone of growth plate cartilage was studied in the distal radial growth plate of 4-week-old Yucatan swine using a postembedment method on Epon-embedded sections. Direct comparisons were made to articular, tracheal, and auricular cartilages not involved in endochondral ossification. All patterns of lectin binding that in the growth plate were restricted to the reserve cell zone were also patterns characteristic of tracheal, articular, and auricular cartilages. These included: (a) pericellular binding with peanut agglutinin (PNA) without prior digestion with neuraminidase; (b) pericellular binding with wheat germ agglutinin (WGA) at 24 h; (c) intracellular cytoplasmic binding to concanavalin A (CON-A), Lens culinaris agglutinin (LCA), and Lotus tetragonobolus agglutinin (LTA) after periodic acid oxidation; and (d) a lack of pericellular binding with CON-A and ricin agglutinin 1 (RCA-1) after periodic acid oxidation. We conclude that reserve zone chondrocytes lack specific phenotypic markers as defined by lectin-binding affinity that are found in the cellular zones of the growth plate that undergo calcification and vascularization. The reserve zone has identical lectin-binding affinities to the three structural cartilages used as controls. One interpretation of these results is that the reserve zone may not be involved directly in endochondral ossification, but may have a structural function in growth plate cartilage.

Density and distribution of canine conjunctival goblet cells.

Conjunctival goblet cells (GCs) were quantitated to establish baseline values for density and distribution of these cells in healthy canine eyes. From each of 18 sites, tissue was collected, sectioned at 2 micron, and stained with periodic acid Schiff stain. Within each sampling site, 500 epithelial cells (GCs, squamous, polygonal, and basal epithelial cells) were counted and the ratio of GCs to total epithelial cells was computed as an index of goblet cell density or goblet cell index (GCI). A heterogenous distribution of canine conjunctival goblets cells was demonstrated. Lower nasal fornix (LNf) and adjacent sites, lower middle fornix (LMf) and lower nasal tarsal (LNt), had the highest mean densities of goblet cells. In contrast, GCs were essentially absent from the upper and lower bulbar areas. Remaining sites had intermediate GCIs. Sex differences in GCIs were noted for LNf and LNt sites. Mean tear film breakup times (BUTs) were determined, and, for normal beagle dogs, were 19.38 (+/- 4.80 secs) OS and 19.96 (+/- 5.01 secs) OD. The similarities between canine and human conjunctival goblet cell distributions support the use of the dog for studying the conjunctival mucous system.

Morphologic stages of the terminal hypertrophic chondrocyte of growth plate cartilage.

Recent biochemical and morphologic evidence supports the concept that hypertrophic chondrocytes of growth plate cartilage are fully viable cells that play a major functional role in controlling endochondral ossification. However, events associated with chondrocyte death remain unknown. In this study we assess the viability of terminal hypertrophic chondrocytes in situ in an organ culture system viewed simultaneously with rectified Nomarski interference contrast optics and with vital staining under fluorescence optics. Second, we use two methods of optimal chemical fixation at the ultrastructural level to define morphologically distinct stages of the terminal hypertrophic chondrocyte, which we interpret as the stages preceding chondrocyte death. An analysis of serial sections at the light microscope level showed that terminal chondrocytes were found, with different probabilities, in three morphologically distinguishable stages. Seventy-five percent of all profiles were fully hydrated cells with an intact plasma membrane making direct contact with the pericellular matrix, a morphology identical to that of living terminal chondrocytes viewed in Nomarski optics. Approximately 1% of terminal chondrocytes, while still in a fully hydrated state, consistently made a direct asymmetrical contact of the plasma membrane with the last transverse septum. In 24% of the profiles, terminal chondrocytes were found as condensed cells that retained their attachment to the last transverse septum. The stages were not characteristic of chondrocytes positioned more proximally in the growth plate. We hypothesize that a condensed morphology eventually characterizes each hypertrophic chondrocyte, and we relate these observations to current hypotheses concerning the mechanism of death of hypertrophic chondrocytes.

Assessment of neutrophil function in dogs with primary ciliary dyskinesia.

Compared with neutrophils from healthy dogs, neutrophils from 2 dogs with primary ciliary dyskinesia had increased distance of random migration, but fewer of the neutrophils migrated. The affected dogs had an increase in the numbers of Staphylococcus aureus phagocytized. Lymphocyte blastogenesis in the affected dogs in response to standard mitogens was considered to be normal.

Arterial and venous supply to the bovine jejunum and proximal part of the ileum.

The blood vasculature of the bovine jejunum and proximal part of the ileum was studied in 20 mature dairy cows at slaughter. The cranial mesenteric artery and vein supplied the jejunum and ileum, and their major branches were present in all specimens and supplied similar regions of the intestinal tract. Proximal branches of the cranial mesenteric artery were pancreatic arteries, caudal pancreaticoduodenal artery, middle colic artery, and ileocolic artery. A large collateral branch arose from the proximal segment of the cranial mesenteric artery, anastomosing with the continuation of the cranial mesenteric artery distally along the jejunum. Jejunal arteries arose from the continuation of the cranial mesenteric artery, forming a series of anastomosing arches. Straight vessels arising from these arches did not branch or anastomose before entering the serosal layer of the intestine. The proximal part of the ileum was supplied by branches from the continuation of the cranial mesenteric artery; these branches anastomosed with the mesenteric ileal (ilei mesenterialis) artery, a branch of the ileocolic artery. The venous supply paralleled the arterial supply in all specimens.

Immotile cilia syndrome in an aged dog.

An 11-year-old Dalmatian was examined and treated for bilateral nasal discharge and cough of 6 months' duration. Response to medical treatment and surgical intervention was unsatisfactory. Histologic examination of lung tissue revealed chronic severe catarrhal bronchitis and bronchiolitis with bronchiectasis. Histologic findings and barium sulfate bronchography indicated abnormal mucociliary clearance in the respiratory tract. Electron microscopy revealed abnormalities or deletions of outer and/or inner dynein arms in 26% of the ciliary profiles from the affected dog. Similar abnormalities were not found in 500 ciliary profiles from age- and gender-matched control dogs.

Primary ciliary dyskinesia in the dog.

Electron microscopy was used to diagnose primary ciliary dyskinesia in a litter of English pointer dogs and in a golden retriever dog. A technique of membrane solubilization, fixation, and negative staining with glutaraldehyde tannic acid identified abnormally constructed central and B microtubules in respiratory cilia from dogs with primary ciliary dyskinesia. Shortened outer dynein arms commonly associated with primary ciliary dyskinesia actually represents the absence of a specific subset of the three most peripheral components of the whole outer dynein arm structure.