Inside Aloe Vera: The Compounds That Make (or Break) It

The compounds found in Aloe Vera are incredibly promising and appealing. It has been used for 6,000 years by ancient civilizations, well before science verified its healing potential. Alexander the Great conquered an entire aloe-rich island to help heal his soldiers' wounds. Ancient Egyptians gifted the plant at Pharaoh's funerals, coining it the "plant of immortality." Today, modern research is catching up with ancient wisdom, but most companies aren't doing the plant justice, mainly because they're using the wrong farming and extraction methods. To truly benefit from this ancient healer, you need to understand the bioactive properties that make it so special, why most products destroy them, and how the right process preserves their power.

Why Most Aloe Products Don't Work, And the Compounds That Actually Do

Aloe's key compounds—including acemannan, specific polysaccharides, and essential sugars are susceptible to heat and destabilization. Most facilities destroy the beneficial components before production even begins. It requires vertical integration and scientific expertise, from farm to extraction. It's an expensive and delicate process. 

We're not going to just praise aloe's benefits like every other article on the internet, because most products don't even contain the ingredients mentioned in clinical studies. We're going to explain how you can actually harness those benefits for yourself, with hard science as our guide. Research is limited, but innovative companies are breaking down aloe compound by compound to deliver its true benefits.

Background

There are over 420 species of aloe, but Aloe vera (Aloe barbadensis) is the one most praised by scientific studies. Originating from Africa, it has been used across ancient Greece, Rome, Babylonia, and China. Aloe's name is derived from the Latin word for "true" and the Arabic word for "shining bitter substance." This cactus-like plant is grown in hot, sub-tropical regions. It is used topically or orally for various conditions, ranging from skin health to immune support. Multiple studies have investigated the gel of the inner leaf and the latex of the outer leaf to understand their healing potential. 

Key Compounds & Benefits

Aloe vera's healing potential comes down to a handful of fragile compounds. If they're destroyed during farming or extraction, you'll never experience the benefits that ancient civilizations and modern science both point to. Let's break them down and show you how to actually harness them.

Acemannan

Acemannan is the star compound inside aloe vera — a long-chain polysaccharide unique to the plant. Think of it as aloe's "active engine." For it to actually work in the body, it needs to be present in long, stable chains weighing at least one million Daltons.

Why it matters

Acemannan acts like an aircraft carrier loaded with supplies—as your body calls for help, it releases essential groups that support metabolism, gene regulation, neurotransmission, wound healing, and immune balance. It has also been shown to boost fibroblast activity (skin repair) and endothelial health (nutrient absorption within your blood vessels). 

Why most products don't have it

Acemannan is incredibly fragile. Heat, harsh processing, or improper harvesting methods break its chains into useless fragments, typically just glucose. Even products that claim to have it often don't contain chains long or stable enough to deliver tangible benefits. Without those million-Dalton chains, you're not getting the compound studied in clinical research.

How to harness it

Acemannan can't be mass-produced with shortcuts. It requires hand selection of the right leaves, careful draining, and cold extraction to keep the chains intact. That's why almä processes aloe within six hours of harvesting and uses cold ethanol extraction methods, which preserve acemannan in its most bioavailable form.

LM Pectin

LM pectin (low-methoxyl pectin) is a naturally stable form of pectin in aloe vera. Most pectins require sugar to bind. LM pectin utilizes calcium, which your body already has in abundance. That makes it uniquely bioavailable without needing chemical modification.

Why it matters

LM pectin can lower blood lipid levels (linked to longer lifespan), bind heavy metals in the digestive tract to keep them from entering your bloodstream, and act as a potent prebiotic to feed healthy gut bacteria. It's also a powerful anti-inflammatory.

Why most products don't have it

Most commercial pectins are chemically modified (like citrus pectin), and aloe's natural LM pectin is usually destroyed by industrial processing. Heat, harsh solvents, and poor handling break down its structure, leaving little or none of its bioactive properties intact.

How to harness it

The only way to capture LM pectin in its natural state is through gentle processing that avoids heat and chemical modification. Alma's farm-to-lab integration preserves LM pectin straight from the leaf, just as nature intended.

Essential Sugars

Essential sugars (also called glyconutrients) are complex sugar molecules like glycosyl residues and monosaccharides. Remarkably, aloe vera is the only known plant source that contains the full spectrum of these sugars. The only other place we see them naturally is in human breast milk. Each sugar plays its own role in how cells communicate and function.

Why they matter

These sugars are critical for cell-to-cell recognition and signaling. For example, if you cut your leg, they help your body send repair signals to the wound. They also support balanced immunity (neither too high nor too low), tissue repair, and healthy inflammatory responses. Additionally, they feed your gut microbiome, aid digestion, and upregulate detoxification pathways.

Why most products don't have them

The challenge is stability. Essential sugars exist as long chains, but standard aloe processing methods—heat, mechanical stress, and chemicals—break those chains down into simple glucose. Studies suggest up to two-thirds of these sugars are lost in typical commercial aloe extracts, leaving you with nothing more than plain sugar water.

How to harness them

To preserve essential sugars, aloe must be processed quickly and carefully before enzymatic breakdown begins. That's why almä extracts within six hours of harvest and operates its lab right next to the farm. This farm-to-lab approach keeps essential sugars intact.

Lab Testing - Proof of Potency

A combination of internal and external lab testing is the only way to confirm the presence of Aloe Vera compounds. When almä was third-party tested and compared to other products, the difference was shocking. almä's acemannan supplement was significantly higher than the comparison product, indicating that precise farming and extraction are indeed the key to benefiting from aloe's compounds. 

Internally, almä leaves no stone (or leaf) unturned. Every single batch is tested for acemannan and other science-backed properties. Unlike most companies that select samples and assume the rest is okay, almä tests every single batch multiple times to obtain a larger, statistically significant sample size. This approach enables the verification of each batch with confidence and allows for retesting the same batch multiple times. Samples are also reserved from every batch, allowing future retesting to verify consistency. By working in small batches and testing them thoroughly, the likelihood of errors is significantly minimized, far exceeding typical industry practice, and ensuring consistent results across all stages of production.

Why This Matters for You

When it comes to aloe vera, not all products are created equal. Ancient civilizations knew its power, modern science has explained why,  and Alma has proven how to preserve it. By protecting fragile compounds like acemannan, LM pectin, and essential sugars through precise, small-batch extraction, Alma ensures you don't just get aloe's name on a label, but its real, measurable benefits in every capsule.

 

Citations & Research Guide 

The following studies support the history, science, and bioactivity of Aloe vera. We encourage you to explore them directly and confirm the points covered in this article for yourself:

1. Martínez-Burgos WJ, et al. Aloe vera: From ancient knowledge to the patent and innovation landscape – A review. Industrial Crops & Products. 2022;182:114877.
   
2. Liu C, et al. Extraction, Purification, Structural Characteristics, Biological Activities and Pharmacological Applications of Acemannan, a Polysaccharide from Aloe vera: A Review. International Journal of Biological Macromolecules. 2019;124:423–432.
   
3. Hamman JH. Composition and applications of Aloe vera leaf gel. Molecules. 2008;13(8):1599–1616.
   
4. Zhang L, Tizard IR. Activation of a mouse macrophage cell line by acemannan: the major carbohydrate fraction from Aloe vera gel. Immunopharmacology. 1996;35(2):119–128.
   
5. Femenia A, et al. Compositional features of polysaccharides from Aloe vera (Aloe barbadensis Miller) plant tissues. Carbohydrate Polymers. 1999;39(2):109–117.
   
6. Acemannan: An Extracted Polysaccharide from Aloe vera – A Literature Review. ResearchGate.
   
7. Study on low methoxyl pectin (LMP) with varied molecular structures cross-linked with calcium inducing differences in the gel properties. ResearchGate.
   
8. Kudva P, Bhat G, Dodwad V. Aloe vera gel as an adjunctive treatment of periodontitis: a randomized controlled clinical trial. Journal of Periodontology. 2011;82(6):905–912.
   
9. An Assessment of the Glyconutrient Ambrotose™ on Immunity, Gut Health, and Safety in Men and Women: A Placebo-Controlled, Double-Blind, Randomized Clinical Trial. Nutrition Journal. 2013;12:145.