Wednesday, December 28, 2016

Mushrooms Growing Inside During Winter

Interesting website
http://myceliumconnection.blogspot.com/2012/10/fungal-word-friday-chitin_19.html

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I decided to try something different and bought a few mushroom kits.

Shitake
Enoki
Mitake (Hen of the Woods)
Portabella

So far so good.   Most like it cold, between 50 to 60F they get the corner room with the heat turned off.

Portabella likes it more like 70F so that goes to the "Hobby Room".   I had a pentagon shaped fish aquarium bought for $10 so that became the home for the Portabella kit from Steins.

There are 30 Portabella "pins" right now, now it is the "Fruit Body Development" stage.

This is Portabella 

Maitake aka Hen of the Woods -- they go through 4 ot 5 "fruit body" stages before they take their final form.
Enoki -- Smallish Mushrooms, often added to Japanese dishes or soups

Shitake - Wasn't doing much but some started growing from the bottom so I flipped it over.

Portabella "pins" aka Primordia Formation, these grow fast, bigger everytime you look at them.
Here is a finished Portabella.   Great texture and taste, almost like eating a meat.

Thursday, December 15, 2016

Mushroom Cultivation

easiest way to start is to buy a kit.   See if you like it enough, before taking the plunge into the whole 9 yards from scratch.

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Getting Started with Mushroom Cultivation

by Terri Marie Beauséjour
Copyright 1999, all rights reserved.
This article first appeared in Mushroom: the Journal of Wild Mushrooming. Subscriptions are $25 for four quarterly issues from Mushroom the Journal, 1511 E. 54th St. Chicago, IL 60615.

The Wisdom of Simplicity

If you have been intrigued by the prospect of growing your own mushrooms, perhaps after a bit of research you became daunted by the complexity and potential expense of "sterile techniques," "clean rooms," "laminar flow hoods" and "agar media."
Or perhaps you are the more adventurous type. You plunged ahead with valiant attempts to isolate pure mycelial cultures, only to discover your beautiful white mycelium bursting into a rainbow of brilliantly colored fuzzy mold spores or sleek, shiny pools of bacterial contaminants. Take heart, you are not alone!
As chairman of the Cultivation Committee for the Mycological Society of San Francisco (MSSF), I have talked with many aspiring cultivators, and those are two of the most common roadblocks preventing progress in mushroom cultivation.
Recognizing the need to help overcome these challenges, the MSSF cultivation committee has periodically offered classes and workshops on how to grow mushrooms. I'm indebted to past teachers of these workshops -- Sal Billeci, Dr. Joe Mandell, Fred Stevens and Don Simoni -- for some of the methods I'm presenting here.

Goals and Objectives

The ultimate goal, of course is to start with one mushroom fruitbody and turn it into a bunch of fruitbodies. There are two mechanisms by which mushrooms can reproduce -- by spores (similar to the seeds of plants) or by propagation of tissue extracted from a fruitbody (similar to plant propagation through cuttings). To get started we will use the latter technique, which is simpler and which offers a better chance of success for the beginning cultivator.
The objectives are:
  • Start with a sterile piece of mushroom tissue and transfer it onto a nutrient medium (actually to a series of media in phases, which you will see as you read on),
  • Create multiple copies of the culture,
  • Avoid contamination of the culture,
  • And, finally, create an environment in which the fungal organism is induced to fruit.
There are three distinct phases (see Figure 1) through which your culture will pass:
  1. Sterile culture on an agar medium
  2. Sterile culture on grain, also known as "grain spawn"
  3. Fruiting on a pasteurized substrate
Now don't let the word "sterile" and a bit of terminology deter you. Yes, potential "contaminants" exist everywhere in the environment, in our homes, and even in clean rooms and laboratories. The objective is to prevent them from entering our cultures and competing for the "food" we intend for the sole use of our mushroom cultures. With a modicum of care and a little practice using some simple techniques, this process can be successfully mastered by anyone. So take a deep breath, and read on for the step-by-step details.
Fig. 1
Fig. 1 -- It really is simple! (Drawings by T. Beauséjour)

Phase I: Agar preparation and sterile culture

Agar Preparation: The first step is to prepare the agar media. Derived from a seaweed, agar plus added ingredients is often used to start and isolate cultures. Microbiologists tailor agar media to selectively grow fungi by adding various nutrients, e.g. minerals, antibiotics, etc. Agar media also has the advantage that contaminants are usually detected easily on the media surface, and thus can be eliminated early in the growing process.
Many types of agar can be used to grow fungal mycelium. Two of the more common are Potato Dextrose Agar (PDA) and Malt Dextrose Agar (MDA). Premixed commercial preparations are available from a number of sources. Although these may be considered relatively expensive compared with preparing the agar "from scratch," if one has more money than time, they are a good choice.
For the do-it-yourselfer, two methods of preparation for PDA are given below. The first is a method I have used with success; it is based on that described in The Mushroom Cultivator, by Paul Stamets and J.S. Chilton. The second is a method successfully taught and used by the MSSF cultivation group. Try one or the other, or both, on for size. You will soon either adopt one that suits you well, or you will more likely incorporate some of these jewels of wisdom into your own method, which will undoubtedly evolve over time. The procedures are similar to making a recipe from a cookbook.

Materials Needed for both methods

  • Rolled cotton (available at pharmacies)
  • Aluminum foil
  • Test tubes with autoclavable screw-caps -- get from a medical or biological supply company, or scrounge. Labs sometimes discard these tubes in vast quantities. Call around.
  • A small funnel for pouring the tubes
  • Measuring cups
  • A pressure cooker
  • Two 1-liter small mouth bottles or pouring flasks
First, a note on the pressure cooker. This is probably the most expensive essential item for the home cultivator. If you already own one, and it is of sufficient size to contain the bottles or jars you wish to use, you are all set. If not, a new cooker may cost somewhere between $75 - $250, depending on size and where it is purchased. They may be found at most hardware stores.
It is also possible to start out frugally if you are on a limited budget by searching at thrift stores, garage and rummage sales, and flea markets. Good quality pressure cookers may often be found for $15 - 35. Be sure to get the type with a pressure gauge, rather than the type with weight only and no gauge. In any event, always read and carefully follow the manufacturer's safety instructions for the cooker you choose.

PDA Method No. 1

(Makes about 1 liter of media)
    Materials Needed:
  • 300 grams potatoes
  • 20 grams agar (from biological supply, health food store or Asian food market)
  • 10 grams dextrose or other sugar
  • 2 grams brewers yeast (optional)
Boil potatoes in 1 liter of water for 1 hour. Drain the potatoes, reserving the liquid. Mash the potatoes, apply butter, salt and pepper, and eat. Sour cream, chives and other amendments are optional.
Once your appetite for mashed potatoes has been satisfied, place the potato broth with the agar, sugar and optionally the yeast in a bowl and mix thoroughly (a wire whisk works well, but stir, do not beat).
Pour half of the mixture into each bottle or flask. Fill to only 1/2 to 3/4 of the vessel's capacity. Plug the mouths of the bottles or flasks with cotton and cover with aluminum foil. Put about 1/2 inch water in the bottom of the cooker and insert its rack and then the bottles or flasks. Place the cover on the cooker and lock it in place. Turn on the heat until steam is venting from the cooker. Allow to vent for a few minutes before closing the stopper or applying the weight.
Cook the vessels at 15 psi (250 degrees F.) for 15 minutes. Do not allow the temperature to exceed 250 degrees F. for any length of time as that will caramelize the media and ruin it.
After the 15 minutes, turn off the heat and allow the pressure to return to normal gradually (about 45 minutes). Meanwhile, remove the caps from the tubes, place the tubes in clean tin cans or test tube racks, and place cans or racks of tubes and caps on a clean work surface in a dust-free location. Once the media vessels can be handled with a clean towel or oven mitt, remove them from the cooker to the location with the tubes. Swish the media around a bit to mix it thoroughly and remove the foil and cotton. Fill the tubes to about 1/3 their capacity, using the funnel.
Place the caps loosely on the tubes, place the cans of tubes in the pressure cooker (replacing used water in the bottom of the cooker, if needed), bring back to 15 psi (250 degrees F.) and cook for 30 minutes. Again let the cooker cool gradually until the pressure is back to normal.
Remove the cans of tubes and tighten the caps. Anchor or otherwise support the cans such that they are tilted at an angle and the agar media surface is "slanted" in the tubes, offering the maximum amount of surface area on the media for future mycelial growth. (Tubes prepared in this manner are often referred to as "slants.")
As the media cools, it will harden into a gel, and eventually the cans can be returned to their vertical position and the media will remain in place. If tubes will not be used immediately, they may be stored in Ziploc bags in the refrigerator for weeks to months. If stored, be sure to check for mold or bacterial contamination before use.

PDA Method No. 2

(makes about one quart of medium)
    Materials Needed:
  • 10 ounces or 284 grams potatoes
  • 3/4 ounce or 21.3 grams agar
  • 1/4 ounce or 8 grams dextrose -- table sugar may be substituted
Step 1: Mixing the ingredients
  1. Wash the potatoes but don't peel. Slice into small pieces.
  2. Cook potatoes until tender, in about a pint of water.
  3. Strain and save the liquid. Discard the potatoes or save to eat later.
  4. Mix the dextrose/sugar, potato broth and agar in a metal or Pyrex¿ bowl. Add water bringing the volume to one quart.
Step 2: Liquefying the Agar
  1. Place the agar mixture in a pressure cooker. Cover the bowl with a sheet of aluminum foil.
  2. Bring the pressure up to 15 psi. Cooking 20 minutes will liquefy the agar mixture.
  3. Let the pressure cooker cool slowly.
Step 3: Pouring agar into test tubes
  1. With an oven mitt and measuring cup, fill each test tube about 1/3 full. Tin cans can be used in place of test tube racks. Excess agar may be stored in a bottle, closed with a cotton or polyester fiber plug and sterilized later along with the test tubes. If test tubes are not available, small bottles can be used instead.
  2. If the test tubes have plastic caps, the caps should be loose so that pressure can equalize during sterilization. Cotton or polyester plugs avoid this problem but require an aluminum foil cover to prevent wetness from condensation when the pressure cooker cools.
Step 4: Sterilizing the Agar
  1. Place the test tubes/bottles containing the agar in a pressure cooker and sterilize at 15 psi for 25 minutes. Do not count the time needed to bring the pressure cooker up to 15 psi.
  2. Let the pressure cooker cool slowly. Sudden release of pressure will cause the agar in the tubes to boil violently, splattering the caps and plugs and creating a potential for contamination.
Step 5: Slanting the test tubes
  1. Wipe down with water or a 10% bleach solution the area where the test tubes are to be slanted. Work in a draft-free room.
  2. With an oven mitt, slant the still hot tubes against a raised surface. Experiment beforehand with strips of wood or magazines to establish the correct angle.
  3. After the agar has jelled, tighten the caps. Store the finished tubes/bottles in a cool, dust free area. A cover of aluminum foil will help to prevent contamination before the tubes are used.

Sterile Culture Technique

Once the agar tubes have cooled, it is time to use them to start mushroom cultures.
    Materials needed:
  • A scalpel or very sharp thin-bladed knife
  • An alcohol lamp or propane torch with fuel and lighting device or matches
  • Tin can(s) or test tube racks containing the "slants" and one extra can or rack for storing completed tubes
  • Scalpel or knife rest (see below for examples of homemade varieties)
  • Micro-porous tape (such as first aid tape from the pharmacy or medical supply) or masking tape (a lower-cost option)
  • Spray bottle containing 10% chlorine bleach, 90% water solution (optional)
  • Fresh, clean mushroom fruitbody or bodies (Oyster mushrooms are highly recommended for beginning cultivators)
Select a location in your home, office or lab which is as free as possible from dust and molds. Work on a sturdy table or bench after cleaning the surface with warm, soapy water and wiping dry. (You may also spray the area with the 10% bleach solution for extra protection and wipe with a clean cloth or paper towel.) Have all windows closed and minimize air circulation. (Ideally, try to carry out your cultivation activities first thing in the morning before particulates are kicked up by household activities.)
Have all materials ready and within easy reach. Place the culture tubes in the tin can(s) or racks. Light the lamp or torch. Sterilize the scalpel blade thoroughly in the flame, then place it on the stand. The stand can be fashioned from a wire coat hanger, a tin can, or from other appropriate household material. The object is to have a stable place to rest the handle such that the blade is suspended in the air near the flame to avoid contamination when not in use.
Start with a fresh, clean mushroom fruitbody. Although the outer surfaces of the fruitbody may harbor bacteria and mold spores, the internal tissue usually is free from contaminating organisms, assuming the mushroom is not waterlogged.
Tear or break off a section of the mushroom (do not cut with a knife, as the blade will introduce contaminants from the outer surface). Place the mushroom on the table with the clean surface facing sideways (not touching the tabletop). The object is to have one clean, exposed surface from which a very small piece of tissue may be extracted, and to keep that piece as pristine as possible while removing it to the culture tube.
Now you must organize your materials so that when the tube is opened, it is exposed for a minimal amount of time while you insert the piece of tissue. To decrease the probability of contamination, neither the tube nor the cap are allowed to rest on the table. This part is just a bit tricky. It is a good idea to practice the technique a few times with an empty tube before using real agar tubes and a mushroom. (The following assumes you are right-handed. Reverse directions if you're not.)
Position your left hand with thumb facing downward and fingers facing forward horizontally. Place the tube in your left hand between middle and ring finger, placing the ring finger on top of the tube and the middle finger underneath it, with the tube cap facing toward the inward direction. Always keep the tube positioned horizontally so particulates from the air cannot fall into the mouth of the tube. The slanted agar surface, on which you will place the mushroom tissue, should be facing upward. Carefully remove the cap from the tube and place it between the ring and pinkie fingers, sideways, with the pinkie on the top and the ring finger underneath. (See Figure 2).
Fig. 2
Fig. 2 -- A little tricky, but practice helps
Using the remaining index finger and thumb of the left hand, firmly grasp a piece of the mushroom with the clean surface facing upward or sideways. With the right hand, grasp the scalpel firmly by the handle as you would hold a pen or pencil. Starting with the tip of the scalpel, cut a very small triangular shape from the clean inner tissue. Gently "tease" the tissue free and quickly place it just inside the lip of the tube. If necessary, tap the scalpel to free the tissue. Return the scalpel to its holder, and quickly replace the cap.
Now tap the bottom of the tube a few times on the heel of your hand to position the mushroom tissue on the surface of the agar (See Figure 3.) Place the tube in a second storage can.
Fig. 3
Fig. 3 -- Move by tapping
Voila! There is a very good chance you now have a pure tissue culture.
Repeat these steps for the remaining tubes and mushroom material. It is important to make several tubes from each mushroom specimen, since even with the most careful technique contamination can sometimes occur.
Between each tube inoculation, re-sterilize the scalpel or knife blade in the flame, and tear off a fresh piece of the mushroom exposing yet another clean tissue surface.
When finished with all of the tubes, tighten the caps, and tape each on the area where the tube meets the cap with micro-porous tape. Micro-porous tape allows the culture to "breathe" but prevents contaminants from entering the tube. Label the tubes with the date and contents using a permanent marker such as a Sharpie™ or use a small mailing label.
Finally, place the newly inoculated tubes in a low light location with moderate temperature (55 - 70 degrees F. is fine). In a few days to a week, the inoculated tissue will become "fuzzy" as the mycelium begins to grow. After several weeks, mycelium will completely cover the agar surface.
If you see mold (usually detected by its green, black or other colored spores) or bacteria (usually colored slimy material), you should discard the culture immediately and clean the tube and cap thoroughly with hot, soapy water. If possible, empty the contaminated tube in a location as far away from your other cultures as possible. For example, carry it straight outdoors to the garbage can. You may use a chopstick or other long thin tool to loosen the media; it should then slide out in one or a number of pieces.

Phase II: Sterile Transfer Techniques and Grain Spawn

Sterile transfer to multiply agar tubes

Your agar tube containing mushroom mycelium is your "master culture." If you want to replicate the culture to increase your supply or to share with other cultivators, you should transfer the material from one tube into many tubes. This may be accomplished using the same process as during the initial sterile transfer described above.
Instead of using a piece of tissue from a fruitbody, however, substitute a tiny piece of agar containing mycelium from the master tube. The transfer is made using a scalpel or another appropriate tool such as an inoculation loop, which can be purchased or easily made using a piece of thin wire attached to some sort of handle. (See Figure 4.)
Fig. 4
Fig. 4 -- A simple tool
Again, be sure to sterilize the tool between each inoculation and minimize the amount of time the cap is off each tube. With a little practice, these transfers can be made quickly and with excellent success.

Sterile transfer to grain to create spawn

The next step in the cultivation process is to increase culture size by growing it on grain, often known as "grain spawn." Mushroom cultures grown on grain are easily proliferated by shaking and, as you will see, easily transferred by pouring from one container to another. As an example, one bottle of grain spawn can be used to inoculate many gallons of the final substrate. Grain is fairly inexpensive and readily available at health and animal feed stores.
It is readily colonized by many saprophytes, including Pleurotus species (Oyster mushrooms) and Agaricus species (button mushrooms and their relatives).
Here are two equally viable methods. The first uses 12 or 28 oz. beer, water or soft drink bottles and wheat, although rye can be substituted. The second uses canning jars and wild bird seed. Although wheat, rye or bird seed can be used with either type of container, the two methods produce slightly different results. Experiment to see which works best for you.
The primary advantage of the bottles is that the opening is smaller, thus decreasing the chance of contamination during inoculation. That advantage can later be a disadvantage: It can be more difficult to remove the material from the bottles.
If you have, or later obtain, a laminar flow hood with a HEPA filter which minimizes contamination problems, canning jars are recommended because they are easier to work with. If you are careful, however, you can have good success using either technique, even without the hood. (See Figure 5.)
Fig. 5
Fig. 5 -- Two ways to create spawn
    Materials needed for both methods:
  • A pressure cooker large enough to contain the bottles or jars
  • Aluminum foil
  • Grain (wheat, rye, millet or sorghum) or wild bird seed

Preparing Grain, Method No. 1

    Materials Needed
  • Clear 12 oz. or 28 oz. beer, water or soft drink bottles
  • Rolled cotton or cotton or polyester fiberfill such as pillow stuffing
  • Grain (wheat, rye, millet or sorghum) or wild bird seed Recipe for 12 oz. bottle:
  • 1/3 level cup wheat or other grain
  • 1/4 cup water Recipe for 28 oz bottle:
  • 1 level cup wheat
  • 2/3 cup water

Guidelines for grain and bottles

An important consideration when preparing grain is that it will roughly double in volume when cooked or sterilized. A rule of thumb is to fill a container only one third full with dry grain. If using bottles, a breathable plug closure can be fashioned from rolled cotton (available at pharmacies) or polyester/fiberfill material (at fabric stores).

Cooking/Sterilizing

Grain can be cooked/sterilized in either one or two steps. The two step process produces a very uniform product, but if time is limited, cooking and sterilizing can be done simultaneously.

Two Step Process

After the bottles are loaded with grain and water, place them in the pressure cooker and cover with a sheet of aluminum foil. The foil will help to prevent the filter plugs from getting wet from condensate. Cook the grain in the pressure cooker by bringing the pressure up to 15 psi for seven minutes. Let the pressure cooker cool and use oven mitts to shake the hot bottles so that wet and dry grain is mixed. Place the containers back in the pressure cooker and sterilize by cooking at 15 psi for 45 minutes. Do not count the time required to bring the pressure cooker up to pressure. Then let the pressure cooker cool slowly.
Remove the bottles and shake once again to mix the grain. Cover the filter plugs with a paper dust shield. The will help prevent contamination. Store the bottles in a dust-free box or cabinet. Since the grain will gradually dry out over time, avoid making cultures too far in advance of your needs.

One step process

Proceed as above, but simply cook for 45 minutes at 15 psi. After the pressure cooker has cooled, but while the bottles are still hot, use oven mitts to shake the bottles to mix wet and relatively dry grain.
Well-prepared grain is plump and shakes readily with a soft "ring." Overcooked grain prepared with too much water will often rupture. Then the starchy contents cause clumping, making it difficult to shake. Grain prepared with too little water will be flinty, shriveled and unsuitable for mycelial growth.

Spawn Method No. 2

    Materials needed:
  • Pint or quart sized canning jars
  • Micro-porous filters fitting inside canning jar lid ring (Mycological supply or homemade)
  • Aluminum foil
  • Paint strainer bags (from hardware or paint store)

Grain preparation

Measure one jar of grain for every three jars you will prepare into a paint strainer bag until the bag is half full. Use more bags as needed, keeping in mind that you can only cook as many jars at once as you have room for in the available pressure cooker(s). Tie the bag closed with twine, place in a large pot or the pressure cooker bottom (setting the lid aside), fill with water until just covering the grain, and boil for 30 minutes. Remove into the sink and rinse for a few minutes in cool water. This will remove some of the released starch so the grain will not stick together as readily.
Let drain for a few minutes. While draining, insert the canning jar lid filters into the lid rings. The filters may be obtained commercially (see sources at the end of this article), or may be cut out of appropriate fabric, such as a stiff, heavy polyester to fit the lid ring. Instead of using a filter, you may invert the disk that comes with the lid to provide for a small amount of air exchange, but the filtering capability of this method is questionable and a greater possibility of contamination may result. In the long-run, the commercially available filters or handmade filters are re-usable and probably worth the investment.

Cooking/Sterilizing

Untie the bag and fill the jars with grain. The jars should be 1/2 to 2/3 full. Place the lids with filters on the jars and seal loosely. Pressure cookers generally have some sort of rack to hold the jars away from the bottom of the cooker. Add water to the cooker so that it almost reaches the bottom of the jars when they are placed on the rack. (There should be at least a couple inches of water.)
Load the pressure cooker with the jars. Please see the manufacturer's instructions for the pressure cooker and observe all safety guidelines. Bring the cooker up to 15 psi (250 degrees F.) and maintain that pressure/temperature for 2-1/2 hours. Turn off heat and let cool for 30 minutes. Carefully remove jars from cooker, using a clean potholder or oven mitt if the jars are still too hot to handle. Tighten the lids and cover with a small square of aluminum foil. Shake the jars vigorously to ensure that the grain is not sticking or clumping. Store in a clean, dust free location until ready to use.

Grain Amenities

For some mushrooms, the acidity of the media, as measured by Ph, can influence growth. Acidity can be adjusted by adding 1 tbsp of ground limestone (CaCO3) to a gallon of water and using the latter to mix with the grain. Limestone may be purchased at a garden supply store (it's sometimes called "agricultural lime"). Agaricus bisporous (the button or Portobello mushroom) is an example of a species that benefits from adding CaCO3 to the grain. For more information on the requirements of various species, consult a cultivation guide such as Paul Stamets' The Mushroom Cultivator (see "Sources" at the end of this article).

Transfer of agar culture to grain bottle or jar

One agar culture tube will inoculate several spawn bottles or jars, since only a tiny piece of mycelium is required for each jar. Generally you will follow the same sterile technique described for Phase 1. Again, have all of your materials and equipment in place before you begin, and practice the technique with empty jars and tubes until you are comfortable and can work quickly.
When working with grain bottles or jars it is helpful to have a cradle to hold the bottle or jar in a horizontal position while making transfers. This frees the hands for removing and replacing lids. A cradle can easily be fashioned from a quart or half-gallon milk carton by cutting appropriate-sized notches in it.
After you've removed the cap and lid of the agar tube and of the bottle or jar, use your inoculation loop (Figure 4) to cut a small piece of mycelium from the agar. Place it just inside the jar and close both lids. Lastly, tap the jar against the heel of the hand until the mycelium is positioned on the grain.
Be sure to sterilize your inoculation loop in the flame between each inoculation, and to keep both tube and jar in a horizontal position at all times to prevent airborne particulates from entering.
Once the jars have been inoculated, date and label their contents using a permanent marker, such as a Sharpie, or use a small paper mailing label. You may also want to mark an arrow on the container closest to where the mycelium has been placed in the jar for further monitoring, as sometimes it is difficult to see until it begins to grow. As the mycelium begins to grow through the grain, periodically shake the container to speed colonization and to prevent the grain from clumping into a thick mass. The mycelium of mushrooms like Oysters and Agaricus grows well at room temperature. Once a grain culture is fully colonized, it can be stored in a refrigerator to maintain its viability.

Phase III: Final Substrate and Induction of Fruiting

In the third and final phase of mushroom cultivation, culture size is increased again, but usually on a different substrate than grain, and environmental conditions are manipulated to stimulate fruiting. The choice of a fruiting substrate will vary, depending on the mushroom species. Here we will describe the substrate and conditions necessary to fruit Pleurotus species (Oyster mushrooms).
Oyster mushrooms are an excellent choice for the beginning cultivator as the mycelium grows quickly, competes aggressively with undesirable organisms, and fruits readily under a relatively wide range of conditions. Also, there are numerous varieties available in a rainbow of colors including white, brown, pink and yellow, and they are available from food stores or via mail order suppliers.

Fruiting Substrates

Oyster mushrooms can be fruited on a variety of materials, e.g. hardwood logs, straw, sawdust, corncobs, shredded newspaper, etc. Avoid sawdust and chips from softwood trees such as pine, as these inhibit the growth of Oyster mushroom mycelium. Substrate for growing Oyster mushrooms can be obtained from pet stores and feed stores where you can buy bales of straw or bedding material like aspen shavings. Lumberyards that saw hardwoods and tree-trimming companies are also good sources of growing material. Use your observation skills and creativity.

Preparing the substrate

Oyster mushrooms can be grown on a pasteurized substrate, which is easier to prepare and less expensive than sterile media. The purpose of pasteurization is to leach out soluble compounds that might attract competing molds, and to kill insect pests. A simple method for preparing pasteurized chopped straw or similar material is to soak it in steaming water for about 30 minutes, then drain and cool it. The moisture content will be about right when a squeezed handful just barely produces droplets of water between the fingers.
For larger quantities of substrate, or for logs, a 55-gallon metal barrel or drum may be placed on an outdoor type propane stove or burner. Filled with substrate and covered with water, it is brought to a boil and boiled for 30 or 45 minutes. The material is then strained (a homemade strainer is fitted inside the barrel before filling, made from wire mesh secured from a hardware store). Alternatively, fill paint strainer bags 1/2 full with the substrate, tie with twine, fill the barrel 1/2 or 3/4 full with these, add water and boil as described above.

Culture Size and containers

Fruiting cultures can be of any size, but hobbyists would be wise to start small in order to perfect their technique. A half gallon milk carton lined with a plastic bag is a convenient hobby-sized culture. Another alternative is to purchase sleeves of clear plastic food containers and lids from a restaurant supply store. These are inexpensive, sturdy, easy to transport, and offer good viewing of the culture's progress.

Enriching the substrate

Yields can be improved by adding rich food sources like coffee grounds, cotton meal, rice bran, etc. However, these should be used with caution since they increase the likelihood of contamination. Typically these materials are added after initial spawn run, i.e. after the culture has already been fully colonized, to avoid contamination. Try using a chopstick to make small tunnels in the colonized mycelium from the top, then pour in the pasteurized additive, possibly using a funnel. This will help the mycelium to colonize it quickly, minimizing the opportunity for contaminants to get to it first.

Spawning

The more grain spawn used to inoculate a fruiting culture the faster it will be colonized, the less likely it will become contaminated, and the sooner it will fruit. Because pasteurized cultures can become contaminated with molds and bacteria, it's best to err on the side of excess spawn when inoculating your first cultures. A spawning rate of one cup of inoculum to a half gallon of substrate works well.
Shake the grain bottle or jar well before opening. Pour the grain spawn across the surface of the substrate or, with clean hands, mix the substrate and spawn together in a tray and then place in a bag or container. Tie the plastic bag loosely with a twist-tie, or simply fold over. With plastic lids, poke small holes after a few days to allow air exchange. Store in a dust-free location, possibly laying some paper or plastic loosely across the top to prevent dust and contaminants from entering.
Most strains of Oyster mushroom, especially those used commercially, grow quickly between 65 and 75 degrees F. and don't require a lowering of temperature to fruit. During spawn run, cultures should be maintained in a high humidity environment with low levels of air exchange. Oyster mushroom mycelium can endure fairly high levels of CO2. A culture the size of a half gallon milk carton should be fully colonized in about three weeks when grown at 70 - 75 degrees F.

Fruiting

A culture normally will not fruit until the substrate has been fully colonized. Small aggregations or coralloid growths on the surface indicate that a culture is beginning to fruit. Although lowering the growing temperature is usually not required for fruiting, a small amount of indirect light is believed to be important.
For normal-shaped fruitingbodies, more air exchange is required than during spawn run, but high humidity must still be maintained. To achieve this condition, cultures are often kept in a plastic bag with holes for aeration or in a box or terrarium with a moistened tray of gravel. If using container and lid, once the mushrooms begin to "pin" (i.e., begin to form tiny masses resembling miniature fruitbodies), the lid may be removed, and then the aforementioned plastic bag with holes or a terrarium may be used to maintain humidity.
It can take as long as a week for an Oyster mushroom to grow from a pinhead to maturity depending on temperature and humidity. When the cap margin starts to turn up, the fruitingbody is past its prime, so by this point you ought to have either used it to start another series of culture, or to have eaten it for supper. (See Figure 6.)
Fig. 6
Fig. 6 -- Successful Fruiting

Where Do We Go From Here

Once you have become comfortable with the techniques and have had success with an easy-to-grow variety such as the Oyster mushroom, you may be inspired to try another species. Or perhaps your loved ones will have implored you to designate a "special" location in your home for your growing collection of fruiting mushrooms, cultures and associated paraphernalia. Perhaps you'd like to further your campaign against contaminants by investing in a laminar flow hood, or even building a lab, perhaps in an unused room or closet. Or perhaps you would like to explore the prospect of naturalizing some species in your garden or other outdoor habitat.
First of all, if there are cultivation classes and workshops offered in your area, I highly recommended that you try to attend them. The more exposure you have to the techniques and the more you commiserate with other cultivators at all levels, the more successful and rewarding your experiences will be. Your local mycological society may offer classes. It may even have a cultivation committee or at least a list of individuals interested in cultivation, with whom you can exchange ideas and from whom you may obtain information and advice.
If your local society doesn't offer classes, be sure to express your interest; there may be experienced members who would happily teach a class if sufficient interest were expressed. Or start a cultivation committee yourself!
At this point, if you haven't done so already, I recommend that you invest in a good cultivation guide such as The Mushroom Cultivator by Paul Stamets and J.S. Chilton (see "Sources"). You may also wish to order some cultures via mail from suppliers such as Fungi Perfecti or Western Biologicals (again, see "Sources") and those cultures will come with specific instructions. Of course, when you are comfortable with the techniques, you may also begin to experiment with varieties collected from your local area or grocery by taking tissue cultures or even by advancing to spore cultures.
Once you have experienced the joy of seeing those tiny little pinheads turn into beautiful fruiting mushrooms from your very own cultures, you will surely be changed. And that is truly when the adventure begins!

Mushroom Cultivation Sources

Mycological Supplies, Cultures, Kits and Growing Information

Lab Supplies and Media Ingredients

  • Online Auction Sites Such as "EBAY" (www.ebay.com). Search with keywords such as "laboratory," "test tubes," "pressure cooker," "HEPA filter," etc. General Services Administration
  • A government agency which sometimes liquidates material such as lab equipment. GSA offices are listed by region, and they have a mailing list to which you may subscribe for your region. Also available on the web at www.gsa.gov
  • Medical Supply companies. They are often willing to sell to the public and their prices are often quite reasonable. Good source of test tubes, scalpels, inoculation loops, as well as microscope slides, etc. For example, in San Rafael, Calif., Casad Surgical Supply, telephone 415-454-1236.
  • Chemical supply companies. May carry both lab supplies and media ingredients such as agar, dextrose, etc. For example, Chemicals for Research and Industry, telephone 510-893-8257.
  • Beer brewing suppliers. They carry media ingredients such as brewer's yeast.
  • Health food stores. May carry various media ingredients in bulk.
  • Hardware Stores. Source of pressure cookers, ground oyster shell (agricultural lime), gypsum, peat moss.
  • Nurseries. Source of agricultural lime, gypsum, peat moss.

Reference Books

  • The Mushroom Cultivator: A Practical Guide to Growing Mushrooms at Home, by Paul Stamets and J.S. Chilton, Agarikon Press. (Buy at the MykoWeb Bookstore.)
  • Growing Gourmet and Medicinal Mushrooms, by Paul Stamets, Ten Speed Press. (Buy at the MykoWeb Bookstore.)
  • Growing Wild Mushrooms, by Bob Harris, illustrated by Susan Neri, Wingbow Press.
  • Growing Mushrooms the Easy Way: Home Mushroom Cultivation with Hydrogen Peroxide, by R. Rush Wayne. web http://members.aol.com/PeroxyMan.
  • Mushrooms in the Garden, by Hellmut Steineck, Mad River Press.
  • Some of the above can be purchased from Fungi Perfecti (www.fungi.com). All can be found online at Amazon.com (www.amazon.com). Also try searching other booksellers and the web. Unfortunately, there are a limited number of titles on mushroom cultivation, and many are out of print. Used book stores may be able to help. Amazon.com claims to be able to search successfully for books out of print. Try the keywords "mushroom culture," "mushroom cultivation," "growing mushrooms," etc.

Cultivation Workshops and classes

Monday, December 12, 2016

It's a Winter Wonderland Out There

LOL November 18th I took a selfie of me cleaning up the garden, getting a sun tan with my shirt off.

Winter didn't waste any time showing up, with an awesome blanket of powder snow.

I took the cross country ski's out of the attic, I think it will be "a good year" for snow.







With 16 cords of red oak in the back yard, you expect a few mushrooms. This is a non-edible one, but good for dying fabrics. We are growing 4 types of mushrooms indoors, I'll do some pictures on that later.

Ferrocell Magnetism Invention






https://www.youtube.com/watch?v=bBy7NnbFyMY&spfreload=5




<iframe width="580" height="360" src="https://www.youtube.com/embed/bBy7NnbFyMY" frameborder="0" allowfullscreen></iframe>

Wednesday, December 7, 2016

Mushroom Cultivation and Natural Harvesting - Enoki

https://www.shroomery.org/9101/Flammulina-velutipes

The Japanese lead in popularizing this mushroom. In the wild, Flammulina velutipes is a short, furry footed mushroom. Usually cultured in chilled growing rooms, abnormally small caps and long stems are achieved by elevating carbon dioxide levels and limiting light exposure. This unnatural shape makes the harvesting of Enoki easy.
Mycelial Characteristics: White, longitudinally linear, becoming finely appressed and tinged light brown to spotted with golden yellow brown zones with age. The surface roughens, resembling fine sand paper, and sometimes becomes beaded at the earliest stage of primordia formation. Long stemmed, small capped mushrooms commonly form along the inside periphery of the petri dish or during cold storage of culture slants.
Microscopic Features: This mushroom produces white spores.
Suggested Agar Culture Media: Potato Dextrose Yeast Agar (PDYA), Malt Yeast Agar (MYA), Oatmeal Yeast Agar (OMA), or Dog Food Agar (DFA).
Spawn Media: Grain (rye, wheat, sorghum).
Substrate for Fruiting: A wide variety of hardwoods (oak, alder, poplar, cottonwood, aspen, willow, birch, beech, etc.), and some softwoods (Douglas Fur) although the latter is, in general, less productive. The pH range for fruiting falls between 5-6. Enokitake also grows on a wide variety of paper products.
Yield Potential: Biological effieiency rating to 150%, the preponderance of which is stem mass. If grown in 1 liter bottles, yields of 3-5 oz. are standard for the first flush.
---Growth Parameters---
Spawn Run:
  • Incubation Temperature: 70-75° F (21-24° C)
  • Relative Humidity: 95-100
  • Duration: 14-18 days
  • CO2: >5000 ppm
  • Fresh Air Exchanges: 0-1
  • Light Requirements: n/a
Primordia Formation:
  • Initiation Temperature: 45-50° (7-10° C)
  • Relative Humidity: 95-100
  • Duration: 3-5 days
  • CO2: 2000-4000 ppm (this is really high, natural air is around 400)
  • Fresh Air Exchanges: 2-4 per hour
  • Light Requirements: 100-200 lux
Fruitbody Development:
  • Temperature: 50-60* F (10-16* C)
  • Relative Humidity: 90-95
  • Duration: 3-5 days
  • CO2: 2000-4000 ppm
  • Fresh Air Exchanges: 2-4 per hour
  • Light Requirements: 100-200 lux.
Cropping Cycle:
  • Two to three crops, 10-12 days apart.
Comments: This mushroom is the classic example of the influences light and carhon dioxide have on fruitbody formation. Like Oyster mushrooms, this mushroom's appearance is contingent upon the environment in which it was grown. The growing room environment can be tuned to elicit the perfect crop. Over time, experienced growers can orchestrate flushes with precision and generate cluster-bouquets of golden mushrooms. Properly managed, each bundle achieves a remarkably similar weight.

Under outdoor conditions (moderate light/low CO2), this mushroom is short-stemmed with caps as wide as the stems are long. The lower regions of the stem develop a darkened fuzz, hence the common name "The Velvet Foot". Under the lighted, high carbon dioxide conditions, the stems greatly elongate and are yellow to white in color. The caps remain relatively small. While CO2 determines the length of the stem, light is an overriding factor in influencing the formation and development of the cap. Thus under high CO2 and no light conditions, thin stems may form usually without any caps. Most strains behave in this fashion but responses vary. Depending on the surrounding environment, the stems can be as short as 1 inch to as long as 12 inches. The cap to stem ratio varies from 1:1 to 1:100. This range in the shape of the fruitbody is remarkable.

The surface mycelium undergoes a radical transformation during the period of pre-primordia formation. The mycelium yellows, and then forms dingy, blemished brown and white zones, which soon evolve into a roughened, beaded surface. From this micro-landscape, a high population of minute, squat, yellow primordia emerge. The mushooms appear virtually stemless. If carbon dioxide levels are kept elevated, above 5,000 ppm., significant stem elongation continues. Japanese cultivators have invented the technique of fruiting in bottles that are topped with a cylindrical insert of clear plastic or paper. The cylinder pools carbon dioxide and the stems elongate. This technique encourages the formation of highly uniform flushes of mushrooms in each bottle.



Thursday, November 24, 2016

Camera Research, Canon 5D versus Canon 7D

I selected the 6D along with a EF 24-115mm 3.5 IS USM lens kit.

Then bought a used zoom from B&H --  70-300mm/4-5.6 IS USM lens

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Looking at an End of Year Purchase, maybe a black Friday purchase

The 5D is quite a bit more expensive than the 7D.    Is it worth it?

Can I use my existing lens'?

http://www.imaging-resource.com/cameras/canon/5d-mark-iii/vs/canon/7d-mark-ii/

https://www.bhphotovideo.com/c/product/1081808-REG/canon_9128b002_eos_7d_mark_ii.html






 


Saturday, November 19, 2016

Performance Modifications for Ford F150 5.4L Triton Engine

Just my notes...........



Steve’s Summary
Figure out what mods you are going to make before buying a tuner, since you may need to customize the tune based on the other mods.

1.       K&N Air Filter
2.       Throttle Body 80mm ( 10 to 15 HP) Performance Power-Plus throttle Body $320
3.       UnderDrive Pulleys (8 to 15HP, 12HP, more with Tuner)
4.       Electric Fans
5.       Headers, if doing at all, do long tube headers.
6.       Tuner - customizable

Not researched
Throttle body spacer
Tuner above, requires custom tunes created by “local tuner expert”
RE throttle body
wondering if the added horsepower/torque is moved up the rpm range? looking for more low end torque for towing.
Asked by: Greg - 10/25/2015
Customer AnswerWhen installed on its own, the throttle body does tend to skew horsepower and torque higher into the rpm range, though once you start throwing other modifications and tuning at your truck, the range tends to normalize. However, the best upgrades for low-end torque on the 5.4L F150s are long tube headers, a matching mid-pipe, and appropriate tuning.

Troyer Performance numbers for the following:

Pulleys: 11.8 HP with stock settings – 14 HP with a Superchips programmer. Don’t know the numbers but I would guess you’d see similar numbers with just about any programmer.

JBA Headers: 4.6L = 13 -15 HP, 5.4L = 14 – 17 HP

Cats: No numbers given but Troyer states that the Magnaflow cats they sell can support engines making over 800 HP. They also say that these cats cheaper ($$) than OEM.

Other items I am considering at some point down the road along with the above upgrades:

1) Y-pipe – kind’a complicated but would free the exhaust up even further with the headers and 3.0” cats. Probably should have this done in a muffler shop.

2) 75mm throttle body would also compliment the K&N FIPK intake.

Just my two cent everyone but would stay away from headers unless your putting on a major power adder. Stock exhausts are prettyy good and a swap is really just for the sound on a basically stock truck. Had a friend put shorties on a 01 5.4 and after he ran .1 better on a gtech. Tried it before and after.... not alot for the 500 bucks.

Long tub hoarders not shortys. Pacesetters are a good one to get, 1 3/4 tubing with 3" collector can get for around $250
Two things come to mind, first electric cooling fans and under drive pulleys. Now, for some plain general stuff, clean the MAF sensor, clean the throttle body assembly, use a good injector cleaner like "SeaFoam".
And, you could add a high flow air filter.
Postby Jorzech » Fri Jun 03, 2005 1:07 pm
Where is the best place to start looking for underdrive pulleys and e-fans? Do you guys think someone that isn't that good with vehicles can do either of those, or should I take it to a good mechanic?

Thanks for all the info everyone, this site kicks a**!!!!

Postby JBarx » Fri Jun 03, 2005 1:44 pm


While a cold air intake is nice, by far the mos effective power upgrade for your 2004 to 2008 F150 is PCM tuning, and we here at Stage 3 can provide tuners from some of the best names in the business, as well as even more potent custom tunes from 5-Star Tuning. A performance PCM tune works by changing key parameters of your truck's Powertrain Control Module, adjusting things like fuel curves, ignition timing, shift points, and other computer-controlled functions of your engine to help your truck get improved horsepower, torque, fuel economy, and transmission function all in one go. Most tuners come with fairly standard "canned" tunes that are pre-built for use with just about any truck that the tuner or monitor is hooked into. A custom tune is a whole different animal and is specifically programmed for use with your particular truck. Our custom tunes come from 5-Star Tuning, one of the leaders in F150 custom tuning, and their custom tunes can be built around both your preferred fuel octane and application to get you the perfect tune for your aggressive truck.

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The last of the "first" modifications is generally a cat-back exhaust kit. While a 2004 to 2008 F150 cat-back exhaust system generally won't give you much or a performance gain, they do give your V8-powered F150 a very impressive sound. We here at Stage 3 carry both single-exit and dual-exit cat-back kits for your truck, all of them from some of the biggest and best names in the performance exhaust industry. We have kits that can give your everything from a mellow purr to a ferocious roar so that you get the exact sound you want for your custom F150 build. We've even done an impressive amount of our own exhaust system testing on our 2004 Project truck. Check out the videos below:
2004 to 2008 F150 Lighting Components and Upgrades
If there's one thing we have plenty of for the 2004 to 2008 F150s, it's lighting parts, and these truck's respond remarkably well to a wide range of aftermarket lighting components. Our very own 2007 F150 Project truck is decked out with a complete Recon Smoked Lighting Package that consists of new headlights, taillights, and a third brake light that give your truck a total overhaul and makes an excellent platform for future lighting upgrades and other exterior accessories. If basic replacement lighting components still aren't cutting it for your late-night trail rides, then check out our impressive selection for Rigid Industries Off-Road LED lights and light bars. We have Rigid Dually Lights, D2 Lights, E-Series Light Bars, and SR-Series Light Bars all in different size and lens configurations to meet your truck's off-road lighting needs.

Lift Kits and Suspension Upgrades
Want to turn your 2004 to 2008 F150 into a brutal desert runner? How about a potent rock crawler? Or do you just want some extra ride height to fit on those 33" tires? Whatever your reason, we here at Stage 3 have you covered with a ton of lift and leveling kits from some of the best names in the business. Spacer Leveling kits are our most popular suspension modifications and get rid of your truck's front rake and let you squeeze on slightly larger wheel and tire combinations. Coilover Leveling Kits do the same thing, but also give your truck better off-road performance. For anything else, there's our selection of complete suspension lift kits. Lift kits are the go-to options for getting your truck higher in the air and fitting on truly massive wheels and tires. Our current lineup of trucks have all been graced by lift kits of some sort. Our 2005 F150 Project Truck has a Zone 4" Suspension Lift Kit, our 2004 F150 Project Truck has a Pro Comp 6" Suspension Lift Kit, and our 2007 F150 Project Truck has a Zone 6" Suspension Lift Kit. The end result on all of these trucks was nothing short of incredible, and the lift kits, wheels, and tires dramatically changed their looks for the better.
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