We’ve all heard social networks help us to be healthy and successful. It ends up that trees have been networking quite intimately for a very long time.


Tree networking takes two forms. They frequently share nutrients indirectly, using soil microorganisms as go-betweens. And they fuse their root systems in natural root grafts, called anastomoses.

How do roots graft?

Natural root grafts occur when relatively small roots of two different trees come into contact with each other. As they grow, they fuse, creating mutually accessible cambium layers and vascular bundles that allow them to share water, nutrients, and the products of photosynthesis. 


Why does this happen?

More than 150 plant species exhibit natural root grafts, according to researchers. There is debate about whether this occurs due to overcrowding or if plants purposefully graft their roots onto neighboring roots. There is also debate whether this action is beneficial or verging on parasitism. Most researchers lean toward the mutually beneficial explanation. Potatoes and strawberries frequently graft their roots onto neighboring plants of the same species. Surprisingly, some natural root grafts are between different species.

Benefits of natural root grafting

Natural root grafting provides several benefits to all parties involved. Those benefits include improved stability and water and nutrient sharing. These benefits help keep neighboring trees healthy, making them more resistant to wind and herbivore damage. In one study, trees with natural root grafts were found better able to recover from a spruce budworm attack.


Tree root grafting allows groups of trees to share water and nutrients. It also forces them to share soil-borne pests and diseases, such as Dutch elm disease and apple proliferation. 


For me, this is yet another example of the amazing processes going on underground. I was stunned to learn that plants can hear. I wonder what will be discovered next.

Plants respond to heat

When plants are hot and dry, they protect themselves by closing pores found on the underside of leaves. These stomata control the rate of gas exchanges used by plants in photosynthesis. This respiration can be slowed by as much as 50% during periods of extreme heat. Unless your plants are drunk.


Pints and plants

Recent research has found that many plants can thrive during drought if they are given ethanol. Ethanol is alcohol. It ends up that plants produce alcohol when they don’t have enough water. This fact led some researchers at the RIKEN Centre for Sustainable Resources Science to wonder if the same processes could be used to protect plants.


Alcohol abundant and cheap to make. Did you know that U.S. bars mark up their alcohol by an average of 400-500%? But back to the plants.


Researchers compared wheat and rice plants that had been treated with alcohol to those without. The plants were deprived of water for a couple of weeks in summer. Only 5% of the untreated plants recovered, while 75% of the alcohol-treated plants were able to resume growing once watered. Those are some significant numbers!


The scientists radio-tagged the alcohol so that they could see where it went within the plants. Plants that were given alcohol started behaving like they were in a drought even before the water was cut off. This helped them to be better prepared than their teetotaling brethren. Not only did they make better use of the water they had, but they also used the alcohol to create sugars to provide themselves with energy and perform more photosynthesis, even though their stomata were closed.


Now, this doesn’t mean you should go around giving your pumpkin plants shots of tequila. That would be a bad idea. What it does mean is that an occasional spilled beer might not be such a bad thing and we should all be on the lookout for more specific instructions as the research continues.

Bacterial soft rot destroys more crops than any other bacterial disease.


Commonly occurring in cruciferous, cucurbit, nightshade, and onion families, bacterial soft rot also causes severe pitting in carrots.

Symptoms of bacterial soft rot

Like other bacterial diseases, bacterial soft rot is easily overlooked at first. As the disease progresses, water spots start to form on soft tissues. Unlike the whitish splash marks left on old wooden furniture, these spots grow larger, softer, and start to sink. As interior tissues break down, these damaged areas may ooze and start changing color. Discolorations can range from cream to black. And they smell bad.


Bacterial soft rot management

Poor drainage, waterlogged soil, and insufficient airflow all set the stage for bacterial soft rot. Infected plants must be destroyed and removed. Prevention is worth the effort. The following good cultural practices can significantly reduce the likelihood of bacterial soft rot affecting your plants:

•  Use certified clean seeds and seedlings.
•  Quarantine and harden off new plants.
•  Install resistant varieties.
•  Plant at the appropriate times and correct depths.
•  Use recommended plant density.
•  Monitor plants regularly for signs of infection.
•  Provide adequate airflow through proper pruning.
•  Irrigate properly, allowing the soil to dry out between waterings.
•  Employ crop rotation to reduce overwintering bacteria.
•  Remove weeds.
•  Avoid working crops when they are wet.
•  Remove infected plants and dispose of them in the trash.
•  Clean and disinfect tools regularly.


If bacterial soft rot continues to be a problem in specific areas of your garden, use that space for plants that are generally not susceptible. That list includes beets, corn, and snap beans.

Aloe vera as medicine

There are more claims about the medicinal uses for aloe vera than I have room to list. As is usually the case, most of those claims are false. While we would all love simple answers to common problems, life rarely works that way. Claims that sound too good to be true generally end up being false.


The compounds found in aloe vera provide conflicting results. For example, one compound found in aloe vera, alprogen, reduces inflammation and allergic responses, while another component, acemannan, does the opposite. In 2002 aloe vera sap was banned as an OTC laxative by the US FDA. However, reports from the U.S. Department of Health and Human Services tell us that topical applications of aloe vera do provide the following benefits:

• Reduce acne after washing with soap and water.
• Alleviate pain and speed healing from burns and cuts.
• Ease herpes simplex, lichen planus, or psoriasis.

As for all the other claims, research is still ongoing. We will have to wait. While we wait, there’s no reason we can’t grow and enjoy these lovely burn treatments.


How to grow aloe vera

Aloe vera plants are easily grown from leaves taken from parent plants. Just pull off a leaf and stick it in moist soil. These plants take well to containers. Just be sure to allow the soil to dry out between waterings. Overwatering can kill an aloe vera. It can also attract fungus gnats. If you start seeing gnats, sprinkle crumbled mosquito dunk on top of the soil and water it in. The Bacillus thuringiensis bacteria found in these dunks kill fungus gnat larvae, along with mosquitoes.


Aside from the numerous false claims about what aloe vera can do, overwatering and poor drainage can result in several diseases, including aloe rust, anthracnose, bacterial soft rot, basal stem rot, fungal stem rot, leaf rot, and root rot. As always, aphids can turn up in your aloe plants.


Even though aloe vera can’t do all the things claimed in popular media, they are still attractive, useful, and easy plants. Every home should have one. And once you do, you can start taking leaves off and creating gifts for family and friends.

The fruit is a botanical berry and can become heavy enough to break branches, so supporting poles may be needed. The bark, leaves, and twigs of pawpaws contain natural insecticides (acetogenins) that keep most pests away. Fruit flies and whiteflies may still show up. Zebra swallowtail caterpillars love to feed on these trees, but this is generally not a problem for the trees or the caterpillars, and the toxins consumed provide natural protection against predators for the adult butterflies.


Caring for a papaya tree

Common diseases associated with papaya trees include anthracnose, black leafspot, papaya mosaic virus, phytophthora blight, and powdery mildew, along with the dreaded papaya ringspot virus.


Before you start working with a papaya tree, you need to know that the latex from unripe fruits can be extremely irritating. Many people learn the hard way that they are allergic. Sadly for those individuals, this latex is commonly used as a meat tenderizer.


Did you know that you can use papaya seeds as a pepper replacement? Now you know.

Apple proliferation might sound like a bumper crop of Granny Smiths, but it’s far more sinister than that. Sadly, I couldn’t find any images I could use.


Apple proliferation (AP) is a devastating plant disease that can result in crop losses of up to 80%. It is spread by apple proliferation phytoplasmas (Candidatus Phytoplasma mali). There are quarantines for this pest in Canada and the U.S. While AP mainly attacks apple trees, it also occurs on Asian and European pear, hazelnut, and plum trees, along with dahlias, hawthorns, magnolias, and roses.


What are phytoplasmas?

Phytoplasmas are a type of bacteria known as mollicutes. Mollicutes are unique in that they do not have cell walls. Instead, they have a multi-layered membrane. Phytoplasmas were discovered in 1967. Most phytoplasmas contain a single mysterious protein. Studying these 1 μm life forms has been difficult since no one has been able to grow them in a lab to date. For reference, the plastic wrap in your kitchen drawer is probably 10 μm thick.


How the disease spreads

Phloem-feeding insects such as cherry leafhoppers, planthoppers, and psyllids are responsible for spreading apple proliferation. AP can also spread through natural root grafting. Natural root grafting occurs when the roots of different trees end up pressed against each other. Over time, the vascular tissues of both root systems come into contact with each other and begin sharing nutrients. There is debate about whether or not this is a survival mechanism. We may explore that another time. For this discussion, those natural root grafts can spread disease.


Research has also demonstrated that infected trees emit unusually high amounts of a chemical that actively attracts psyllids, increasing the spread of disease to neighboring trees and shrubs.


Apple proliferation symptoms

Symptoms of apple proliferation change with the seasons because the phytoplasmas migrate within the tree. In the winter, they head south into the root system. As temperatures rise and the sap moves upward into twigs and leaves, so do the phytoplasmas.


Symptoms also vary depending on the species infected and how long the infection has been present. This condition may appear in only some branches. It may disappear altogether for a couple of years before returning. No one knows why, but it may be related to the fact that there are more and less virulent strains of this particular phytoplasma.


The most common symptoms of apple proliferation are small tasteless fruits with longer stems, witches’ broom, leaf rosettes, enlarged leaf stipules, shortened petioles, and dwarfism. Other, less common symptoms include increased suckering around the tree base, chlorosis, and downward leaf cupping. Leaves may also be smaller than normal and brittle. In autumn, the leaves of infected apple trees will turn red rather than yellow.


AP Management

There is no known cure for apple proliferation, so prevention is the only option. Infected trees must be removed and destroyed. Luckily, there are APP-resistant rootstocks, so look for that when tree shopping. And if apple proliferation is occurring in your region, do your best to control those psyllids and leafhoppers.


The adventure never ends.

Parasites make up more than half of Earth’s biodiversity. Like them or not, parasites serve important functions. Without them, evolutionary change would be reduced, and we would all be more vulnerable.


​And I’m grateful to whatever is parasitizing the aphids in my strawberry pots.

Characteristics of wind-pollinated plants

This is one of those cases where you don’t know what you have until it’s gone. Most plants invest a lot of energy and resources into attracting pollinators. They produce chemicals with enticing aromas, construct flashy, intricate flowers, and crank out sugary nectar. Anemophilous plants don’t need to go to all that trouble. Even the size and stickiness of pollen grains are reduced in wind-pollinated plants. The pollen of these plants is so small that it can be captured by a bee’s electrostatic field. [There’s a lot of it flying around at certain times of the year.] That is why honey can contain ragweed pollen even though honey bees generally do not visit ragweed flowers. Bees do visit corn tassels and other grains.


Structurally, these plants tend to have long, exposed stamens and feathery stigmas. These are used to dispense and collect pollen, respectively.


If you are allergic to pollen, it’s most likely pollen from anemophilous plants.

Pseudomonas isn’t all bad

As handy as it would be to say that all Pseudomonas are bad, it ends up that some of these soil bacteria help plants stay healthy. In fact, they practically make life possible on Earth. Life sure is messy, isn’t it?


Some Pseudomonas protect plant roots against disease-causing Fusarium fungi and Pythium oomycetes. They also protect against plant-eating nematodes. And other strains help activate disease resistance within wheat and other cereal crops. Some Pseudomonas can metabolize pollutants and are used in bioremediation.

Finally, Pseudomonas is also responsible for the formation of most of the snowflakes and raindrops that fall on Earth.


Now you know.

Bacterial blight is not the same thing as common bacterial blight, which attacks legumes. To make matters worse, many people call another bean variety of blight ‘bacterial blight’. I know, it gets confusing. Let’s see if we can clarify some of this.


The cause of bacterial blight

Bacterial blight, also known as blossom blight or shoot blight, is caused by a bacterium called Pseudomonas syringae. There are over 50 different strains of this bacteria that cause plant disease. Common examples include bacterial canker, bacterial speck, citrus blast, and halo blight. Pseudomonas syringae is commonly found on the exterior surfaces of healthy plants. It is only when bacteria get inside, through wounds or natural openings, that the trouble starts.


Bacterial blight symptoms

Like the other diseases caused by this pathogen, the first symptom is water-soaked areas on leaves. These areas turn brown and mushy and often have yellow halos. If these spots occur early in a leaf’s development, leaf curling and twisting may also occur. Leaves may also start dying from the outer edge, with the infection moving inward toward the center. Twigs may exhibit black streaks, and it is common for infected blossoms, branch tips, and leaves to die. If infected twigs develop a shepherd’s crook shape, it’s probably fireblight.


Managing bacterial blight

Pseudomonas syringae is most commonly spread by wind and rain. Insects and your garden tools can also be part of the problem. You have to assume that the disease is present. These bacteria can survive in diseased plants, infected plant debris, and soil.


Once a plant is infected, you can try to save it by trimming 10 to 12 inches below infected areas, making sure to disinfect your pruners between each cut. You can dip them in a 10% bleach solution for 30 seconds, though bleach is hard on tools. You can also use bathroom cleaner or other spray disinfectants that contain at least 70% alcohol. Just be sure to give it a few minutes to work before making another cut. Infected plant material should be bagged and thrown in the trash right away.


Prevention is easier. To prevent bacterial blight from taking hold in your landscape, use these tips:

• Start with resistant varieties.
• Space plants out enough that they get some good airflow.
• Feed and water plants appropriately to help them stay healthy.
• Avoid overhead watering
• Do not work around plants when they are wet.

Fixed copper sprays may also help.

To get the most out of your containerized fruit tree, you may want to get a fruit cocktail tree. These are trees that have different types of fruit grafted onto the branches. For example, a fruit cocktail stone fruit tree can produce apricots, nectarines, and peaches on the same tree. Or, you may select a 4-in-1 cherry tree with four different varieties of cherries growing on the same tree. It really helps make the most out of small spaces.

When shopping for rootstock, look for self-fruiting varieties, or you’ll need more than one tree to get fruit. Whichever tree you select, make sure that it is suited to your USDA Hardiness Zone. If you absolutely must have that dwarf lime (Zones 9-10) and you live in Grand Rapids, Minnesota (Zone 3a), you’ll have to bring it indoors for the winter, so make sure you have a plant stand with sturdy wheels. Or, you can keep it indoors and hand-pollinate. In either case, your potted fruit or nut tree will need at least 6 hours of sunlight each day.


Other factors to consider when selecting your potted tree are chill hours and local pests and diseases. One of the first things I noticed about Seattle when I arrived last summer was the number of plants affected by powdery mildew. And the few plants I put on my balcony were soon populated with stink bugs. (And I’m on the 7th floor!). Fruiting trees need a certain number of chill hours each winter to trigger fruit production in spring. As always, be sure to buy certified pest- and disease-free rootstock.


Caring for potted trees

Containerized plants need to be monitored regularly to make sure they don’t dry out too much in summer. You can encourage root growth by watering your potted tree from the bottom, rather than the top. Simply add water to the tray under your pot. The soil will absorb the water and the tree roots will extend downward to access that water. You will also need to feed your tree regularly.


So which tree am I going to get?

My balcony faces north and I live in Hardiness Zone 8b. Luckily, my balcony gets lots of sunlight and Seattle usually gets 3,000 chill hours each winter. My next step is to figure out which tree is least likely to attract or be affected by powdery mildew or stink bugs.


I found a website dedicated to thwarting invasive brown marmorated stink bugs (Stop BMSB) and learned that these pests love almond, apple, apricot, black walnut, cherry, fig, hazelnut, olive, peach, pear, pecan, and pistachio trees. They also feed on beans, cabbage, cayenne peppers, collards, cucumbers, horseradish, persimmons, soybeans, summer squash, sunflowers, and Swiss chard. Darn! It looks like my balcony garden is going to have a stink bug problem no matter what I grow! Luckily, fruit trees are mostly resistant to powdery mildew.


Based on where I live, the amount of sun exposure available, and all the rest, I think I am going to opt for a dwarf multi-variety cherry or plum tree for my balcony. Now if I could only find one that isn’t already sold out! Which tree are you going to plant?

Planthopper diet

Planthoppers are sap suckers. As they feed on practically all of your garden plants, they produce a sugary poop called honeydew. Sooty mold thrives on honeydew. So do ants. In fact, ants are known to tend planthopper larvae, protecting them from predators. The larvae of some planthopper species live underground and feed on plant roots or fungi.

​
Planthopper management

Planthoppers can be difficult to control because of their mobility. Many people recommend spraying them with a blast from the hose. I imagine this would take care of the nymphs who would be unable to return to their food supply, but I can’t imagine it would be very effective against adults. I could be wrong. Luckily, they are attracted to yellow sticky sheets. And predatory stink bugs feed on planthopper larvae.


Did you know that some planthopper species communicate with their neighbors through vibrations in plant stems? I didn’t either.

X disease is often mistaken for root rot. To figure out which it is, look closely at the graft union. That’s where the rootstock was grafted onto the fruiting stock. If it is X disease, you will see pits and grooves near the graft union. If you cut into the wood, you will see brown areas in the phloem. These other symptoms are also common:

• Chlorosis
• Purple leaf spots that create a “shot hole” effect
• Sparse leaf cover
• Tip dieback
• Upward leaf curling

The fruit from infected trees tends to be pale, pointed, small, and nasty tasting.


X disease hosts

There are two types of X disease hosts: those that don’t mind the infection (reservoir hosts) and those who succumb to the disease (non-reservoir hosts). Reservoir hosts are a problem because they look perfectly healthy, but they provide a source of infection to many important fruit and nut trees in our landscapes. Almonds, chokecherries, sweet and sour cherries, Japanese plums, clovers, and dandelions are all reservoir hosts. [Dandelions?!!? Yes, dandelions.]


Nectarines and peaches can also become infected with X disease, but they are non-reservoir hosts. This means that they can catch the disease but not spread it. Scientists don’t yet understand why that is, but they’re working on it.


X disease management

​Since scientists have been unable to reproduce the phytoplasmas responsible for X disease in the lab, there are currently no treatments for this fatal disease. To reduce the likelihood of X disease occurring in your landscape, do your best to manage the insect pests responsible for carrying the pathogen.


The insects responsible for spreading X disease are often found on beets, burclover, ceanothus, curly dock, hawthorn, and pyracantha. Because of this, it is a good idea to maintain some distance between these plants and vulnerable trees.


If you suspect X disease has infected one of your trees, it’s a good idea to get help. Contact your local Master Gardeners or Department of Agriculture for verification. They can also help you figure out the safe removal and disposal of any infected trees.

Here is a list of the many diseases that can be spread by cherry leafhoppers:

• Almond witches’ broom
• Apple proliferation
• Aster yellows
• Cherry X disease
• Eastern X disease
• Grapevine yellows
• Western X disease

They also leave collections of white crystalline frass on apples, pomegranates, and stone fruits.


Cherry leafhopper lifecycle

Leafhoppers lay their eggs in soft plant tissue where they are protected through the winter. Nymphs may also overwinter in tiny hideaways. Come spring, the eggs hatch, and nymphs go through several molts before reaching adulthood. These pests are most active during the hottest months of summer.


Leafhoppers are best managed with insecticidal soap.

Cherry crinkle symptoms

Vein clearing, especially in the margins, is the most common symptom of cherry crinkle. Vein clearing refers to the way veins look lighter or more yellow than normal. I wasn’t able to find a photo that I could use, but these other symptoms may also occur:

• Leaves are thinner.
• Leaves become more heavily serrated or irregular.
• Slot-shaped perforations may appear.
• Affected leaves often fold in half lengthwise, wilt, and drop in midsummer.
• Blisters may appear on the underside of leaf veins.
• Silvering may occur on upper leaf surfaces.
• Buds may be distorted.
• Flowers are abundant, but very little fruit develops.
• Fruits tend to be pointy and flattened on one side, with a pointed ridge.

Cherry crinkle management

If you suspect cherry crinkle, send a sample of soil to a lab for testing. This will tell you if your boron levels are low. It’s not a good idea to add nutrients without a soil test because too much of a nutrient can cause just as many if not more, problems as a nutrient deficiency.


If boron isn’t the problem, the tree is probably a mutant and should be replaced.


Cherry crinkle can be spread to unaffected trees by grafting mutated scions onto healthy wood. When shopping for a cherry tree, try to find one listed as unlikely to crinkle.

Aphid parasites are available commercially and are frequently used to control aphids in greenhouse environments. You can attract and maintain habitat for aphid parasites by planting clumps of rye or barley. These plants attract aphids, providing a long-term food source for your aphid parasites. You can also add the flowers mentioned earlier. Because aphid parasites can fly, they will regularly scan your garden for all sorts of aphids. You should start seeing aphid mummies 10 to 14 days after releasing these hunters into your garden.

Working with aphid midges

February may feel too early to consider aphids (unless you live in the Southern hemisphere). But it’s never too soon to learn how to help your garden plants stay healthy. As temperatures rise, you may want to buy aphid midge pupae to help in your fight against aphids. Pupae arrive in the mail in containers filled with moist vermiculite or peat. Depending on the temperature, pupae emerge as adults in 3–7 days. This is important. You’ll want to time your aphid midge release to coincide with newly emerging aphid populations. If you release them too early in the season, they’ll run low on food.


Before you squish another cluster of aphids, you may want to take a closer look to see if aphid midges aren’t already at work.

Preventing blackheart

To prevent blackheart from occurring, use these tips:

• Plant resistant varieties.
• Provide good drainage.
• Avoid overwatering and over-fertilizing.
• Do not harvest potatoes in extreme heat (above 86°F) or cold (below 35°F).
• Store harvested potatoes loosely in a cabinet, rather than tightly bagged or in the refrigerator.
• Store tomatoes in your pantry or on a countertop.

I hope the only blackhearts you have to deal with are the ones found in comic books.

Sometimes things look fine on the outside when the inside is damaged. This can happen to people. And it happens in beets, potatoes, seeds, and watermelons.


If you cut a beet, potato, seed, or watermelon in half and find the empty space in the center, it has hollow heart. Also known as hallowheart, this condition indicates that the plant faced more stress than it could handle. [The same might be said for people, but I digress.]

Sadly, this was the only licensable photo of hollow heart I could find.

Hollow heart of beets

If you cut into a beet and find an empty center, it’s time to get your soil tested. Hollow heart in beets is most commonly caused by a boron deficiency. If you look closely at the petioles, you will see that they are cracked, deformed, or smaller than normal. If the cavity is rotting, it may be black heart.


Hollow heart of potatoes

Hollow heart in potatoes is related to the water supply. And hollow heart is only one potato problem caused by irregular watering. Splitting and spraing (brown lines) are also water-related. Cold injury can also cause hollow heart in potatoes.

​Hollow heart in seeds

Garden peas and other seeds can also develop hollow heart. This occurs when unusually high temperatures occur right after germination begins. Because this disorder happens so early in the plants’ development, it leaves plants vulnerable to several fungal diseases. The best way to avoid hollow heart in peas and other seeds is to plant at the optimal time of year for each species.
 
Hallowheart of watermelons

Hollow heart in watermelons is mostly caused by insufficient pollen transfer. Poor pollination occurs when temperatures are low or when there are not enough pollinators in the area. Somehow, poor pollination causes the interior of a watermelon to develop triangular, often symmetrical gaps in the fruit. Seedless watermelons are more likely to develop hollow heart than seeded varieties, and orange and yellow-fleshed watermelons are the most likely to develop this condition. I have no idea why. What I do know is that you can attract more pollinators to your watermelon patch by adding flowers that appeal to both honey bees and bumblebees. You can offset low temperatures with row covers.
 

Hollow heart in watermelons can also occur when they are hit with too much fertilizer combined with not enough water, making the cells responsible for producing fruit unable to keep up with the cells producing rind.

​
Bottom line: a steady supply of water, planting at the appropriate time, and the right amount of nutrients can help prevent hollow heart from occurring in your garden.

Gardening helps us deal with that sense of helplessness because we have some level of control. There is little risk. Like a beloved pet, our garden plants accept us exactly as we are, without judgment. They don’t hurt us. Gardens offer the possibility of a better future, even if that future is nothing more than a germinating seed.

Spending time in a garden brings us back in touch with natural cycles. No matter what we have gone through, spring bulbs bloom, summer squash grows, and the seasons advance as they always do. This helps ease our natural fight/flight/freeze response. The sights, smells, textures, and sounds of a garden reassure us on a lizard-brain level.


The act of gardening resets us physically. Bending, pulling, breathing, reaching—blood flows to our brains, our muscles, helping us think more clearly and sleep more deeply. We are more in the moment when gardening. Time passes unnoticed. We are in the zone, in a flow state, fully engaged in the right now, experiencing ourselves doing something positive instead of experiencing pain and loss.


And these claims are not just my opinion. Recent research has demonstrated that gardening has powerful therapeutic effects. Known in the psychology world as horticulture therapy, caring for plants reconnects us with ourselves, our communities, and nature. It is believed that planting seeds and caring for plants parallels our healing. There is even a professional association dedicated to this type of therapy. According to the American Horticultural Therapy Association, “horticultural therapy helps improve memory, cognitive abilities, task initiation, language skills, and socialization. In physical rehabilitation, horticultural therapy can help strengthen muscles and improve coordination, balance, and endurance. In vocational horticultural therapy settings, people learn to work independently, problem solve, and follow directions.” Horticultural therapy is frequently used in prisons, mental hospitals, rehabilitation facilities and retirement homes to improve healing and recovery.


Building a healing garden

You may have nothing more than a window sill or balcony, like me. You may have a huge yard. Odds are, you’re probably somewhere in between. Whatever your starting point, how can you create a space that will help you through difficult times?


First, any act of gardening will be a step in the right direction. Second, there is no Right Answer when designing a garden to help you heal emotionally. Whatever helps you is the best design.


My healing garden design

This post was inspired by a garden design that popped into my head while writing my gardening as therapy post. Let me share it with you, if I may. Imagine standing on the edge of a space in a rage, distraught and exhausted. Ready to lash out or give up, your feelings are mirrored by the plants closest to you: sharp thorns, ominous colors, looming trees, darkly shaded nooks and crannies. And a hard, rigid path.


A few steps down that path, things begin to change. It's a little brighter, the colors are somewhat softer, and you hear a gentle rustle. The path becomes less rigid, and it beckons.