patandchickens wrote: I really really wish someone would do a good research-based STUDY of it. I had read somewhere that some poultry science type was wantin' to test some of these old-timey things properly; I don't remember any more than that, but it sure would be excellent to have it HAPPEN
Both manufacturers and retailers of ADE (particularly those that push its use as an insecticide) focus on the easy to grasp concept of needle like spicules and sharp edges of DE cutting up insects and this results in some confusion. In the U.S. Pool Grade DE contains 20% crystalline Silicon Dioxide (basically tiny shards of `glass'). This stuff abrades the surfaces of both insects and human lungs. While those same `jagged' particles keep pool filters from clogging up.
The primary mechanism of ADE is adsorption of lipids from the thin waxy layer that otherwise prevents insect's internal fluids from `leaking' out. It does not deliver the coup de grace by thrusting slivers of quartz into the body.
Ebeling (who the Univ. of CA at Riverside lauds as the father of urban entomology), whose paper I linked to, was one of the first entomologists to promote sorptive dusts for pest control (easy to run down the Pop. Mech. article, seemed a pretty accessible explanation of ADE mechanism), but the actual `leg work' had been going on for some time before. I did not link to the paper below as the sorptive dusts investigated did not include ADE (examined a variety of others).
what was found (honeybees were the subjects) was that sorptive dusts exerted their primary effect (adsorption) on both living and
dead bees (abrasion requires friction, i.e., if not moving - alive - no abrasion occurs). Same mechanism that excited Ebeling (use of exclamation marks in a journal article - what a guy).
From: THE CUTICULAR WATERPROOFING MECHANISM OF THE WORKER HONEY-BEE
An excellent and extensive description of action (apiarists might also be interested in the physiology alone):
http://jeb.biologists.org/cgi/reprint/32/1/95.pdf
1. Experiments are described which show that the rate of water-loss from living and dead worker bees is increased when a variety of dusts are brought into intimate contact with the surface of the cuticle. The common property of the more effective dusts is their capacity to act as adsorbents. Considerable evidence has been accumulated to suggest that the dusts need not abrade the surface of the cuticle in order to effect an increased water-loss and that the dusts act by adsorbing the epicuticular lipoid.
As ADE (for food/feed - and it is the same - just bought some food/feed grade yesterday, more on that in a moment), contains <1% crystalline silica and, once in the digestive tract it loses its desiccant property (absorbs ~4 times its wt. in water), it is difficult to know how worming would proceed (am ready to get up to speed - please post links to research - I am old and need novelty!).
Not directly related to `worms' this study on dietary DE on broiler performance doesn't reveal any exemplary `additive' value. Indeed, the research (searching for probiotics/mineral compounds to replace antibiotic growth promoters) indicated that ADE appears to decrease digestibility of `food' :
http://docsdrive.com/pdfs/ansinet/ijps/2008/862-871.pdf
Does this mean ADE is worthless againt internal `bugs'? No, but what is available relates to its use a mechanical adjunct in litter (most of us who use are familiar with this), or is being `ground' into nano-particles (lipophilic mechanism again on a much smaller scale and by a different mechanism ).
[69 Efficacy of acidic calcium sulfate + (clay or diatomaceous earth) litter formulations against Salmonella in broilers. E. L. Larrison* 1 , M. A. Davis 1 , J. A. Byrd 2 , J. B. Carey 1 , and D. J. Caldwell 1 , 1 Texas A&M University, College Station, 2 USDA/SPARC, College Station, TX. :
http://www.poultryscience.org/psa08/abstracts/021.pdf
Research has shown that Salmonella can be prevalent in poultry litter, which can be a source of contamination for newly arrived chicks at the poultry house. Since this organism is a pathogen of concern to the poultry industry, 2 types of litter amendments were created and tested to determine effects on broiler growth, litter moisture and efficacy against Salmonella colonization. Litter amendments consisted of the combination of Acidic Calcium Sulfate (ACS) with either diatomaceous earth (DE) or hydrated sodium calcium aluminiosilicate (HSCAS). Litter samples were taken weekly from 5 areas in each pen and combined for determination of Salmonella counts. At 3 and 6 weeks postplacement, 6 birds from each pen were euthanized by CO 2 asphyxiation. The crop and ceca from these birds were tested for counts and/or presence/absence of Salmonella. Application of both litter amendments positively affected feed conversion and at 3 weeks postplacement the DE+ACS treatment did not have any birds positive for Salmonella. Efficacy of the litter amendments were varied in other treatments and further research is planned to fully determine efficacy on Salmonella and Campylobacter jejuni colonization.
Control of poultry chicken malaria by surface functionalized amorphous nanosilica :
http://arxiv.org/ftp/arxiv/papers/0707/0707.2446.pdf
We therefore looked for a drug source or lead molecule which has already been used by the poultry industry as feed for a long time and is also considered inert in nature. Naturally occurring amorphous silica is used by poultry industries for a long time and is considered to be safe for human consumption by different regulatory agencies worldwide. But the major problem with amorphous silica is its hygroscopic nature; this does not allow it to absorb other substances once it absorbs water. In order to circumvent this problem, we decided to first increase the surface area by breaking them to the nano-meter range and then modify the surface properties described elsewhere in detail 17-19...
...As a result, the nanosilica became hydrophobic as well as lipophilic in nature. These nanosilica possess nanopores and due to their lipophilic nature they could absorb lipids non-specifically via physio-sorption. These particles have been used in the present set of experiments as drugs to mop up the excess amount of the host serum cholesterol lipids which is used by the malarial parasite mainly for their intra-erythrocytic growth. The results show clearly that these nanosilicas at the doses mentioned earlier in the text could be used as excellent therapeutic agent against chicken malaria and will be a very valuable tool for the broiler industry worldwide.
FYI: Another couple ruminant study results: (FEC fecal egg count):
http://www.mtsylviadiatomite.com.au/mod/files/research/DE_Natural_Dewormer_Study.pdf (quoted).
(Not quoted, but even less encouraging:
http://beef.unl.edu/beefreports/200019.shtml ).
The physical performance results from study 1 are summarised in Table 1 below. In the cattle study (Study 1) there were no significant differences between treatment groups in terms of liveweight gain. There were significant differences in FEC (see Figure 1) however, with cattle in the control group (untreated) having significantly higher (P<0.05) FEC (404 epg) at week 7 compared to cattle in the drench group (137 epg). Cattle in the diatomaceous earth group had lower FEC (172 epg) in week 7 than cattle in the control group but this just missed significance.
Food Grade/Feed grade/insecticide grade ADE. FDA/EPA make no distinction, except in the labeling, (I supposed there was a CFR that I was too stupid to find but in this instance I got lucky) in that all contain <1% crystalline silica. Yesterday, I bought a 50lb. bag of `feed' grade ADE, manufactured for Canton Mills in MN., by the Celite Corp., for $24.95.
On the shelf was a 2lb. bag of Natural Guard ADE for insects $8.95. I compared the product info.. Someone is making a killing.
Always read the labels, some ADE is mixed with pyrethrins and that will be listed.
Fly suppression examination at home? Two wide mouthed Ball jars of the same size. Stir up a cecal poop from a single hen, apply an equal amount of poop in the bottoms of the bottles (smear with a paint brush). Blow a bit of DE from the palm of your hand over the open mouth of one of the bottles, place the bottles one foot apart in the area where the most flies are normally observed, at the time of day when the most flies show up. Count how many flies enter each bottle, how many land on each poop, and how long they remain on the poop if they do land. That is an extremely informal initial step. Have fun!
Hypotheses non fingo, ya'll
Ed: formatting/sp
