似鲇高原鳅皮肤与鳍的组织学观察

采用石蜡切片技术及H.E和AB-PAS染色方法,对似鲇高原鳅(Triplophysa siluroides)头部、腹部、背部、侧线部和尾部皮肤结构及胸鳍、腹鳍、背鳍、臀鳍和尾鳍的组织结构进行观察。各部位皮肤均由表皮和真皮构成,真皮包括疏松层和致密层,不同部位皮肤厚度不同。表皮层腹部最厚,为(84.62±10.82)μm,侧线部最薄,为(14.97±3.95)μm,各部位表皮厚度差异显著。表皮层分布着黏液细胞、棒状细胞及味蕾。疏松层头部最厚,为(282.71±70.56)μm,尾部最薄,为(29.07±4.88)μm,该层分布有黑色素细胞、空泡状细胞和颗粒腺,而黏液腺分布于致密层。各部位的鳍均由表皮层、胶原纤维层、胶原下层及鳍条构成,表皮层与皮肤表皮层组成相似,鳍条是矿化的结缔组织。     

松江鲈鱼皮肤的显微和亚显微结构

采用光学显微镜、扫描电镜和透射电镜,对松江鲈鱼(Trachidermus fasciatus)成体皮肤的显微和亚显微结构进行了观察。结果表明,松江鲈鱼体表不同部位皮肤的厚薄不一,但基本结构相似。皮肤由表皮和真皮层构成。松江鲈鱼的皮肤裸露无鳞,表皮层较薄,由约4～8层细胞构成,主要由复层上皮细胞和黏液细胞及基底细胞组成。表层细胞呈扁平、多边形,细胞之间主要靠桥粒紧密连接,连接处形成增厚的边缘嵴状突起。表皮细胞游离面向内凹陷,表面形成指纹状微嵴。黏液细胞呈圆形或卵圆形,散布在上皮细胞之间。黏液细胞内的黏原颗粒具有椭圆颗粒状、均匀致密的块状和疏松丝状3种不同形态。真皮通过基膜与表皮相连,由稀疏层和致密层构成。真皮结缔组织在腹部较厚而在其他部位较薄。表皮与真皮连接处有色素层,头部、背部、尾柄和体侧皮肤色素细胞分布多,色素层明显,而腹部和颏部皮肤缺少色素。松江鲈鱼黄河群体真皮层中有角质棘状突起,而滦河群体则无。头部、体侧和尾柄处皮肤上还分布有侧线孔和表面神经丘等感觉器官。     

The skin of primates. XXXVII. The skin of the pig-tail macaque (Macaca nemestrina)

The skin of the pig-tail macaque is basically similar to that of the rhesus monkey and the stump-tail macaque. The epidermis is thin and contains occasional basal melanocytes. The dermis, rich in elastic fibers, is practically free of pigment-containing cells. The upper dermis is highly vascular in the perianal region and sex skin. Cholinesterase-reactive nerve endings are plentiful beneath the friction surfaces of the pes and manus, mucous membranes, and junction of the hairy gluteus and glabrous ischial callosity. Hederiform-like endings are present in the eyelid, pinna, and frontal scalp. Apocrine and eccrine sweat glands occur throughout the hairy skin in a 2–3: 1 ratio. Both types are invested by nerves reactive for acetyl- and butyrylcholinesterase.     

Avian scale development. IX. Scale formation by scaleless (sc/sc) epidermis under the influence of normal scale dermis

Unlike normal scutate scales whose outer and inner epidermal surfaces elaborate β (β-keratins) and α (α-keratins) strata, respectively, the scaleless mutant's anterior metatarsal epidermis remains flat and elaborates only an α stratum. Reciprocal epidermal-dermal recombinations of presumptive scale tissues from normal and mutant embryos have demonstrated that the scaleless defect is expressed only by the epidermis. In fact, the scaleless anterior metatarsal epidermis is unable to undergo placode formation. More recently, it has been determined that the absence of epidermal placode morphogenesis into a definitive scale ridge actually results in the establishment of a scale dermis which is incapable of inducing the outer and inner epidermal surfaces of scutate scales. Can the initial genetic defect in the scaleless anterior metatarsal epidermis be overcome by replacing the defective dermis with a normal scutate scale dermis, i.e., a dermis with scale ridges already present? Or, are the genes involved in the production of a β stratum regulated by events directly associated with morphogenesis of the epidermal placode? In the present study, we combined scaleless anterior metatarsal epidermis (stages 36 to 42) with normal scutate scale dermis (stage 40, 41, or 42) old enough to have acquired its scutate scale-inducing ability. After 7 days of growth as chorioallantoic membrane grafts, we observed grossly and histologically, typical scutate scales in these recombinant grafts. Electron microscopic and electrophoretic analyses have verified that these recombinant scales are true scutate scales. The scaleless mutation, known to be expressed initially by the anterior metatarsal epidermis, can be overcome by exposing this epidermis to appropriate inductive cues, i.e., cues that direct the differentiation of the outer and inner epidermal surfaces of the scutate scales and the production of specific structural proteins. We have determined that the time between stages 38 and 39 is the critical period during which the normal scutate scale dermis acquires these inductive abilities.     

Structure of the skin of Agonus cataphractus (Teleostei)

The skin of the scuted teleost Agonus cataphractus has been investigated by histochemical methods, SEM and TEM. The anterior dorsal skin bears tubercles of epidermis overlying tiny ossifications (scutelets) superficial to the main scutes. The epidermis secretes a cuticular layer containing acidic non-sulphated glycoproteins, but there are no mucous goblet cells in the external skin. Non-mucous sacciform cells of two types are present in the epidermis, also numerous chloride cells. Scanning electron microscopy reveals variation in the microridge pattern of superficial epithelial cells, thought to relate to arrival at the surface and secretion of the cuticle. The major scutes overlap anteriorly, contrary to the normal arrangement of scales, indicating that they are secondary ossifications. The type of mineralization is similar to that of acellular bone. The scutes are set directly in the collagen of the dermis. They have a girdered structure with radial and cross bars, inserting on both faces of a thin plate. The interstices are occupied by unmineralized collagen, and extrinsic collagen bundles impinge on the bone. Non-mineralized parts of the dermis contain tracts of microfibrils in addition to collagen; these are best developed in the flexible gular skin and in the barbels and are interpreted as elastic tissue, although an amorphous component was not seen. The barbels have a core of connective tissue without a cartilaginous skeleton and bear taste buds and numerous chloride cells.     

Adaptations for cryopelagic life in the antarctic notothenioid fish Pagothenia borchgrevinki

Summary The cryopelagic circumantarctic notothenioid fish Pagothenia borchgrevinki lives near the undersurface of the sea ice in McMurdo Sound, Antarctica. When compared to closely related benthic species (especially Trematomus bernacchii), Pagothenia exhibited substantial morphological differences in a variety of organ systems. The values of the fineness ratio and the indices of trunk shape and flatness suggested streamlining and drag reduction, adaptations to life in the water column. Pagothenia also lacked substrate contact adaptations in the pelvic and anal fins. Silvery reflective layers (strata argentea) beneath the skin and in the iris and choroid of the eye provided camouflage when Pagothenia were viewed against a background of platelet ice. The retina had many cones indicating the eye was adapted to both diurnal and nocturnal vision. During the austral spring Pagothenia fed exclusively on nektonic organisms near the ice-water interface. Dietary diversity was low; copepods and amphipods were the most frequently occurring and amphipods were the most frequently occurring taxa. In conclusion, Pagothenia appear specialized for life in the water column.     

Temporal variations in the skin of Atlantic salmon Salmo solar L.

The thickness of the skin of Atlantic salmon increases throughout the first two years of life. This increase involves, principally, an increase in the connective tissue of the dermis, and occurs independently of sexual maturity. The concentration of mucous cells in the epidermis changes seasonally, being least during the winter period. No sexual dimorphism is observed in these features among sexually immature fish. The epidermis of precociously mature male parr is thicker and contains more mucous cells than that of sexually immature individuals.     

The initial expression and patterned appearance of tenascin in scutate scales is absent from the dermis of the scaleless (sc/sc) chicken.

Morphogenesis of the anterior metatarsal skin (scutate scale region), from 9.5 to 12 days of development, results in the formation of orderly patterned scale ridges. It is after the initial formation of the Definitive Scale Ridge that the characteristic outer and inner epidermal surfaces differentiate. The hard, plate-like beta stratum, with its unique beta keratins, characterizes the epidermis of the outer surface, while the epidermis of the inner surface elaborates an alpha stratum. The anterior metatarsal region of the scaleless mutant does not undergo scale morphogenesis. Therefore, scale ridges do not form nor do the outer and inner epidermal surfaces with their characteristic beta and alpha strata. We have found that the extracellular matrix molecule, tenascin, first appears in the scutate scale dermis at 12 days of development when the scale ridge is established. Tenascin is found in the dermis only under the scale ridge and is not associated with the dermal-epidermal junction. Tenascin is not found in scaleless anterior metatarsal dermis at this time. As outgrowth of the Definitive Scale Ridge takes place, tenascin distribution correlates closely with the formation of the outer epidermal surface of each scale ridge. By 16 days of development tenascin is also found in close association with the dermal-epidermal junction. Tenascin does not appear in scaleless anterior metatarsal dermis until 16 days of development and then it is randomly and sparsely distributed at the dermal-epidermal junction. Tenascin's initial appearance and pattern of distribution in the scutate scale dermis and its abnormal expression in the scaleless dermis suggest that morphogenesis plays a significant role in regulation of its expression.     

Ultrastructural and histochemical study on gills and skin of the Senegal sole, Solea senegalensis

This study was undertaken to identify the normal ultrastructural features of gills and skin of the Senegal sole, Solea senegalensis, for a comparative measure to morphological alterations caused by environmental stressors such as reduced water quality and diseases. In the Senegal sole skin, four morphologically distinct layers were identified: cuticle, epidermis, dermis and hypodermis. The epidermis was composed of stratified epithelium containing three cellular layers: the outermost or mucosa layer, the middle or fusiform layer and the stratum germinativum or the basal layer. In the mucosa, two mucous cell types were differentiated: type A cells containing several round vesicles of different electron density and type B cells containing mucosomes of uniform electron density. Senegal sole have five pairs of gill arches, each containing two rows of well‐developed and compactly organized primary filaments and secondary lamellae. Fingerprint‐like microridges were observed on the surface of epithelial cells. The branchial lamellae epithelium consisted of different cell types: pavement, mucous and chloride. Between the chloride cells and the larger pavement cells, accessory cells were observed. Complexes of tight junctions and desmosomes were frequently observed between adjacent chloride and epithelial cells. Neutral mucosubstances and/or glycoconjugates were observed in the epidermis, dermis and hypodermis of S. senegalensis skin. Proteins rich in different amino acids, such as arginine and cysteine, reacted negatively or weakly positive in the epidermis, dermis and hypodermis. In gills, some mucous cells responded weakly positive to periodic acid‐Schiff (PAS) reaction but were strongly stained with Alcian Blue at pH 0.5, 1 and 2.5. When Alcian Blue pH 2.5–PAS reaction was performed, most mucous cells were stained blue (carboxylated mucins) and some mucocytes stained purple, indicating a combination of neutral and acid mucins. Proteins rich in cysteine‐bound sulphydryl (‐SH‐) and cystine disulphide (‐S‐S‐) groups were strongly detected in branchial and epidermal mucous cells, whereas lysine, tyrosine and arginine containing proteins showed very weak staining in both epidermal and branchial mucous cells. Protein reactions were strongly positive in the pillar cells, except for those rich in tryptophan, whereas the branchial cartilaginous tissue did not show an important reaction. The performed lipid reactions were negative in goblet and chloride cells. It is concluded from this study that ultrastructural and cytohistochemical features of the Senegal sole skin and gills may serve as control structures in both natural and aquaculture systems to monitor or detect environmental stress responses at the histological level.     

Regional specificity of anuran larval skin during metamorphosis: dermal specificity in development and histolysis of recombined skin grafts

Summary Skins from back and tail were dissected from tadpoles of Rana japonica prior to resorption of the tail and separated into epidermis and dermis by treatment with neutral protease. Homotypically and heterotypically recombined skins were constructed from the separated epidermis and dermis and transplanted into the tail of the original tadpole. Skin grafts using dermis from tail region degenerated simultaneously with resorption of the tail. However, skin grafts containing dermis from back region survived on the posterior part of the juvenile frog beyond metamorphosis. Furthermore, all epidermis underlaid with dermis from back region formed secretory glands and became flattened epithelia characteristic of adult back skin, regardless of region from which the epidermis came. Even when epidermis isolated from tail skin was cultured inside a back skin graft, the tail epidermis survived forming an epithelial cyst and developed secretory glands. These results suggest that regional specificities of anuran larval skin, i.e., development of back skin and even histolysis of tail skin, are determined by regionally specific dermis. The results also suggest that some of epidermal cells of tail skin are able to differentiate into epithelial cells similar to back skin of the adult under the influence of back dermis.     

Functional organization of the skin of the ‘Green-puffer fish’Tetraodon fluviatilis (Ham.-Buch.) (Tetraodontidae,Pisces)

Summary The present study concerns the functional organization of the skin ofTetraodon fluviatilis. The epidermis consists of five different types of cells — the flask-shaped mucous cells, the eosinophilic granular cells, the sacciform granulated cells, the vesicle containing granulated cells, and the polygonal cells. A thin noncellular layer, the cuticle found on the surface of the skin, is probably secreted from the polygonal cells in the outermost layer of the epidermis. A,well-defined lymphatic plexus exists between the cells of the basal layer.Numerous triradiate calcareous spines are embedded within elastic connective tissue pockets in the thick dermis. These pockets are filled with an amorphous, acellular, PAS positive material, and are richly supplied with fine blood capillaries. A histomorphologic basis for the erection of the spines and various structural modifications in the skin facilitating its enormous stretching under inflated conditions of the fish are discussed.Abbreviations Used BCA blood capillary - BM basement membrane - BC basal cell - BL basal layer - CFB collagen fiber bundle - CTB connective tissue band - DER dermis - EGC eosinophilic granular cell - EPD epidermis - FB fibroblasts - FC fat cell - L lymphocyte - LS lymphatic space - MC mucous cell - ML middle layer - MUS muscle - MYS myocommata - NV nerve - OL outermost layer - PCB black pigment cell - PCY yellow pigment cell - PEC polygonal epidermal cell - SCT subcutis - SGC sacciform granulated cell - SP spine - STC stratum compactum - STL stratum laxum - VGC vesicle containing granulated cell - VS vertical strand This investigation was supported by a research grant No. 38(131)/72-GAU-II from the Council of Scientific and Industrial Research and a financial assistance grant for teachers No. F. 6(4626) 72-(SF-1), from the University Grants Commission, Government of India, New Delhi.     

Epidermal-dermal tissue interactions between mutant and normal embryonic back skin: site of mutant gene activity determining abnormal feathering is in the epidermis.

The site of the scaleless gene's activity in the development of abnormal feathers was determined by reciprocally recombining epidermis and dermis between normal and scaleless chick embryos and culturing the recombinants for seven days on the chorioallantoic membrane. When recombined with a common dermal source, feather development is enhanced by scaleless high line as compared to scaleless low line epidermis. Against a common responding tissue, 7-day normal back epidermis, significant differences were not found in feather inducing ability between normal, scaleless high line and scaleless low line dermis. It was concluded that, in relation to abnormal feathering, these tissue interactions reveal that the site of the scaleless gene's activity is the epidermis. A model of tissue interaction in the development of normal and abnormal feathers is presented. According to the model, the focus of the scaleless mutation and the genes accumulated by selection for high or low feather numbers is the epidermis, the effect being that the reactivity of the epidermis to dermal stimuli is altered. Subsequently, the epidermis controls the morphogenetic organization of the dermis. The scaleless dermis is presumed to contain normal positional information for the determination of feather structure and pattern.     

Structure of the integument of a fresh-water teleost,Bagarius bagarius (Ham.) (Sisoridae,pisces)

The skin of Bagarius bagarius (Ham.) is devoid of scales but is rough due to the presence of numerous pentagonal epidermal elevations, which are separated by deep furrows at regular intervals. These elevated pentagonal regions of the epidermis are covered by dead cornified cells in the form of caps. As the old cap goes off a new one is formed by the death of the underlying epidermal cells. The middle layer of the epidermis is mainly composed of well defined polygonal cells. Their cytoplasm is granular in nature and give reactions for protein bound sulphydryl groups. The stratum germinativum is composed of two types of basal cells, the columnar cells and the spherical cells. The flask shaped mucous glands are restricted to the epidermal furrows and secrete either neutral or acidic mucopolysaccharides. Certain large specialysed granular cells are found in the epidermis which are grouped around the taste buds. These specialysed cells may be the photocytes. Two layers of the dermis can be distinguished—the relatively thin stratum laxum and the thick stratum compactum. Dermal papillae mainly support the taste buds. The pigment cells are arranged in two layers in the dermis. The subcutis is composed of loose connective tissues, richly infiltrated with the fat cells, nerves and blood capillaries.     

The integument of the paddlefish,Polyodon spathula

The integument of the paddlefish (Polyodon spathula) is unusual as a relatively small amount of mucus is produced by epithelial cells that are not modified into regular mucous gland cells. A thick compact epidermis and dermis compensate for the slight amount of mucus secreted. Paddlefish have a variety of scales formed of concentric bony lamellae containing osteocytes. There are five kinds of scales: dorsal and ventral fulcra on the caudal fin, rhomboidal scales on the caudal lobe, horny denticles over the pectoral girdle, calcareous denticles on the trunk, and anchor-shaped plates on the rostrum. Except for the fulcra, the scales are undoubtedly vestigial. The numerous surface pits on the rostrum, head, operculum, and throat are epithelial invaginations which are not connected to lateral line canals. No nerves lead to the pits. The spherical to cuboidal and often ciliated cells at the base of the pits are considered to be aplasic cells of unformed neuromasts.     

Epidermal-dermal tissue interactions between mutant foot skin and normal back skin: a comparison of the inductive capacities of scaleless low line and normal anterior foot dermis.

The inductive capacities of 9- to 16-day anterior foot dermis of scaleless low line and normal embryos were compared by recombining them with a common source of epidermis, i.e., 7-day normal back epidermis. Tissue recombinants were cultured as grafts to the chorioallantoic membrane (CAM). Both normal and scaleless low line dermis of 12 to 13 days of incubation began to lose their ability to elicit feather production in 7-day normal back epidermis. Normal foot dermis began to elicit scale production at 12 to 13 days, whereas scaleless low line anterior foot dermis maintained feather production at a low level. It is inferred that without being associated with scale placode formation, scaleless low line anterior foot dermis does not acquire specific inductive capacities related to the production of an outer scale surface in the overlying epidermis. Feather placodes do not function as surrogates of scale placodes. The difference between normal and scaleless low line anterior foot dermis in terms of specific inductive capacities related to scale production is interpreted as a secondary effect of the action of the scaleless allele in interfering with scale placode formation in the scaleless low line anterior foot epidermis.     

金佛拟小鲵幼体皮肤的显微结构观察

采用光镜和扫描电镜对金佛拟小鲵(Pseudohynobius jinfo)幼体皮肤进行组织学和形态学观察。金佛拟小鲵幼体皮肤由表皮和真皮构成。不同部位皮肤厚度不同,头部背侧皮肤最薄,其厚度为(45.99±12.77)μm,尾部腹侧的皮肤最厚,其厚度为(95.21±42.72)μm。表皮角质层仅躯干背部和尾部明显,由仍具有一定生理活性的复层扁平上皮细胞构成。皮肤腺体包括黏液腺和颗粒腺。黏液腺广泛分布于身体各个部位的皮肤,颗粒腺呈区域性分布,仅见躯干部和尾部皮肤,其体积大于黏液腺。毛细血管多分布于真皮疏松层腺体周围,与表皮层紧密接触并凸向表皮。色素细胞主要分布于表皮和疏松层的交界处,呈多细胞聚集的状态,形成厚度不一的色素层。     

雄性峨眉髭蟾“胡子”的组织结构特征

采用石蜡切片与苏木精-伊红染色及扫描电镜,对雄性峨眉髭蟾Leptobrachium boringii的角质刺及其周边皮肤进行了显微结构和亚显微结构的观察。显微结构观察发现,峨眉髭蟾的角质刺属于皮肤衍生物,突起呈倒"V"形。角质刺由表皮和真皮构成,表皮为复层扁平上皮,可分成4层;最外层细胞角质化,细胞轮廓不清,被染成深红色。真皮由疏松结缔组织构成,分辨不出致密层与疏松层,其内未见皮肤腺,但有少量色素细胞与毛细血管分布。表皮嵴伸入到真皮层,在以往的无尾两栖类研究中未见报道。角质刺基部可见皮肤褶翻起将其包裹在内,皮肤褶向上延伸形成角质刺。扫描电镜观察表明,角质刺顶端呈锥形的"小山丘"状,表面可分辨出表皮细胞轮廓,细胞为呈覆瓦状排列的角质化细胞。角质刺与皮肤交界处为多边形的角质化细胞。角质化上皮细胞的上表面与下表面均具有凹凸不平的花纹结构,细胞之间以镶嵌的方式连接。     

白边油蝠表皮角质化细胞末端分化的超微结构

蝙蝠是一种唯一能够飞行的哺乳动物,其皮肤的超微结构尚未见报道。在电镜下观察了白边油蝠(Pipistrellus kuhlii)背部和翼膜皮肤的超微结构。表皮的厚度较低(10~12μm),角质层下有1~2层的刺细胞,该刺细胞由相似于鸟类无羽表皮的纤细角化细胞形成。颗粒层不连续且仅有少量小型透明角质颗粒(<0.3μm)。在翼膜的若干区域,表皮简化为一层与角质层相连的基底层。过渡期的角化细胞几乎不存在,提示其角质化过程非常迅速。基底膜上的无数半桥粒在真皮下面形成密集的附着点。大量胶原纤维直接维系在半桥粒和基底膜的致密层上,稀疏的弹性纤维使得蝙蝠表皮在飞行时易于伸展、在飞行后易于迅速折叠而不会受到损伤。与鸟类的表皮相似,蝙蝠角化细胞富有大量的脂质。由于脂质有助于蝙蝠皮肤在飞行中与冷空气流的传热绝缘,大量脂质的存在可能是为补偿蝙蝠翼膜的真皮缺乏厚的脂肪层。研究还表明,毛发较薄(4~7μm),并具有与皮层相似的突状物组成的精细表皮,其表皮细胞形成钩状抓握点使毛发紧紧粘结在一起,通过这种方式毛皮保持紧凑以恒定体温。     

Dorsal skin responses to subchronic ultraviolet B (UVB)-irradiation in Wistar-derived hypotrichotic WBN/ILA-Ht rats

Dorsal skin responses to a subchronic UVB-irradiation (10kJ/m2/rat /day), were examined in Wistar-derived hypotrichotic WBN/ILA-Ht rats for up to 3 months. Hyperplasia of epidermal cells and hair follicle epithelial cells as well as parakeratosis developed at 1 month and progressed thereafter, resulting in a prominent epidermis thickening and formation of epidermal ingrowths projecting into the dermis. At the same time, the percentage of proliferating cell nuclear antigen (PCNA)-positive epidermal cells significantly increased after I month. In some portions of the hyperplastic epidermis, especially of the epidermal ingrowths, keratinocytes were somewhat pleomorphic and migrated into the dermis. In the upper dermis, edema with capillary congestion, mast cell infiltration and fibroblast proliferation developed at I month, and the intensity of edema and the number of dermal mast cells was most prominent at 3 months. Edema spread to the epidermis, resulting in intercellular edema and subsequent dissociation of epidermal cells. Degeneration of collagen fibers was also detected in the upper dermis, especially beneath the epidermis. In addition, although not significant because of a large individual difference, the serum IgE concentration, showed a tendency to increase after 2 months. The present study clarified the characteristics of the dorsal skin responses to a subchronic UVB-irradiation in rats.     

A comparative study on vascularization and the structure of the epidermis of an amphibious mudskipper fish,Scartelaos gigas (Gobiidae,Teleostei), on different parts of the body and the appendages

Epidermal structure of the amphibious mudskipper, Scartelaos gigas (Gobiidae), was investigated in relation to their terrestrial adaptation whereby a histological study on the epidermis of 15 regions including nine body regions, five fins and the sucking disc was carried out. The structure of the epidermis consists of three layers: an outermost layer with polygonal cells or rather flattened cells, small cells and mucous cells; a thick middle layer with voluminous cells swollen by epidermal cells; and the stratum germinativum. A dermal bulge was located at each apical area of the epidermis of almost all body regions, but was not existent in the operculum and the appendages, including none of the fins or the sucking disc. In the epidermis of the body regions, the dermal bulges had numerous dermal capillaries just beneath the stratum germinativum. By contrast, the appendages never had dermal capillaries due to the absence of the dermal bulge. Based on these results, the cutaneous air uptake in S. gigas would seem to be more effective in the upper body regions that are most often exposed to air than in the lower body regions, however, cutaneous air uptake is not likely to occur in the appendages.