Hygrophila polysperma

Common Name(s): East Indian hygrophila

Non-Native to Florida

Origin: India, Malaysia1
Introduction to Florida: 1950s (ornamental)2

Video ID segment (2-3 minutes / transcript below) | YouTube Link

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East Indian hygrophilaEast Indian hygrophilaEast Indian hygrophilaEast Indian hygrophilaEast Indian hygrophilaEast Indian hygrophila

East Indian hygrophila, Miramar weed, Indian swampweed, hygro
Acanthaceae/Water-Willow Family

pronounced: hi-gro-fi-lah po-lee-sperm-ah
from: hygro (G.): moist, wet
phil (G.): loving
poly (G.): many
sperm (G.): seed
“wet-loving plant with a fruit that contains many seeds (20-30)”

Justicia polysperma Roxb., Fl. Ind. 1:120. 1820.
Hemidelphis polysperma (Roxb.) Nees in Wall., Pl. Asiat. Rar. 3:30. 1832.

East Indian hygrophila is mostly submersed, with a few inches sometimes emersed above the water. East Indian hygrophila is not a native plant. It may be found in streams and in slowly moving waters.

Hygrophila stems are square. The submersed stems grow to six feet long. Its leaves are opposite on the stem. Leaves are 1 1/2 inch long and 1/2 inch wide. East Indian hygrophila flowers are bluish-white to white, and have two lips. They grow from the axils where the leaves meet the stems.



  • herbaceous perennial
  • amphibious, “obligate” (requiring a wet habitat)
  • in freshwaters, mostly submersed, partly emersed
  • growing from bottom to surface in water to 10 feet deep, or found creeping along edges
  • forming dense stands of stems in the water, later in the season breaking loose to form large floating mats
  • rarely, terrestrial growth form grows in moist soil (McCann)
  • flowering in fall and winter
  • reproduces asexually (regrows from plant fragments) and perhaps sexually (from seed), however Sutton (1996) says it’s unknown whether seeds play a major part in its spread
  • stems fragment easily and are able to develop new plants from small fragments; reportedly even a free-floating leaf can form a new plant



  • in warmer climates; preferring flowing streams, but also may be found in slow-moving waters and in lakes
  • temperature tolerance: minimum temperature, 4o C (39o F); optimum temperature, 22-28o C (71-82o F); maximum temperature, 30o C (86o F) (Kasselmann 1995)
  • best light intensity for hygrophila growth is around 110 micro-einsteins/meter squared/hour (Cobb and Haller, 1981) (what is light intensity of site under trees in warm weather?)
  • low light compensation and saturation points and low CO2 compensation point make it a competitive plant because it can start growing in low light before other plants do (Spencer & Bowes 1985, Bots et al. 1990 – from Angerstein 1994)
  • tolerates a range of pH and water hardness conditions


Hygrophila polysperma (Roxb.) T. Anderson
Original description: J. Linn. Soc., Bot. 9:426. 1876.

  • dicot
  • rooted in the hydro-soil
  • stems creeping ascendant (rarely erect); to 6 feet and longer; upper most emersed stems may be squarish; stems are brittle and easily break into fragments
  • leaves opposite (on the stem); simple; sparsely hairy; with pointed tips (acute)
  • leaf color variable, light green to brown to reddish
  • leaves submersed and emersed are more or less the same shape; mostly 1.5 in. long, .5 in. wide, but can be larger
    • emersed leaves elliptic to obovate-elliptic; having no leaf stalks (sessile)
    • submersed leaves larger and thinner than emersed leaves, broadly elliptic, broader toward tip; having short stalks
  • flowering in fall and winter (in Florida), October to early March (Sutton 1996)
  • flowers small, to 3/8 in. long, solitary, without stalks; found in leaf axils (angle where leaf meets the stem) in the apical (uppermost) parts of the emersed stems; corolla (petals) bluish-white to white, hairy, with two “lips”, upper lip 2-lobed, lower lip 3-lobed; calyx (leaves covering the bottom part of the flower) hairy with 5 equal lobes
  • rooting at stem nodes; many roots
  • fruit a narrow capsule 6-7 mm long; 20-30 tiny flattened-round seeds


Hygrophila polysperma with small, opposite-leaves, may sometimes be confused with submersed or partially submersed plants such as:

alligator weed in water flowering alligator weed

non-native alligator weed (Alternanthera philoxeroides): alligator weed has largish white papery flowers which are totally different

underneath, red ludwigia leaves from above, red ludwigia leaves

native red ludwigia (Ludwigia repens): red ludwigia has yellow flowers with 4 petals (however the petals fall off quickly, so they are rarely seen); purple pigment throughout, especially in submersed leaves; blunt leaf tips

native lake hygrophila (Hygrophila costata (H. lacustris)): lake hygrophila is entirely emersed or terrestrial; much larger and taller (to 80 cm); mostly erect; much larger leaves; flowers along the entire stem (rather than just at the top).



  • there are about 100 species of Hygrophila in the world (Sutton says 80; Wasshausen says 25 (per Sutton)), mostly terrestrial, mainly tropical
  • only three Hygrophila species occur in the U.S. – native H. costata and non-natives H. polysperma and H. corymbosa.
  • Hygrophila polysperma is said to be native to the East Indies (Les and Wunderlin 1981); India (Rataj and Horeman 1977); India and Malaysia (Angerstein 1994); Taiwan (Lee et al. 1988)
  • in India, its seeds are said to be used as a medication (Baveja 1974 — from Bowes 1982)


Distribution in the U.S.

Hygrophila polysperma is naturalized in many regions of Florida and in south central Texas. The best way to track the spread of invasive aquatic plants may be to identify the drainage basins (watersheds) they have been discovered in. Drainage maps give useful information to eco-managers because drainage maps show precisely where the plants are, making it easier for managers to infer where the plants might go next, and thus where to take preventive measures.


How it got here

  • Hygrophila polysperma was brought to the U.S. as an aquarium plant about 1945 as “oriental ludwigia” (Innes 1947);
  • was cultivated in Ohio at the end of WWII by aquarium dealer (Reams 1953);
  • was first found in Florida near Tampa in 1965, but not correctly identified till 1977 (Les and Wunderlin 1981);
  • was first reported as a weed problem in south Florida canals in 1980;
  • and had spread to 18 Florida public water bodies by 1994.
  • Hygrophila polysperma continues to be sold through aquarium supply dealers and over the Internet, even though the plant is on the U.S. Federal Noxious Weed List.


Potential to spread elsewhere in U.S.

There is no information in the scientific literature as to the potential for Hygrophila polysperma to spread in the U.S.



  • Hygrophila polysperma is a fast-growing and fast-spreading invasive that can outshade and therefore outcompete other submersed plants; it can occupy the entire water column; many adventitious roots at stem nodes means that fragments can easily grow.
  • Hygrophila polysperma clogs irrigation and flood-control canals; in south Florida, large mats of fragments collect at culverts and interfere with essential water control pumping stations; it interferes with navigation; and it’s even able to compete with another aggressive non-native invasive plant, hydrilla, and is replacing hydrilla in some Florida locations.
  • Hygrophila reportedly grew on Lake Tohopekaliga (Florida) from 0.1 acre in 1979 to 10 acres in 1980 (MITRE).



Hygrophila polysperma is difficult to control:

aquatic plant harvesting machine
aquatic plant chopping machine

the action of mechanical harvestors and chopping machines fragment the hygrophila plants and increase their distribution

grass carp, herbivorous fish

the herbivorous (plant-eating) biological control fish, the Chinese grass carp, have a low preference for hygrophila (Cassani); triploid grass carp reportedly were “used successfully in canals to control hygrophila” (Ferriter et al. in Simberloff 1997, p. 319); no other biological control work has been done for this species (Pemberton, 1996).

man applies aquatic herbicide
helicopter applies aquatic herbicide

registered aquatic herbicides provide only marginal control of hygrophila; hygrophila is relatively resistant to herbicides that control hydrilla (Vanadiver 1980; Sutton 1996); hygrophila is much more difficult to control with herbicides than is hydrilla, and requires higher rates of herbicides (Hall and Vandiver, 1990); treatments using copper plus Reward herbicides combined showed little effect on this plant in Florida canals 4 weeks after application (Sutton 1996)

From the University of Florida Aquatic Weed Management Guide, Vandiver 1999:

    According to this Guide, the only herbicide labelled to be used against hygrophila is “Aquathol Super K Granular Aquatic Herbicide”, having the active ingredient, “endothall”. This herbicide is labelled to be legally used in Florida canals, drainage ditches, lakes, ponds, reservoirs, rivers and streams. It is unknown at this time to this author whether this herbicide may legally be used against hygrophila in other states. As always, comply with federal law by following the herbicide label instructions, permissible sites and application rates.


What can you do?

First, clean your boat before you leave the ramp! Transporting plant fragments on boats, trailers, and in livewells is the main introduction route to new lakes and rivers.

But, there’s plenty more you can do to help.


Laws and lists

Hygrophila polysperma

  • is “state-listed” only by Florida
    • is on the Florida Prohibited Plants list, Florida Department of Environmental
      • Category II – “may be cultured in Florida for out-of-state sales, but may not be imported or
        collected from wild”
  • is on the Federal List of Noxious Weeds (USDA/APHIS, 2000)
  • is on the Florida Exotic Pest Plant Council list:
    • Category I – “plants invading and disrupting native plant communities in Florida”


Want to know more?

The information contained on this wep page was extracted from published scientific literature and agency reports. It is important to know that plant research, like most areas of scientific research, is still relatively young and incomplete–much may have been published about the physiology of one plant but not about its management; much may have been published about how to culture and grow another plant but not about its natural ecology. Thousands of research articles may have been published about one invasive plant, but perhaps only a dozen about another.

If you want to read the research yourself, perhaps to clarify or expand an area of information contained here, or to help determine your own line of research, you are welcome to query the world’s largest collection of international scientific literature about aquatic, wetland and invasive plants, the APIRS bibliographic database, which contains more than 54,000 citations and their content keywords. Or you might want to ask us to do it for you and mail or e-mail the search results to you.

Video Transcript

East Indian hygrophila – Hygrophila polysperma
This plant is not native to Florida. There are about 40 species of aquatic hygrophila in the world. East Indian hygrophila is the only submersed hygrophila found in the state. The plant is rather small and may be found totally submersed, or with some emersed leaves. East Indian hygrophila may be found in streams and slowly moving waters of central and south Florida. It is prohibited in the state. Hygrophila stems are square. The stems are erect, or they may be sprawling. The submersed stems grow to 6 feet long, with only a few inches emerging from the water. East Indian hygrophila leaves are opposite on the stem. They are an inch-and-a-half long, and one-half inch wide. The flowers are bluish-white to white and have two lips. They grow from the axles where the leaves meet the stem. The exotic East Indian hygrophila has square stems. Its leaves are arranged oppositely on the stem. Hygrophila flowers grow at the leaf axles. The flowers are two-lipped and can be white or bluish-white.


This is the literature about Hygrophila polysperma that was used to develop this web page. More research items about this plant may be found at APIRS:

  • Angerstein MB, Lemke DE. 1994. First records of the aquatic weed Hygrophila polysperma (Acanthaceae) from Texas. Sida 16:365-71
  • Bowes G. 1982. Baseline physiology of the potential problem plants, Limnophilia sessiliflora and Hygrophila polysperma. Dept. of Bot., Univ. of Florida, Gainesville, 17 pp.
  • Cassani JR. 1996. Managing aquatic vegetation with grass garp. A guide for water resource managers. American Fisheries Soc., Introduced Fish Sect., Bethesda, MD., 196 pp.
  • Cobb JE, Haller W. 1981. Annual Report, Florida Cooperative Agreement, Integrated Management of Aquatic Weeds 1980-1981. USDA/SEA/AR- University of Florida
  • Hall DW, Vandiver VV Jr. 1990. Weeds in Florida. Gainesville: University of Florida, Institute of Food and Agricultural Sciences (IFAS). Publication SP 37. 43 pp.
  • Innes WT. 1947. Hygrophila, a new aquarium plant. The Aquarium 16:30-1
  • Kasselmann C. 1995. Aquarienpflanzen. Egen Ulmer GMBH & Co., Stuttgart. 472 pp. (In German)
  • Les DH, Wunderlin RP. 1981. Hygrophila polysperma (Acanthacae). Florida Scientist 44:189-92
  • McCann JA et al. 1996. Nonindigenous aquatic and selected terrestrial species of Florida-Status, pathway, and time of introduction, present distribution, and significant ecological and economic effects. Southeastern Biological Science Center, Gainesville, 256 pp.
  • Miller JW. 1990. Florida aquaculture regulatory source book: leasing, licensing, and permitting requirements for aquaculture in Florida. FL Dept. Agric. Consumer Serv., Tallahassee, 238 pp.
  • Pemberton RW. 1996. The potential of biological control for suppression of invasive weeds of southern environments. Castanea 61(3):313-319
  • Reams WM. 1953. The occurrence and ontogeny of hydrothodes in Hygrophila polysperma T. Anders New Phyto. 52:8-13
  • Schardt JD. 1997. Florida Aquatic Plant Survey 1994. Tech. report. Tallahassee: Florida. Dept of Environmental Protection. Report nr 972-CGA. 86 pp.
  • Schardt JD, Schmitz DC. 1991. Florida Aquatic Plant Survey 1990. Tech. report. Tallahassee: Florida Dept. of Natural Resources. Report nr 91-CGA. 89 pp.
  • Schmitz DC. 1985. Hygrophila polysperma, A review of the scientific literature. Tech. report. Tallahassee: Fla. Dept. of Natural Resources. 15 pp.
  • Simberloff et al. 1997. Strangers in paradise- impact and management of non-indigenous species in Florida. Island Press, Washington, DC, 467 pp.
  • Spencer W, Bowes G. 1984. Limnophilia and hygrophila: a review and physiological assessment of their weed potential in Florida. J. Aquat. Plant Manage. 23:7-16
  • Stocker RK. 1996. Control technologies for use against the submersed aquatic weeds hydrilla and hygrophila. Semi-Annual Rept., USDA/ARS-IFAS, Gainesville, FL, 68 pp.
  • Sutton DL. 1995. Hygrophila is replacing hydrilla in south Florida. Aquatics 17:4-10
  • Van TK, Steward KK. 1982. Evaluation of chemicals for aquatic plant control. Annual Report 1981, Ft. Lauderdale, FL, 66 pp.
  • Van dijk GM, Thayer DD, Haller WT. 1986. Growth of hygrophila in flowing water. J. Aquat. Plant Manage. 24:85-7
  • Vandiver VV. 1999. Florida aquatic weed management guide. Univ. of FL, IFAS, Cooperative Extension Service, Publ. SP-55, 130 pp.
  • Vandiver VV. 1980. Hygrophila. Aquatics 2:4-11
  • Westbrooks RG, Eplee RE. 1996. Regulatory exclusions of harmful non-indigenous plants from the United States by USDA APHIS PPQ. Castanea 61:305-312
  • Wunderlin RP, Hansen BF, Bridges EL. 1995 (updated May 1996). Atlas of Florida vascular plants. Website: http://www.plantatlas.usf.edu/


See more information and pictures about East Indian hygrophila, as contained in the Langeland/Burks book, Identification & Biology of Non-Native Plants in Florida’s Natural Areas.

View the EDIS publication,Waterlily Leafcutter, Synclita obliteralis (Walker) (Insecta: Lepidoptera: Crambidae: Acentropinae), by Dale H. Habeck and James P. Cuda.


View the herbarium specimen image of the University of Florida Herbarium Digital Imaging Projects.

Sea Grant

This web page was authored in June, 2001, by Victor Ramey (Center for Aquatic and Invasive Plants, University of Florida), with significant contribution from Barbara Peichel (Sea Grant, University of Minnesota). The information contained herein is based on the literature found in the APIRS database.


1. From Identification and Biology of Nonnative Plants in Florida’s Natural Areas – Second Edition, by K.A. Langeland, H.M. Cherry, et al. University of Florida-IFAS Pub SP 257. 2008.

2. From Strangers in Paradise, Impact and Management of Nonindigenous Species in Florida, Chapter 2: Florida’s Invasion by Nonindigenous Plants: History, Screening, and Regulation, by D.R. Gordon and K.P. Thomas, pp. 21-37. Island Press, Washington, DC, 1997.

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