The ability of Aedes aegypti mosquitoes to survive and transmit infective larvae of Brugia pahangi over successive blood meals

The mortality of Aedes aegypti mosquitoes increased; immediately following a blood meal containing microfilariae of Brugia pahangi, when infective larvae began to migrate out of the flight muscles and when infective larvae were lost from the mosquitoes during a blood meal. When infective mosquitoes took a second blood meal 86.2% of the infective larvae escaped from their bodies. However, only 50.3% escaped when mosquitoes fed through a thin layer of cotton. Infective larvae in the abdomen of the mosquitoes stood the least chance of escaping from the insects. When infective mosquitoes were offered a third blood meal four days later, the proportion of infective larvae in the head and labium had risen from 56.6% in the control group to 66.0% and 69.4% in the two test groups. At this third feed 54.7% and 75.7% of the infective larvae were lost from mosquitoes with a low and medium pre-feeding worm burden respectively. This suggests that the escape of infective larvae from mosquitoes with only a few worms is less efficient than from mosquitoes with a medium worm burden.     

Angiostrongylus costaricensis: culture of third-stage larvae to young adults in a defined medium

The third-stage larvae of Angiostrongylus costaricensis were successfully cultured to young adults in a chemically defined medium. The most suitable medium for the development was Waymouth's medium among eight defined media examined. Twenty-eight days after cultivation in this medium, 77% of the larvae developed to young adults, although these worms gradually died thereafter. When Waymouth's medium was supplemented with mouse red blood cells, these young adult worms continued their development. The mean body lengths of the worms cultivated in Waymouth's medium supplemented with RBCs were significantly larger than those of the worms in the medium without RBCs on Days 14 and 21 after cultivation. Addition of RBCs was essential for their further development. At 28 days after cultivation, the maximum body length of the worms was 2.1 mm for males and 3.3 mm for females. Additions of serum, yeast extract lactalbumin hydrolysate, and growth factors to Waymouth's medium did not provide any additional benefits for worm development.     

Angiostrongylus cantonensis (Nematode: Metastrongiloidea): In Vitro Cultivation of Infective Third-Stage Larvae to Fourth-Stage Larvae

The present study to attempt to cultivate Angiostrongylus cantonensis from third-stage larvae (AcL3) to fourth-stage larvae (AcL4) in vitro in defined complete culture medium that contained with Minimum Essential Medium Eagle (MEM), supplemented amino acid (AA), amine (AM), fatty acid (FA), carbohydrate (CA) and 20% fetal calf serum (FCS) was successful. When AcL3 were cultured in the defined complete culture medium at 37°C in a 5% CO₂ atmosphere, the larvae began to develop to AcL4 after 30 days of cultivation, and were enclosed within the sheaths of the third molts of the life cycle. Under these conditions, the larvae developed uniformly and reached to the fourth-stage 36 days. The morphology of AcL3 develop to AcL4 were recording and analyzing. Then comparison of A. cantonensis larval morphology and development between in vitro cultivation in defined complete culture medium and in vivo cultivation in infective BALB/c mice. The larvae that had been cultivated in vitro were smaller than AcL4 of infective BALB/c mice. However the AcL3 that were cultured using defined incomplete culture medium (MEM plus 20% FCS with AA+AM, FA, CA, AA+AM+FA, FA+CA, CA+AA+AM or not) did not adequately survive and develop. Accordingly, the inference is made that only the defined complete medium enable AcL3 develop to AcL4 in vitro. Some nematodes have been successfully cultured into mature worms but only a few researches have been made to cultivate A. cantonensis in vitro. The present study is the first to have succeeded in developing AcL3 to AcL4 by in vitro cultivation. Finally, the results of in vitro cultivation studies herein contribute to improving media for the effective development and growth of A. cantonensis. The gap in the A. cantonensis life cycle when the larvae are cultivated in vitro from third-stage larvae to fourth-stage larvae can thus be solved.     

The development of Eustrongylides tubifex (Nematoda: Dioctophymatoidea) in oligochaetes

Egg development of Eustrongylides tubifex (Nitzsch in Rudolphi, 1819) J?gerski?ld, 1909, was studied at 5, 10, 15, 20, 25, and 30 C. Eggs developed at 20, 25, and 30 C. Development ceased at 0, 5, 10, and 15 C but resumed when temperatures were raised. Eggs contained first-stage larvae in 23-26 days at 25 C. Seven species of aquatic oligochaetes were exposed experimentally to eggs of E. tubifex containing first-stage larvae. Third-stage larvae of E. tubifex developed in the aquatic oligochaetes, Limnodrilus hoffmeisteri Claparède, 1862, and Tubifex tubifex (Müller, 1774). Larvae developed in the ventral blood vessel of oligochaetes. Second-stage larvae were seen first in oligochaetes 30 days postinfection and third-stage larvae were seen 70-109 days postinfection at 25 C. Third-stage larvae in oligochaetes retained the cuticle of the first and second molt.     

Ascaris suum: immunoperoxidase and fluorescent probe analysis of host proteases and parasite proteinase inhibitors in developing eggs and second stage larvae

Live Ascaris suum females were incubated in medium containing chymotrypsin liganded to fluorescein-5-isothiocyanate, and eggs in the parasite's genital tract took up the probe and fluoresced. Eggs passed by these worms into the medium containing fluorescent probe retained their fluorescence in formaldehyde-saline and by 65 days had developed into second stage infective larvae. Eggs passed naturally by untreated worms were incubated in media containing fluorescent probes and all of the eggs exposed to chymotrypsin liganded to fluorescein-5-isothiocyanate were extensively labeled. Control eggs were labeled sporadically and less intensely, indicating specificity in the uptake of environmental proteins. Chymotrypsin from the parasite's environment can bind to A. suum eggs, and this occurs both inside the worm's genital tract and outside of the parasite. Immunoperoxidase studies showed that IgG developed against chymotrypsin or against A. suum chymotrypsin/elastase isoinhibitors A or C, binds to antigens in cross sections of second stage larvae and their egg shell coats. This suggests that host chymotrypsin is retained during development and may be complexed to A. suum isoinhibitors A and C.     

Anopheles stephensi and Toxorhynchites amboinensis: aseptic rearing of mosquito larvae on cultured cells

Aseptic larvae of Anopheles stephensi and Toxorhynchites amboinensis were reared on a continuous cell line (RU TAE 12 V) from the mosquito, T. amboinensis, that grew in suspension as multicellular vesicles. Surface-sterilized eggs were hatched in a 24-well plate containing 0.2 ml of Leibovitz's L-15 medium per well and incubated in a humidified atmosphere. Toxorhynchites amboinensis eggs of 36 hr or older were placed singly to assure hatching and avoid cannibalism. Hatching rates were over 80%. All larval instars were maintained in L-15 medium at 28 C with a 12-hr photoperiod. Anopheles stephensi larvae were reared in 25-cm2 tissue culture flasks containing 10 ml of L-15 medium with 30 to 50 first and second instar larvae or 10 third and fourth instar larvae per flask. Toxorhynchites amboinensis larvae remained in the 24-well plate in 1.5 ml of medium through the second instar; third instar larvae were kept in 12-well plates (3 ml of medium per well) and transferred to 25-cm2 flasks (10 ml per flask) when they reached the fourth instar. First and second instar A. stephensi larvae were fed cultured cells once, and third or fourth instar larvae twice a day. Toxorhynchites amboinensis larvae were fed vesicles once during the first 4 days after hatching, and every 1 or 2 days thereafter. Each A. stephensi larva consumed approximately 2 X 10(6) cells, and T. amboinensis larvae 10 times more cells before pupating. Anopheles stephensi pupated after 7 to 8 days and adults emerged during days 9 to 11. Pupation in T. amboinensis began on day 21 after hatching and adults emerged 5 days later. Cell lines isolated from A. stephensi larvae or embryos of the ticks Rhipicephalus sanguineus and Anocentor (Dermacentor) nitens supported only limited growth of A. stephensi larvae. Defibrinated hamster (Mesocricetus auratus) blood, though readily ingested, did not support the growth of A. stephensi whereas larvae reared on blood cells plus T. amboinensis cells showed limited growth.     

Epizootiology of Eustrongylides ignotus in Florida: transmission and development of larvae in intermediate hosts

Under laboratory conditions, 2 modes of transmission of Eustrongylides ignotus (Nematoda: Dioctophymatoidea) to fish were identified. Eastern mosquitofish (Gambusia holbrooki) became infected after ingestion of either eggs of E. ignotus containing first-stage larvae or aquatic oligochaetes (Limnodrilus hoffmeisteri) containing third-stage larvae of E. ignotus. After removal from the uterus of gravid E. ignotus females and incubation for 17-28 days, depending on temperature, it was found that parasite eggs contained first-stage larvae that were infective to fish and oligochaetes. Larvae developed to the third stage in oligochaetes and were infective to fish 35-77 days postinfection (PI) and when fed to fish, developed to the fourth stage between 127 and 184 days PI. Eggs containing first-stage larvae fed directly to fish developed to the fourth stage between 84 and 105 days PI. The amount of time for development from the undifferentiated egg to the fourth-stage larva was 78-156 days shorter when fish ingested eggs containing first-stage larvae than when fish ingested oligochaetes containing third-stage larvae. Three species of large piscivorous fish, including black crappie (Pomoxis nigromaculatus), largemouth bass (Micropterus salmoides), and warmouth (Lepomis gulosus), were fed mosquitofish containing fourth-stage larvae. At necropsy, live E. ignotus larvae were recovered from all 3 species. Several fish had multiple infections after ingesting > 1 larva, indicating that bioaccumulation of the parasite in the food chain may occur.     

Efficacy of ivermectin against Parelaphostrongylus andersoni (Nematoda, Metastrongyloidea) in white-tailed deer (Odocoileus virginianus)

Ivermectin was injected subcutaneously at 200 and 400 micrograms/kg of body weight into seven white-tailed deer (Odocoileus virginianus) in an attempt to control the muscle nematode Parelaphostrongylus andersoni. Counts of first-stage larvae in feces dropped to zero at 17 to 18 days posttreatment. Larvae reappeared in feces 1.5 to 6 wk later in six deer. Four deer were treated again approximately 9 wk after the first treatment; larval counts dropped to zero in 12 to 18 days. Larvae reappeared in low numbers 45 to 55 days after the second treatment. Because deer were held indoors on cement and the prepatent period of these worms is approximately 2 mo, the reappearance of larvae was not due to reinfection by accidental ingestion of gastropod intermediate hosts. Results suggest that ivermectin at dosages of 200 or 400 micrograms/kg of body weight suppressed larval production by adult female nematodes for several weeks or destroyed first-stage larvae in the lungs.     

Studies on the cryopreservation of Dictyocaulus viviparus (Nematoda) third-stage larvae

Various cooling (0.1-5,100 degrees C min-1) and warming (20-6,800 degrees C min-1) rates, stepped cooling schedules and four cryoprotective additives (dimethyl sulphoxide, methanol, ethanediol and glycerol) were investigated in cryopreservation studies with Dictyocaulus viviparus third-stage larvae. Exsheathment with sodium hypochlorite was essential to achieve significant survival. With uninterrupted cooling, highest survival (30% normally motile) was achieved with rates of 10-70 degrees C min-1. Survival was higher (50-75%) using 1 degree C min-1 to -10 degrees C followed by plunging into liquid nitrogen. The optimum warming rate was 6,800 degrees C min-1. The use of cryoprotectants led to marginally lower survival while varying the suspending media had no significant effect on survival. X-irradiated, exsheathed third-stage larvae cryopreserved by the optimum protocol yielded 38.3 +/- 4.2% survival. Two calves each infected with 45,000 (15,000 viable) exsheathed, unirradiated, cryopreserved third-stage larvae harboured 494 worms (1.1% infectivity) and 355 worms (0.8%) at necropsy. Numbers of first-stage larvae in the faeces reached 420/g and 105/g respectively 27 days after infection.     

Maturation, fertilization, and development of dog oocytes in vitro.

Preovulatory oocytes were collected from ovaries of beagle bitches that had received superovulatory treatment. They were cultured in a modified Krebs-Ringer bicarbonate solution containing 10% fetal calf serum and 30 mg/L gentamicin sulfate for up to 72 h. About 32% of oocytes reached metaphase II by 72 h of culture. When these in vitro-matured oocytes were inseminated with ejaculated beagle spermatozoa that had been preincubated for 4 h, sperm penetration of the zona pellucida started about 1 h after insemination, and both male and female pronuclei were seen in the ooplasm at 8 h after insemination. At 18-20 h after insemination, oocytes were transferred to Whitten's medium and cultured for 76-78 h. The first cleavage was observed at 48 h after insemination, and 15 of 45 oocytes developed to the 2-8-cell stage. These results demonstrate that in vitro-matured canine oocytes can be fertilized and develop to the 8-cell stage in vitro.     

Leishmania mexicana: Serial cultivation of intracellular stages in a cell-free medium

A cell-free liquid medium has been devised for serial cultivation of Leishmania mexicana pifanoi amastigotes at 33 and 35 C. It consists of tissue culture Medium 199 fortified primarily with a high concentration of water-soluble vitamins, nucleotides, and inactivated fetal bovine serum. The initial pH of the medium is 7.2. Starting with a population of promastigotes as inoculum and serially cultured at 33 or 35 C at 4- to 10-day intervals, the proportion of amastigotes steadily increased and that of promastigotes gradually decreased during the first subculture. By the end of the incubation period in the second subculture, practically all (99%) of the organisms are amastigotes. The amastigotes thus obtained can be cultured indefinitely by serial transfers. In this medium, amastigotes may reach a density of 8 × 10⁷/ml after 10 days of incubation at 33 C, and 5 × 10⁷/ml at 35 C. The medium was modified to have an initial pH of 8.0 by Hepes [4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid] buffer and higher concentrations of sodium bicarbonate. When amastigotes cultured in the original medium at 33 or 35 C are transferred into the modified medium and incubated at 26 C, the amastigotes entirely transformed into promastigotes after three serial passages. These promastigotes could be serially subcultured indefinitely in the modified medium at 4- to 12-day intervals. The promastigotes cultured at 26 C may reach a population density of 7 × 10⁷/ml after 12 days of incubation.     

Resistance to ivermectin by Haemonchus contortus in goats and calves.

Efficacy of ivermectin on susceptible or resistant populations of the parasitic nematode Haemonchus contortus was determined in cattle and goats held in a barn. Goats were each infected with 3000 infective, ivermectin-susceptible or -resistant H. contortus larvae on day 0 and reinfected with 2000 infective larvae on day 24. Goats were treated orally with 600 micrograms kg-1 ivermectin on day 31. No significant differences were detected in blood packed cell volume (PCV) or total protein (TP), prepatent period, or epg among the four groups of goats that were each infected with one of four parasite strains (one susceptible, three resistant). There were no differences among the four parasite strains in the numbers of infective larvae that developed to the third larval stage from fecal cultures or in the viability of cultured infective larvae when held in the laboratory at 27 +/- 1 degrees C for 14 weeks. After treatment with ivermectin, there were significant differences among the parasite strains in PCV, TP, and epg. Total worm counts were reduced by 94 to 97% with three times the recommended dose. Immature and adult Skrjabinema ovis were also present in two treated goats. In a second test, one goat infected once with 10,000 infective larvae of a resistant strain of H. contortus and then treated with nine doses of ivermectin, increasing from 500 to 2000 micrograms kg-1 over a period of 133 days, had 35 adult worms at necropsy. In a third test, three calves were readily infected with an ivermectin-resistant strain of H. contortus from goats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nematospiroides dubius: arrested development of larvae in immune mice.

When immune NIH mice were killed 10 days after a challenge infection with Nematospiroides dubius, approximately 10% of the inoculated larvae were recovered from the intestinal lumen, irrespective of the dose administered. When such mice were treated with cortisone from Day 10 for a period of 8 to 14 days and were subsequently killed for worm counts, it was found that they had significantly more worms than the immune control mice killed on Day 10. During the week following the beginning of treatment with cortisone there was little change in the low worm burdens in immune mice. However, 9 to 11 days after this treatment worm counts indicated that worms were accumulating in the intestinal lumen, and concurrently eggs were recorded in the feces of the mice. These observations indicated that a period of 9 to 11 days was required after the initiation of cortisone treatment on Day 10 for the worms in immune mice to complete their development to the adult lumen-dwelling stage. It is suggested that the larvae in the challenge infection became arrested early in their development in the intestinal wall and that growth resumed only after cortisone treatment. When treatment with cortisone was initiated later after challenge, it was still effective in reactivating arrested worms, but the lower worm recoveries in these mice indicated that the arrested larvae were being slowly rejected by the host. In subsequent experiments it was established that the arrested larvae of N. dubius were insusceptible to the activity of pyrantel embonate, an anthelmintic which is 99% effective against adult worms in the intestinal lumen. The mechanism whereby the larvae of N. dubius became arrested in immune mice and subsequently resumed their development after cortisone treatment is discussed.     

Dipetalonema viteae: primary, secondary and tertiary infections in hamsters.

Hamsters were given primary infections of 100, 200, and 300 D. viteae larvae and groups killed at various intervals after infection. In addition, hamsters were sequentially infected with 100, 200, and 300 larvae and groups killed at 100 or 75 days after the secondary and tertiary infection, respectively. Blood microfilariae were detected on Day 60 following a primary infection, reached a maximum on Day 75, declined to low levels by Day 105, and were negative on Day 120. No microfilariae reappeared in the blood of hamsters given secondary or tertiary infections.Between 20–30% of the infecting larval dose had reached the adult stage by Days 75 or 100 postinfection in hamsters given primary, secondary, or tertiary infections. There was no evidence of arrested larval development in hamsters receiving a second or third challenge infection. Almost half of the tertiary infection hamsters developed subcutaneous nodules and their numbers varied greatly among individual animals. The nodules variously contained living worms, pus, and fragmented worms, or pus only. Hamsters given primary infections of 100, 200, or 300 larvae and killed 375 days after infection had no subcutaneous nodules; however, hamsters given the 200 and 300 larval infections were seen to have dead worms in the subcutaneous tissues. No stunting of adult worms was noted and all female worms had uteri packed with microfilariae.     

Strongyloides stercoralis: Amphidial neuron pair ASJ triggers significant resumption of development by infective larvae under host-mimicking in vitro conditions

Resumption of development by infective larvae (L3i) of parasitic nematodes upon entering a host is a critical first step in establishing a parasitic relationship with a definitive host. It is also considered equivalent to exit from the dauer stage by the free-living nematode Caenorhabditis elegans. Initiation of feeding, an early event in this process, is induced in vitro in L3i of Strongyloides stercoralis, a parasite of humans, other primates and dogs, by culturing the larvae in DMEM with 10% canine serum and 5mM glutathione at 37 degrees C with 5% CO(2). Based on the developmental neurobiology of C. elegans, resumption of development by S. stercoralis L3i should be mediated, in part at least, by neurons homologous to the ASJ pair of C. elegans. To test this hypothesis, the ASJ neurons in S. stercoralis first-stage larvae (L1) were ablated with a laser microbeam. This resulted in a statistically significant (33%) reduction in the number of L3i that resumed feeding in culture. In a second expanded investigation, the thermosensitive ALD neurons, along with the ASJ neurons, were ablated, but there was no further decrease in the initiation of feeding by these worms compared to those in which only the ASJ pair was ablated.     

Attempts to culture the parasitic stage of Dermatobia hominis (L. Jr.) in vitro (Diptera: Cuterebridae)

Dermatobia hominis larvae were cultured in a semidefined liquid medium. First-instar larvae (L1) grew well up to 44 days; 29.1% molted in a mean period of 8.62 days. Two larvae reached the third instar but lived only 1 and 18 days, respectively, after the second molt. The increase in size, measured in 4 larvae, was about 10-fold. Second- and third-instar larvae, obtained from the skin of cattle, survived and grew in the medium for up to 2 mo; 39.0% of the L2 molted while 77.3% of the L3 pupated, and some produced flies when transferred to sand after 14.84 +/- 10.08 days in the culture medium. Some maturation factor, obtained from the skin, may be necessary for the larvae to grow satisfactorily and to complete the full parasitic cycle in vitro.     

Effect of flubendazole on the number of first-stage larvae of Angiostrongylus cantonensis released in the faeces of treated rats

The effect of flubendazole orally administered at 10 mg/kg/day for 5 consecutive days (the 11th, 20th or 40th post-infection) on the number of first-stage larvae (L1) of Angiostrongylus cantonensis released in the faeces of rats each infected with 40 third-stage larvae was determined. Faecal examination for 5 months, the period from medication to dissection of rats, showed that L1 release ceased in all the rats of medicated groups by about 1 week after the termination of dosing and resumed 1-2 months later in 86% of the rats which were dissected at the end of experiments with the recovery of adult worms of both sexes. Throughout the period of 5 months, about 2-4 x 10(4) L1/gram of fresh faeces was recorded in non-medicated control groups. There was a 38-79% reduction in adult worms at the dissection. Microscopic examination of the uteri of the remaining adult worms and lung tissues of rats confirmed no normal egg production in the adult worms from rats of medicated groups, except the rats with the resumption of faecal L1 release.     

The bionomics of the free-living larvae and the transmission of Dictyocaulus filaria between lambs in North-East England.

The bionomics of the free-living larvae of Dictyocaulus filaria on pasture, and the transmission of infection between lambs, were studied during different seasons of the year in North-East England. The rate of development of first-stage larvae to the third stage took 4-9 days in late spring and summer, 1 1/2-4 weeks in autumn and 5 1/2-7 weeks in winter. The proportion of first-stage larvae developing to the third stage ranged from 10-28% in autumn and winter, and 2-25% in spring and summer. The rate of mortality of the third-stage larvae was approximately logarithmic in nature, although the survival time was shorter in spring and summer than in autumn and winter. Third stage larvae were able to survive from autumn until the spring of the following year in sufficient numbers to perpetuate transmission but not to cause clinical disease. In a transmission study, the survival of the infective larvae on the experimental plot was poor in summer, but the larval population increased in the autumn and then declined slowly throughout the winter. Infection in the susceptible lambs was related to the level of infection on the herbage increasing in severity from early summer to late autumn. However, those lambs infected in the summer were resistant to the heavy autumn challenge of larvae on pasture.     

Effects of temperature on hatching and development of Nematospiroides dubius in aerated water.

Fresh eggs obtained from female Nematospiroides dubius were cultured at temperatures ranging from 5 degrees C to 33 degrees C. Hatching occurred between 5 degrees C and 30 degrees C; third stage larvae were obtained between five degrees C and 25 degrees C. The minimum time required from hatching to development to the third stage was 3-6 days (at 20 degrees C) and the maximum was seven days (at 5 degrees C). Larvae cultured at higher temperatures were smaller than those cultured at lower ones.