- Granting Systems- provincial and federal.
- Training & Education- BCIT & Kwantlen Polytechnic University for the Applied Sciences with agronomy & engineering
- Captilization with Lab/Farm and further R&D with basic research in the uni. with plans to automate and manufacture equipment or appliances with robotics as is already occurring to a limited extent
- Industrialization with investors or angels both private and also importantly public, managing certification through labour organizations or unions and promoting through public opinion for funding, use of technologies that are both sustainable (e. g. less global warming) and food secure, and public safety and the benefits of use in good and services of the industry.
- We have word of a contracting professional for building infrastructure; a co. to source in HI and CA USA for appliances and hardware (electronics), an aspiring young botanist heading for UBC (Point Grey, BC Canada), and business administrator steeped in computing science. Our current CEO/Principal is planning to write modules for training pracs to run the equipment (automated/semi-automated) (manually by hand) and accessory machine equipment.
Fields with Our Informational Enterprise in Botanical Aquaculture:
- Weed Science - phenolic extractives from plant-bearing sources and gasification (CH4) from fibre like wood pulp, alkaloids and pollination in weed science
- Agricultural Consulting - plse. write in; FYI available for you (14 research folios and counting)
- Aquatic Ecology - water hyacinthe, duckweed, Cryptocoryne (Araceae), marine grass spp. (including off-shore locally, not by vertical farming); as we speak there are developments already restoring intertidal habitats and their marine seagrasses- a potential resource to spp. types to use in seagrass farming enterprise.
- Zoology - salt water spp. of fish with brackish fishpond culture and aquamarine resources
- Botany - FYI available for you (e.g. seco-steroidal based pharma)
- Biosaline Agriculture - land-based hydroponics (submerged) with seawater or biosaline; these projects like reported salmon hatchery and farming off the tropical salt water seas off Arabia can also be further instituted in semi-arid countries in Arabia and C. Asia.
- International Development Research - livestock feeding systems (tropical ensilage or processing), co-ops in industry
Vertical Farming and Aquaponics in the Future.
Vertical farming is now believed to be transposable with current plans for submerged aquatic farming marine seagrasses in more conventionalized form using non-vertical linearilized trough systems only.
It presents as features advantages such as: 1) precision farmed or regulatable systems, 2) cost-cutting in terms of inputs, 3) much more efficient use of space or working area in the complex and 4) use of appliances and their materials that are manufacturably feasible.
It is known that vertical farming will be increasingly employed in more densified urban settings and whether it be in the use for biopharming, feedmaking, "green" bioenergy and for vegetable-cum-fish farming or intensive farming underground in retrofitted subway tunnels like the U. K. Underground in London, England.
Here is the promo released by the FAO-UN, Rome Italy, (click): (9) Post | Feed | LinkedIn.
The Horticultural Farming and the Dairy Industry.
To highlight dairy it is believed, that the horticultural trends with population growth as it mushrooms, possibly still true in future for Canada, will hasten the franchising of outlets for horticultural farming of new fodders or more common forage and will start to blot the landscape in a densified peri-urban and even in rural areas, like a 'whole dairy corporate operation' with its outlet sourcing to answer to the growing community demands for milk food products, and additionally, backyard and horticultural farming of 'fruit-n-veg' commodities running parallel in infrastructural facilities in the farming industry.
It is predicted that food concerns served by food banks will be fully capacitied to answer to them depending on the attendant labour costs, utilities and other energy-intensive inputs for farming. These can be funded through both federal-provincial granting and donations as a public trust. Their operations will be expected to answer to demands in innovation as 'greener' alternatives to technology that is increasingly becoming non-viable in their related industries, e. g. organic composting and vermiculture to help sustain and enhance soil fertility in horticulture.
The insider agri-retailers dealing with feedstocks, from seagrass for e. g., to dairy farming communities in B. C. are being goaded to transform (e. g. outputs then inputs to manufacturing of dairy food milk products), modify (e. g. make specific radical changes to animal and agronomic production with non-GMO technology, method and modality of distribution of the milk supply to sources of food manufacturing) and to move ahead food production into greater sustainability (viz. support and reliability) and food security (e. g. less commercial waste/food sharing, less disruptable food system- drought, wildfires, floods, severe cold, disease and pest control- and continuing accessibility to our consumers of B. C.).
Socio-Economic Trends: what progress?
Although movement could be further "left" in terms of progressive socialism in countries that are economically nonsustainable, nevertheless, we choose to improve efficiency, sustainability and regional security or assurance, and given the extreme demographic pressures present today, including immigration across borders. We also desire to move to better cooperativity evident of technological savy, practice of the free enterprising values and economic success, with efficiency as the ultimate goal (attested for by the Canadian experience). We believe we can conquer with this efficiency, leading to our healthier economic growth.
Genus Seagrass Project: West and Central Asia and the Philippines.
For more on our work on this topic click (or paste) this link: https://dannnnnnflores5@wixsite.com/genus. Further to research on marine grasses out at sea or in the mainland (inland areas) is the growth possibility of biosaline agriculture in marginalized lands requiring further development in rural and semi-rural areas which deserves attention in terms of balancing nutrition with growing population density and settlements with dairy farming using HQ fodders with hi-producing cows. Adapted to semi-arid areas and the weather including farm management needs will be required. E. g. s. we are approaching are the United Arab Emirates and Afghanistan, in West and Central Asian republics. Solar energy use will become critical, e. g. for heating/cooling and electrical/mechanical operations of the horticultural barns or shop areas.
Biokerosene. (Auto & Home and Aviation.)
Plant-derived suberins as starting material in cut rhizomes and off-shoots in seagrasses consist of polyaliphatics (bionol) residing in the cell membrane and cell wall while the polyaromatics reside in the cell wall alone where the tissues are ruptured and homogenized in a mouton grinder press and the homogenate under high pressure and temperature, with glycerol, pressure filtered in a poly-sintered filter reinforced to the perimeter; the solvent phase is separated out in aliphatic and aromatic fractions separated by distillation and reduced with reducing agent Bu3SnH; the alphatics are then cracked either: 1) thermally without catalyst under high temperature/pressure or 2) at lower temperature/pressure with catalyst into smaller molecules with zeolites or alumino-silicates to produced biokerosene - a mixture of C6-C16 molecules.
The other more significant industrial approach is to effectively polymerize subunits of ethanol molecules originally to precise length octanes (C-8) as bio-kerosene stopped time for the polymerization chain reaction over time within seconds in so-called torsion rotating mixing wells repetitively with stopping for collection of the resulting solvent product for avionics application. Fibre-bearing crops will be milled and fermented to ethanol preliminarily and then polymerized by the process including bagasse, wood pulp, marine seagrass, and agave (to be planted in the region around Zihuatanejo-Ixtapa, Guerrero State, Mexico and in the remedicated Sahel of the African continent and to be earmarked as traditional agave growing lands for Tequila manufacturing).
Goatary Farming (Caprine & Water Buffalo)
Dairy feeding requires high quality forages such as from seagrasses which have been fed from gathered areas in coastal beaches in the southern Indian subcontinent for generations. Pelleted concentrate can be fed in addition to ad lib feeding of forage composed of binder, copra meal:ground yellow corn (30:70), rice bran, crushed oyster shell and salt. It is open to conjecture at this point if SSF pre-treatments would serve the purpose of dried, ground seagrass residues into pelleted feeds from seagrassponics culture.
Dairy in the Philippines includes feeding harvested Napier grass as valuable long fibres of good quality and calls for further investigation of utilization of eco-friendly seagrasses in self-fertilizing fish pond culture in unimproved land and near coastal areas where land availability is not prohibitive. It should be noted also that spp. like duckweed and other Lilly can be used within estuarine settings used for regenerating or refreshing brackish waters a valuable tool in environmental remediation.
Genetic Breeding Strategies:
The ff. strategies will be used to develop the desired varieties that are viable for field production in seagrassponics:
1. Callus development and protoplast fusion approaches to develop the first hybrid varieties vis-a-vis: a) leaf vs. root area growth, this is the initial observation with hybrid variety for either leafiness or root mass as part of total C-sink capacity and fodder production growth rate; b) lignin quality vs. rate of growth, and; c) pest resistance vs. other qualities-albeit, in a biocontained and filtered environment.
2. X-ray (low-level ONLY) treatment to mutate and select out (i. e. breed) improved traits for leaf area, root area, lignification of crude fibre, growth rate (and other possible selectable traits) with back-crossing to stabilize the genetic background of new plant varieties.
3. Hi-throughput Bioinformatics to make GROs a reality will be engineered with Transcription Factors biocontained in a safe laboratory or pilot plant to introduce PNA-Auxin boosted genes, for e. g. bionol production, pharma production and various enhanced feed qualities such as low-lignin, hi-WSC, low-protease and hi-C-sink capacity.
4. Bio-containment of GRO varieties using biosafe facilities which are filtration and furnace serviced to destroy all bioactive material that may escape from plant.
5. Tufts and density are a major factor including vertical and horizontal growth in the growth medium as a matrix together with energy per cu. m. for lighting energy in photons in assessing the overall growth patterns of cultured seagrass.
Aquatic Fodders for Dairy Production.
Here is a SAMPLE of a description on deriving undifferentiated, proliferative cell calli, their transformation to protoplasts, their fusion based on paired up varieties to produce a desired cell type (upon inspection later), a one-step regeneration via somatic embryogenesis from diploid cells to whole plantlets under the right conditions, yet to be determined, then to be grown in agar-agar slant tubes under brine and with plant food added and also on agar-agar plates again under brine and under microscopic examination to manipulate cells, accordingly.
The Steps to Manipulate Cell for Regeneration are: (for review see: A. Feher. 2019. Callus, dedifferentiation, totipotency, somatic embryogenesis: what these terms mean in the era of molecular plant biology? Front Plant Sci 10: 536-552)
1. Make the explant from marine seagrass by harvesting one shoot of a plant from the sandy-loam seafloor and retransplant in the same soil type in a brine-filled bucket for 1-2 days before explant formation and storage in a near-shore pilot research lab; after storage cut an explant of stem tissue from that area of the plant and grow in an agar slant with plant food auxin and cytokinin (in equal ratios) to induce cell profileration for "calli" growth of undifferentiated cell mass in a test tube.
2. Transplant proliferating "calli" cells in agar-agar slants with brine and plant food over a few transfers and remove finally to agar-agar plates. Repeat for 1 and 2, of 2 varieties of marine seagrass species, that have varying characteristics as to root mass or leafiness/leaf area. Remember, store calli cells for further plant molecular biological study according to protocoled parameters before taking them out of storage for disposing.
3. Proceed with the protoplasmic fusion protocol on an agar-agar plate, removing the cell wall with zymogen treatment, and microscopically set the cells attempting to fuse them together with their plasma membrane on contact amongst these so-called "stem cells" of 2 different species and incubate further under microscopic examination to confirm the formation of cell fusants and then "coax" further to new undifferentiated, proliferated calli or cells (see: I. Takebe, G. Labib and G. Merchers. 1971. Regeneration of whole plants from isolated mesophyll protoplasts of tobacco. Nuturwissenschaften 58: 318-320.)
4. In one "single step" (see: D. Back-Husemann and J. Reinert. 1970. Embryobuilding durch isolierte Einzelzellen aus Gervebekulturen von Dauaus carota. Protoplasma 70: 49-60; F. C. Steward, P. V. Aminirato and M. O. Mapes. 1970. Growth and development of totipotent cells. Ann. Bot. 34: 761-787) regenerate the plantlets for regrowth using an experimentally definable protocol referred to as the phenomena of somatic embryogenesis. It is proposed eventually that at pilot-scale a so-called Occu-well (R) of agar-agar with a anchored membrane be used to raise them to fully grown plants with the plant roots in free-hold.
Study Trials with Aquatic Water Hyacinth: the following issues apparent with recent scientific studies.
1) Ensilage is required for feeding in response to proper: handling (mechanized such as harvesting and chopping); processing; storage, and preservation; and required feeding availability year round.
2) Mixture with grass silage at first is required although pure aquatic plant silage is palatable also after adaptation; this likely has to do with protein status, intake and protein rumen digestion.
3) Heavy soil contamination is a significant problem unless extensive washing of aquatic plants is carried out.
4) Screw pressing to reduce H2O before ensilage is required and run-off collected from silos is also required for palatability or acceptance. ~50% removal of water.
5) Additives as preservatives to improve quality of silage, viz. intake & palatability in part due to acidity and quality of preservation are, e. g. citrus pulp, cracked yellow corn or grain, sugarcane molasses and organic acids at 2-4% rate for palatability or acceptance; propionic/acetic acids (8:2) and formic acid are good preservatives. This relates directly to preservation of adequate protein content.
6) Species dependency (e. g. native dairy cows, steers, sheep) in palatability varies.
7) Grasses are not inferior or lower in digestibility necessarily; the opposite can in fact be true; paddy straw is compatible with feeding water hyacinthe.
8) Paddy straw and water hyacinthe silage supplemented for N (e. g. legumes, ground nut cake, fishmeal, rice bran, copra meal and corn meal) is a viable feed source for meat & dairy where feed resources are otherwise scarce; feed is high in carbohydrates.
9) Hyacinthe plants float while other aquatics are submerged. % CF content suggests plants are highly digestible.
10) Paddy straw + aquatic plants with sugarcane feeding regimes should be further investigated as a promising feed for dairy cows.
It is suggested that yeast bagasse with prebiotic MCP supplementation for protein peptides and amino acids and better supply of digestible carbohydrates (CHO) supplied from more digestible crude fibre (CF) from aquatic fodders for increasing ruminal digestion and bulk intake on feed be studied further for improvement in feed quality with sugarcane feeding.
11) Protein Digestion/Intake of DM or OM is dependent on: a) N supplementation with legumes, grains and byproduct feeds, or combining with other feeds, b) silage quality, e. g. additives and methods, c) supply of good quality, long fibres for rumen digestion, d) low %CF for higher digestibility.
Proto-Facility, Island of Vancouver, Canada: an aquaponics facility
A. Facility - set up nr. a closed ecologically protected area and well with stream or creek.
1) Mixing Room/Pump Room.
2) Analytical Room - detectors and data from regulators sent directly to head office and analytics; tower control for telecom communications sends in electronic programming and data to the facility's controlling minicomputer which is worked up after hours daily.
3) Prac Room - practice room online.
4) Instruction Room - learning resource area.
5) Workshop Training - simulated training and syllabus.
6) Locker Rooms - amenities for techies.
7) Shower Rooms - self-care and personal hygiene.
8) Lounge Area - relaxation and amusements.
9) Production Area - aquaculture and adjacent storage/processing room; sterile room or prep room for planting and set-up in each platform and may be semi-automated for speed and reproduciblity or less mistakes.
B. Feed Lines: no recovery of inputs needed despite cycling (c.) through the line; issue around recovery (r) is to save sizable dollars ($$)/d and 2) the magnitude of flushing the line and need for recoverying the flushed substrates (NB: v. sparging a reactor volume).
- c. O2/CO2 gases
- c. XL-Grow or PNA-Auxin/ARF biologic
- c. Micro/Macro Minerals
- c. Anti-microbials- biologic that's expensive required r./c
- c. Plant Food / Auxin or ARF
- c. N-P-K fertilizer
C. Equipment:
-intake pumps
-outpump
-aqua-blocs or chambers
-removable gasketed waterproof platform for tufted matured plants 12 x 12 x 24 level platforms
-elevator to move up and down and over top to aquaria-blocs to harvest and replace platforms (semi-automated and manual)
"Guestimates" for Plant Operations.
It is believed that two weigh-ins in the competition for cost-effectiveness are the ff. factors: 1) Tuft density per square decimeter, total tray number [on 14' (ft) total height per reinforced Nalgene(R) material] =(12) and 2) Chemical inputs (plant food formulations with N-P-K and pesticides) which are energy dense and costly, will determine the scale of production of the initial pilot plant. The next considerations are the parallel connected array of incubator vessels in no. (12 x 8) which will hopefully produce quarterly (/yr) based with some selected XL growth varieties to be used first of all as: 1) dairy fodders (maybe pelleted for better formulation, nutritive value and handling), 2) then if in future cellulose EtOH plants come into line it can be sold at a premium like bagasse to be not chemically treated but biologically or enzymatically processed prior to biofermentation and finally 3) nutraceutical and/or pharma applications in more expensive capitally invested enterprise with much greater added value but using GMO technology in pollen-free, bioscepted plants.
How big in area is big for a plant facility? Look around and you may find a dairy processing of food plant facility in kind, not so odd in a neighboring semi-rural setting or municipality - take a major agro-food area near the GVRD of Vancouver like Chilliwack - this might do like a Dairyland Foods(R) enfranchisement nearer the Vancouver area.
A shocking revelation: is there any more need for hay or all-year round ensilage of green herbage for fodders as a replacement. Is this true? Time may tell the story with us. Can I add, what about the spared resource land that is free? Fallowing in a system? Less fine chemicals expenditures and cost? More zoning problems ? - but of course we know the problems with that one: greenhouse gas emissions, immigration, open borders and overpopulation - the latter is a human right although not in legislated confines. I have a suggestion - veggie and fruit is our delight in our diet for better health so why not grow locally, and source as such!
Where's the marketing plan, you may ask? This is it.
Hydroponics: where are the nuts and bolts for the matter?
We will list in "parts and pieces" for your consideration here, so read on- and believe it or not there are suppliers alive and well including Hydrobuilders Inc.**, we heard about awhile ago headquartered in Chico, CA U.S.A. near Silicon Valley with a former acquaintance (unnamed) to our Principal in charge:
(1) Agar-agar Occuwells (R) - from SkyeBlue's author serving as anchors to rooting shoots in clump size of 40-50 stands which start as plantlets from undifferentiated calli cell culture after R&D development.
(2) Grow Trays & Stands - (built-in frame work) to "quick" charge (12-24 trays per incubator submerged chamber) the array stand filled to the top including addition of media and gases with LED lighting.
(3) Reservoirs and Tanks - Pool reservoirs with pumps for reserve or emergency and the tank incubator chambers submerged of trays all the way to the top.
(4) H2O Filtration and Treatment - Prep of salitre (saline) using filtered piped in marine water at the source pump and treatment at the source plant pump house for nutrients or growth media, pre-primed by staff, including dissolved guano (this has yet to be worked out in formula), buffers, plant food (growth factors), bio-pesticides, and gases.
(5) Water pumps / Airpumps - at source plant pump house to control parallel hooked up lines across chamber valved junctions [est. = 96 arrayed chambers or 12 x 4 x 2 (on either side across the divide)].
(6) Water heaters - at the pump house to incubate temperature similar to tropical climes (28-32 deg C).
(7) Fittings and tubings - to connect the networked reservoirs, priming pumps, incubator chambers and fail safe outvalves.
*All hydroponic operations are by classification capitally-intensive as opposed to open marine ponds by comparison.
**Hydrobuilder Inc., a well-known big box distributor of materials and equipment will be consulted later to see if developments warrant adaptation of the described listed materials of "parts and pieces" for use in submerged seagrassponic farming or culture. No doubt, much R&D is needed. Calling all botanists and agronomists, as we speak including postgrad students. We wish all well.
Seagrass Technology: Indoor Temperate or Outdoor Tropical Climes.
Little has been published on so-called: Seagrass Technology, with its great potential to be a dairy fodder source both intensively as well as in less intensive seagrass-fish pond culture, the development of a biosafe lab complex for varieties accelerated for growth, so-called XL varieties, and those GM varieties with "plant pharming" in mind as with hormones (e. g. insulin, hGH, hGRH), food nutraceuticals, enzymes, using secondary alkaloids to check mitotic spindle fibre function in the pollen sac to arrest any pollination during growth, an incubation housing physical plant or building with attached "boiler" room facilities, the incubation designed chambers themselves with trayed rafts and fitted with our proprietary Occu-wells(R) to allow free growth and stable anchoring of tufts of grass from plantlets.
The environmental control features include: heating, ventilation, humidifier, LED lighting covering 15-30,000 sq. ft. together with an attached prep lab for more advanced calli experiments and cell plant extraction and plant-raising situated near peri-urban farms for purposes of transportation to market of produce or product with our designation in dairy as so-called "ag retailers".
The outlay of the pilot plant will consist of 15 test chambers in a 3 X 5 configuration with a 5 in a row arrangement connected in parallel per row with lines running into them from the back and coming out from the front to drainage or recycle back through the reconditioner and filtration system inputs required being: our so-called Synthroid Guard (R), molecular interventives like PNA-Carriered Technology for gene silencing, soluble minerals, gases, buffers, plant growth promoters (including auxins) including soluble N-P-K from bat guano. At the incubator base are motored mixing rotors. There are flow regulators at junction points to direct circulation of growth media with foiled reflectors to maximize light irradiation, with an overflow pressure valve (positive) and tray rafter as much as 10-12 trays clipped or locked into place after front loaded installation; the Occu-wells(R) are based on open wells plugged with growth media agar-agar on the rafts and are "bouyant" allowing free hold on all growing tuft plantlets throughout their cycle; the heating system consists of heated copper coils, one-way valves, insulated hosing, and seals. Monitors utilizing electrodes or probes at the return collection point of the network and the input or intake valve point or junction will measure parameters such as temperature, pH, gases (CO2/O2) with microfiltration. There might be the option to use semi-automated probes with its feedback control using a computerized control function in the system with flow regulator or effector valves to maintain equilibrium at optimum for seagrass growth throughout their growing cycle.
The need for monitoring operational functions of the equipment and regulation of flow lines will ensure proper and continuous function although deconstruction in case of emergency can be carried out per each incubator cell or chamber by locking the input valve(s) with equilibrated flow to have drainage outflow in effect and the rafted trays removed rapidly and transferred to submerged tray holders for interventive protocols.
Use of green energy sources such as hydro, windpower and solar power are all alternatives we seek after to invest and lower costs in the long run through our own or the electrical grid.
For pond culture enthusiasts there will be a need to allocate or convert available paddy rice land depending on population pressures and agricultural use into hi-tech tarped lined paddy cells but battened down for minimizing debris in case of inclement weather disasters and topped or lined in effect with sanded clay loam previously fertilized by vermiculture and/or chicken or pig litter (stably humic in nature) pre-planted for tufted plantlets using submerged aquaponics in a greenhouse and populated with fish culture (like milkfish, or salmon) and fed regularly with fish food by sparging onto the water surface. As it stands the paddies as they are called are only used with non-manipulated varieties for dairy and meat plant fodders. These high quality feed products as fodders can serve idealy GRO hi-producing dairy cows or goats to support and at the same time maximize yield and with hi-bred meat livestock animals.
---------------------------------------------------
FYI Resources for Bioinformatics to Further Development of Aquatic Botanical Research: Recently taken from A. Faber's (of the Univ. of Western Australia (UWA), WA AU) Post on LinkedIn.com:
Shifting your attention between agro-life sciences to more molecular-level studies for research on seagrasses now, there is a young researcher in Australia (see: LinkedIn.com and Ms. Anna Faber) who has studied in the area of:
"Chemo-synthetic-based ecosystems" and her studies with epigenetics (cf. environmental factors and gene/expression and regulation) useful to creat a milieu and further advance TFs and TFE, for e. g. auxin/ARF expression systems, in our effort to obtain XL-Grow varieties of valuable hi-quality (HQ) seagrasses from Ocean marine environments, thinking of collaborative research. (Canada and Australian collaborative partnership have now arrived.)
Funding: Minderoo Foundation; NSERC/CRSNG(Canada); CHONe(Australia); other outside granting bodies with academia.
With issues on Oceans and Fisheries are addressed by Minderoo as: 1) global warming, plastics pollution, global warming and tech ecosystem- the latter a good chance to stab in the dark to get funding in regards to develop bioinformatics over seagrass DNA epigenetics such as with networking with the Digital Research Alliance of Canada and the University of Victoria in BC Canada..
University Institutions: U of Western Australia, U. of Montreal, U. of Victoria, The Hong Kong U. of Science and Technology.
Bioinformatics Resources: XL-GROW(TM) Varieties.
Organization: Digital Research Alliance of Canada for data gathering/databasing/bioinformatics computing.
OceanOmics Centre (Australia).
Oceanography, Fisheries, Marine Conservation Resources:
Organizations: DFO (Canada), National Oceanography Centre (Australia), see also - UNSW, Sydney (Australia) and Prof. Verges' research and funding.